Field Guide to Amazonian Bats

Field Guide to Amazonian Bats Presidente da República: Michel Temer Ministro da Ciência, Tecnologia, Inovações e Comunicações: Gilberto Kassab Diretor do Instituto Nacional de Pesquisas da Amazônia: Luiz Renato de França Copyright © 2016, the authors. This is publication 702 in the BDFFP technical series. All rights reserved. No part of this book may be reprinted or reproduced or utilized in any form or by any electronic, mechanical, or other means, now known or hereafter invented, including photocopying and recording, or in any information storage or retrieval system, without permission in writing from the publishers. ________________________________________________________________________________________________________ F453 Field Guide to Amazonian Bats / Adrià López-Baucells... [et.al.]. - Manaus: Editora INPA, 2016. 168 p.: il. color. ISBN 978-85-211-0158-1 1. Morcegos - Amazônia. 2. Guia de campo. I. López-Baucells, Adrià. CDD 599.4

First published 2016 by Instituto Nacional de Pesquisas da Amazônia (INPA) Av. André Araújo, 2936 - Petrópolis, Manaus - AM, 69067-375, Brazil Cover design & photograph: Oriol Massana Valeriano & Adrià López-Baucells Authors: Adrià López-Baucells, Ricardo Rocha, Paulo Bobrowiec, Enrico Bernard, Jorge Palmeirim & Christoph Meyer. Contact e-mail:

adria.baucells@gmail.com

Collaborating institutions: Centre for Ecology, Evolution and Environmental Changes (cE3c), Faculdade de Ciências, Universidade de Lisboa, Campo Grande C2, 1749-016, Lisboa (Portugal) Granollers Museum of Natural Sciences c/Palaudàries 102, 08402 Granollers (Catalonia) Biological Dynamics of Forest Fragments Project (BDFFP) Av. André Araujo 2936, CEP 69083-000 Manaus (Brazil) School of Environment & Life Sciences, University of Salford, Peel Building, Salford, M5 4WT Manchester (United Kingdom) Centro de Ciências Biológicas, Universidade Federal de Pernambuco, Av. Professor Moraes Rego, CEP 50670-901 Recife (Brazil) Metapopulation Research Centre, Faculty of Biosciences University of Helsinki, Viikinkaari, FI-00014 12 Helsinki (Finland) Illustrations:

Blanca Martí de Ahumada & Eva Sánchez Gómez

Design:

Adrià López-Baucells

Images:

Oriol Massana Valeriano & Adrià López-Baucells

A PDF version of this book is available for free at www.tropicalconservation.net

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Field Guide to Amazonian Bats

FIELD GUIDE to

Amazonian Bats

“... foi então que o Jurupari pôs fogo e breu pra ferver, e quando ferveram, soltaram fumaça, de onde saíram morcegos, jacamins, uakuraus, murucututus, iakurutus, andorinhas e gaviões...” “Mônica Rodrigues da Costa, Paula Medeiros de Oliveira and Paulo Pedro Costa.

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Field Guide to Amazonian Bats

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Field Guide to Amazonian Bats

FOREWORD Field Guide to Amazonian Bats is the culmination of an almost unimaginable amount of challenging fieldwork. The first publication of its kind, it is beautifully illustrated, comprehensive and extraordinarily easy to use. Authors Adrià Lopez-Baucells, Ricardo Rocha, Paulo Bobrowiec, Enrico Bernard, Jorge Palmeirim and Christoph Meyer have provided an invaluable contribution to the world of bats, a musthave publication for anyone working on bats in the Neotropics. The Amazon basin encompasses more than half of our planet’s remaining rainforests and is home to the world’s largest, most diverse assemblage of bats. Understanding these animals is vital to the conservation of the Amazonian biome. However most Amazonian bats remain unstudied and our lack of ability to reliably identify them has been a major hindrance to research on their unique contributions and needs. As noted, throughout this vast system, bats are essential seed dispersers, pollinators and controllers of vast numbers of herbivorous insects. Only one, the common vampire, causes significant problems for people and their livestock. Yet, far too often, all species are mistakenly killed as vampires, posing an enormous threat to the health of the whole ecosystem and associated human economies. It is my hope that this outstanding field guide will open the door to an explosion of much needed research and education, essential to the authors’ conservation goals. As a fellow photographer and conservationist I deeply appreciate the obvious attempt to show bats, even the vampires, with pleasant expressions that do not contribute to further misunderstanding and fear. This publication is also the first to share a broad, well organized echolocation database and key, accompanied by appropriate cautionary advice and documentation. Hopefully, it will become a model, inspiring additional field guides for the rich and also vitally important bat faunas of Africa and Asia.

Merlin D. Tuttle

Founder and Executive Director Merlin Tuttle’s Bat Conservation

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Field Guide to Amazonian Bats

PREFACE This book is designed as a guide aimed at satisfying the needs of those conducting field work on bats in the Amazon. It is largely based on Lim et al. (2001), with modifications derived from both personal observations and three years of field experience in the Brazilian Amazon at the Biological Dynamics of Forest Fragments Project (BDFFP), as well as a thorough revision of available bat keys and scientific papers describing new species. Our aim was to write a straightforward, easy-to-use guide that would be both practical and very visual, and would facilitate bat species identification in the field. We tried to avoid as much as possible confusing features such as fur colour, as well as certain skull and teeth characteristics that cannot be easily measured under field conditions. We decided to group together many of the cryptic species that are still indistinguishable in the field and that can only reliably be identified using molecular methods such as DNA barcoding. Taxonomic nomenclature throughout this key follows Nogueira et al. (2014).

This is an interactive field-guide that we hope will be continuously improved and updated. We will be delighted to receive readers’ comments and suggestions! Please send them to: adria.baucells@gmail.com Thank you! The Authors

-------------------------------------------------------------------------------------------------------------

Lim, B.K. & Engstrom, M.D. (2001). Species diversity of bats (Mammalia: Chiroptera) in Iwokrama Forest, Guyana, and the Guianan subregion: implications for conservation. Biodiversity & Conservation 10(4):613-657. Nogueira, M.R. et al. (2014). Checklist of Brazilian bats, with comments on original records. Check List 10(4):808-821.

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Field Guide to Amazonian Bats

CONTENTS Acknowledgements p. 8 Photographic credits p. 9 Introduction p. 10 Bats in the Amazon p. 16 How to use this guide

p. 20

Morphological key p. 22 Families p. 22 Phyllostomidae p. 24 Thyropteridae p. 72 Furipteridae p. 76 Noctilionidae p. 78 Mormoopidae p. 82 Emballonuridae p. 86 Vespertilionidae p. 96 Molossidae p. 106 Natalidae p. 118 Echolocation keys p. 120 Appendix I. Species rostra

p. 152

Authors p. 164 Illustrators p. 167 References p. 168

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Field Guide to Amazonian Bats

Acknowledgements This guide could not have been written without the help of the following contributors: William Magnusson was a great help during the final stage of the production of this book. He provided us with the logistic means to publish it as an online e-book, thus enabling us to widely publicize it among scientists, students and institutions. José Luís C. Camargo, Ary Jorge C. Ferreira, M. Rosely C. Hipólito, Alaércio dos Reis, Luiz de Queiroz, Josimar Menezes, Osmaildo da Silva, and José Tenaçol provided continuous support during our fieldwork at the BDFFP. Carles Flaquer Sánchez, Xavier Puig-Montserrat, and Antoni Arrizabalaga gave vital support to the project, and provided material and field equipment, acoustic and mist-netting training, software licenses, and valuable corrections on previous drafts. Maria Mas helped greatly with the analysis of bat calls. Michel Barataud, Vincent Rufray and Thierry Disca are acknowledged for their help in reviewing the acoustic key. Madalena Boto gave advice on photography and she deserves special credit for her amazing contribution to the making, montage and directing of the video trailer used to promote this guide. This video would have been impossible without the altruistic contribution from ‘Of Monsters and Men’ and Helena Mata from Universal Music Portugal and Syncsongs Music Publishing, who provided the instrumental piece Dirty Paws, used as the video soundtrack. We would especially like to thank all the people who selflessly contributed good quality pictures to cover some of the gaps, including Merlin Tuttle, who kindly agreed to write a foreword to the book and also provided some excellent bat photographs. Marta Acácio, Diogo Ferreira, Fabio Farneda, Gilberto Josimar, Madalena Boto, Milou Groenenberg, Júlia Treitler, Rodrigo Marciente, Solange Farias, Kevina Vulinec, Inês Silva, Joana Carvalho, Leonardo Oliveira, Ileana Mayes, and Ubirajara Capaverde were all great help in the field. They were also excellent company during these years and helped keep this project on track. Mercè Baucells, Josep Anton López, Míriam López Baucells, Pilar Valeriano, and Ramon Massana provided financial and logistical support during the whole period. We gratefully acknowledge institutional support from the Centre for Ecology, Evolution and Environmental Changes (cE3c), the Granollers Museum of Natural Sciences, the National Institute for Amazonian Research (INPA), the Biological Dynamics of Forest Fragments Project (BDFFP), the University of Salford, the Universidade Federal de Pernambuco and the Smithsonian Tropical Research Institure (STRI). Funding was provided by a Portuguese Foundation for Science and Technology (FCT) project grant PTDC/BIA-BIC/111184/2009, SFRH/BD/80488/2011 and PD/BD/52597/2014.

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Field Guide to Amazonian Bats

Photographic credits Most of the photographs used in this field guide were taken by Oriol Massana Valeriano and Adrià López-Baucells at the Biological Dynamics of Forest Fragments Project near Manaus (Brazil) during a research project on the effects of forest fragmentation on bats undertaken in 2011–2015.

External contributions Burton Lim, Alex Borisenko (Lasiurus atratus p.101 & 159) Elizabeth Clare (Eptesicus furinalis p.103 & 159, Molossus sinaloae p.161, Myotis albescens p.105 & 160, Noctilio leporinus p.157, Pteronotus davyi p.158, Vampyrum spectrum p.53, 59 & 156). Enrico Bernard (Diclidurus ingens p.93, Lonchorhina aurita p.53, 61 & 155, Eumops bonariensis p.161, Peropteryx leucoptera p.95 & 159, Rhogeessa hussoni p.160). Fabio Falcão (Diaemus youngi p.29 & 152, Diclidurus albus p.93, Diphylla ecaudata p.29 & 152, Mimon bennettii p.156, Nyctinomops laticaudatus p.109 & 162, Platyrrhinus lineatus p.153). Fábio Z. Farneda (Anoura geoffroyi p.152, Eptesicus diminutus p.159, Molossops temminckii p.109 & 117, Natalus macrourus p.23 & 162). Jose Gabriel Martinez (Cynomops greenhalli p.117 & 161, Cyttarops alecto p.89, Eumops perotis p.161, Enchisthenes hartii p.39, 45 & 153, Glossophaga commissarisi p.152, Lichonycteris obscura p.35 & 152, Molossus pretiosus p.113 & 161). Bruce J. Hayward (Glossophaga longirostris p.152). Lizette Siles (Eptesicus chiriquinus p.103 & 159, Nyctinomops macrotis p.162, Platyrrhinus infuscus p.153, Sphaeronycteris toxophyllum p.39, 43 & 154) Maël Dewynter (Lonchorhina inusitata p.61 & 155, Micronycteris brosseti p.155, Micronycteris minuta p.155, Natalus tumidirostris p.119 & 162, Phyllostomus latifolius p.156). Marco Mello (Tonatia bidens p.156, Mimon bennettii p.59, www.marcomello.org). Merlin Tuttle (Artibeus amplus p.47 & 153, Diclidurus isabella p.93, Lasiurus cinereus p.101 & 160, Lophostoma schulzi p.155, Molossops temminckii p.161, www.merlintuttle.org). Octavio Jiménez (Eptesicus andinus p.103 & 159, Eumops glaucinus p.161, Molossus currentium p.161, Myotis simus p.159, Sturnira magna p.154, Dermanura anderseni p.153, Platyrrhinus infuscus). Roberto Leonan (Carollia benkeithi p.157, Diclidurus scutatus p.89 & 93, Eumops perotis p.115, Glyphonycteris sylvestris p.155, Lionycteris spurrelli p.152, Micronycteris schmidtorum p.155, Neoplatymops mattogrossensis p.162, Peropteryx macrotis p.159, Peropteryx trinitatis p.159, Platyrrhinus brachycephalus p.153, Platyrrhinus incarum p.153, Promops nasutus p.162, Saccopteryx canescens p.159, Scleronycteris ega p.29, 35 & 152, Vampyressa pusilla p.154, Vampyrodes caraccioli p.49 & 154). Tiago Marques (Centronycteris centralis p.93 & 158, Dermanura glauca p.153) Ubirajara Dutra (Rhinophylla fischerae p.157, Thyroptera devivoi p.157). Vinícius Cardoso (Histiotus velatus p.101 & 159, Molossus coibensis p.113 & 161, Thyroptera lavali p.157). William Douglas de Carvalho (Molossops neglectus p.117 & 161).

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Field Guide to Amazonian Bats

Introduction

Although elusive due to their mostly nocturnal behavior, bats (order Chiroptera, from the Greek cheir ‘hand’ and pteron ‘wing’) are undoubtedly one of the most fascinating faunal groups in the world. Only outnumbered by rodents, they constitute the second most numerous mammalian order but are arguably the most diverse given that they demonstrate just how ecologically adaptive mammals can be. At present, over 1,300 species of bats are known to science. Nevertheless, this number is growing steadily, mostly due to the splitting of taxa based on new genetic evidence and the discovery of hitherto truly unknown species in remote corners of the planet. Bats range in size from one of the smallest of all mammals, the bumblebee bat Craseonycteris thonglongyai (1.5–2 g), to the large Pteropus flying foxes, which possess a wide array of shapes and colours; in some cases, they weigh over 1 kg and have wingspans exceeding 1.5 m. Bats have been around for some 50 million years and have taken advantage of two unique aspects of their biology – echolocation and powered flight – to conquer the night skies in nearly all of the available ecosystems across the globe, the exception being the Arctic, Antarctic and a few isolated oceanic islands No other mammalian order exploits such a broad diversity of food resources. Although most bat species have evolved as highly specialized hunters of aerial insects, a number have developed a taste for vertebrates (ranging from fish to amphibians, reptiles, birds and even small mammals, including other bats), plant matter (chiefly fruit, but also nectar, pollen, and occasionally leaves and seeds), and blood. Certain species are omnivorous but many bats have highly specialized diets and have developed complex examples of co-evolution. A good example of this is the relationship between the South American plant Centropogon nigricans and their (probably) only pollinator, the recently discovered tube-lipped nectar 10

Field Guide to Amazonian Bats

11

Field Guide to Amazonian Bats

Introduction

bat Anoura fistulata, holder of the record for longest tongue (8.5 cm) in relation to body size in any mammal (its tongue measures 150% of the size of its overall body length!). Predator-prey interactions are equally intrincate and reach their evolutionary climax in the ‘arms race’ between aerial insectivorous bats and their prey. Roost selection is another example of the enormous plasticity displayed by bats. Caves are probably the best-known bat roost sites; indeed many species are mostly cave-dwellers and some caves harbour millions of conspecific bats, as in the case of the Brazilian free-tailed bats Tadarida brasiliensis in Central America and Southern USA. Apart from caves, however, bats make use of a myriad of natural and man-made structures for roosting. Some species of Neotropical stenodermatine fruit-eating bats make tents by biting the central rib of palms and Heliconia leaves. In an interesting case of convergent evolution, Thyroptera bats from Central and South America and Myzopoda from Madagascar have both evolved suction cups or suckers on the base of their thumbs and ankles that allow them to cling to smooth surfaces and roost inside curled leaves. Some species such as the hoary bat Lasiurus cinereus are solitary tree dwellers, whilst others including many Old World fruit bats roost in large tree colonies numbering several thousands. Man-made structures such as mines, bridges and 12 12

Field Guide to Amazonian Bats

roof cavities are used by many species, while others (e.g. several Neotropical Emballonuridae) simply take advantage of their camouflage to roost on lichencovered tree bark or rocks. A few species roost in underground borrows, while the South and Central American white-throated round-eared bat Lophostoma silvicola even roosts colonially inside the nests of arboreal termites. True powered flight and echolocation undoubtedly lie at the heart of this group’s evolutionary success. Flying is much less energy-consuming than running and, given that it removes the need to touch ground, it precludes potentially deadly encounters with terrestrial predators. Echolocation probably evolved hand-inhand with flight and, by allowing early bats to analyse the echoes of emitted sound pulses and so negotiate obstacles, served as an entrance to an ecological niche that was inaccessible to most other groups: the night sky. Although other animal groups including the cetaceans (dolphins and whales) use sound in this way, none does so in such a complex manner. Echolocation has reached its evolutionary peak in bats and, for most species, is key to their ability to avoid physical obstacles and find food. Bats tend to have good auditory sensitivity and therefore can listen to sounds made by moving prey or, as in the case of the Neotropical fringe-lipped bat Trachops cirrhosus, can even identify 13 13

Field Guide to Amazonian Bats

Introduction

edible frogs from their calls. Good night vision and a well-developed sense of smell are also of utmost importance and enable many species to find food; this is especially true for the Old World fruit bats. Bats have unfortunately been the subject of disdain and persecution by many, and are frequently portrayed as blood-sucking demons and associated with dark practices. On the other hand, some cultures such as the Middle-to-Late Qing Dynasty (1644–1911) in China have regarded bats as symbols of good fortune, a much more faithful reflection of their importance to the planet’s ecological health and to our own survival. Bats are key providers of many ecosystem services such as seed dispersal, pollination, and pest control. Their disappearance can lead to enormous economic losses (e.g. the economic value of bats to North American agriculture alone has been estimated at around $23 billion per year) and probable wide-scale ecosystem collapse. Over the last 500 years the planet has faced a human-generated wave of extinctions that is comparable to the Earth’s five previous mass extinctions. Despite their uniqueness, bats face the same threats as many other species on the planet and are consequently being severely affected by the ongoing ‘sixth mass extinction’. Currently, approximately one quarter of all bat species are globally threatened. Increasing rates of habitat loss and fragmentation, overexploitation, misguided persecution, climate change, and epidemic diseases (such as white-nose syndrome, a fungal infection that has killed millions of bat throughout North America in recent years) mean that many more species are likely to become extinct in the near future.

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Field Guide to Amazonian Bats

Fortunately not all is glim. As we come to better understand bats, their importance for ecosystem well-being and functioning, and ultimately, how they benefit humankind, attitudes towards them are slowly starting to change. Across the globe multiple grass roots conservation projects are braving their way to try to reverse ongoing population declines and the image of bats in books, movies and the general media is starting to reflect some elements of truth. Conservation of the planet’s unique biological richness will ultimately depend on how much we treasure the natural world. We hope that by revealing some of the tremendous richness of the Amazonian bat fauna this book will aid in a better understanding of their natural history, our impacts on them and consequently, how we can combine our efforts to better contribute to their conservation, because as the Senegalese conservationist Baba Dioum once said: “In the end we will conserve only what we love. We will love only what we understand. We will understand only what we are taught.� 15

Field Guide to Amazonian Bats

Bats in the Amazon

The increase in species richness with increasing proximity to the Equator is a major biogeographic pattern to which bats are no exception. Bat diversity peaks in tropical regions, and the Neotropics of South and Central America constitute the epicenter of this diversity, harbouring more than 200 currently recognized species. The Amazon basin holds over half of the world’s remaining rainforests and represents the largest and most biodiverse expanse of tropical rainforest on the planet. Roughly one in ten known bat species occurs in the Amazon basin and in some Central Amazonian localities more than 100 species live in sympatry. Bats are divided into 17 families (or 18, depending on the acceptance of Miniopteridae as a separate family), of which nine (Phyllostomidae, Thyropteridae, Furipteridae, Noctilionidae, Mormoopidae, Emballonuridae, Vespertilionidae, Molossidae, and Natalidae) are present in the Amazon. The distribution of the species across the Amazonian bat families is rather uneven: the bulk of species belongs to the family of New World leaf-nosed bats (Phyllostomidae), the ecologically most diverse family within the order (nearly 200 species throughout Central and South America). On the other hand, the Furipteridae are represented in the Amazon by just one of the two members of its family, the thumbless bat Furipterus horrens. Bats are key elements in the Amazon’s intricate ecological networks and, through countless links to other animal and plant groups, help support and sustain the biome in all its complexity and magnificence. Many Amazonian bats such as the Phyllostomidae subfamilies Stenodermatinae and Carolliinae feed almost exclusively on fruit and act as ‘forest gardeners’ by dispersing seeds far and wide. They often introduce seeds into previously disturbed habitats and consequently help the forest reclaim some of its lost domains. Some 16

Field Guide to Amazonian Bats

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Field Guide to Amazonian Bats

Bats in the Amazon

other species such as the Glossophaginae hover like hummingbirds in front of flowers and with their long muzzles and tongues probe flowers to extract their nectar, effectively acting as pollinators, thereby helping to maintain the genetic diversity of flowering plants. However, most Amazonian bats are either obligate or facultative insect-eaters and glean insects and other arthropods directly from the vegetation in the forest understory, or capture prey in open spaces above or below the forest canopy. By doing so, they greatly reduce arthropod-related herbivory and redistribute nutrients via their guano, thereby helping to maintain terrestrial and aquatic ecosystems throughout the Amazon. Four species of Phyllostomidae, namely the greater spear-nosed bat Phyllostomus hastatus, the fringe-lipped bat Trachops cirrhosus, the big-eared woolly bat Chrotopterus auritus, and the spectral bat Vampyrum spectrum, are confirmed carnivores, while the two Noctilio species are both fish-eaters. On the other hand, bats regularly form part of the diet of several faunal groups including spiders, giant centipedes, frogs, marsupials, other bats, birds, and snakes. In recent years several new species have been described and new records have extended the geographic range of some species by hundreds of kilometers. However, knowledge of Amazonian bats is still limited and extremely biased towards certain relatively well-studied localities such as the Biological Dynamics of Forest Fragments Project (BDFFP) and Alter do Chão, in the heart of the Brazilian Amazon. As bat researchers venture into the last unknown Amazonian frontiers we are learning more about the fascinating diversity of this region’s bats, knowledge that is vital for both bat conservation and the conservation of the Amazon biome as a whole.

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Field Guide to Amazonian Bats

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Field Guide to Amazonian Bats

How to use this guide Bat morphology and terminology used in this guide

Tibia 20

Calcar

Ear

Tragus

Field Guide to Amazonian Bats

How does it work? A) This is not a dichotomous key. Each choice may lead to a number of hierarchical options! B) Species that are virtually indistinguishable in the field have been grouped together. Consider collecting wing-punches for genetic studies. C) All measurements are given in mm. D) Forearm length (FA) is given after each species name. However, FA length may vary geographically and thus may not always be a reliable characteristic!

This symbol indicates that the use of a good hand-lens or camera is required.

Phyllostomidae

Thyropteridae

Furipteridae

Noctilionidae

Mormoopidae

How should measurements be taken? Emballonuridae

Vespertilionidae Holding a bat

Forearm (FA)

Molossidae

Natalidae Noseleaf

Thumb (with nail) 21

Field Guide to Amazonian Bats

Key to Amazonian bat families

1a. Noseleaf or flaps of skin on face.

Phyllostomidae (p. 24)

1b. Wrists and ankles with suction cup. 1c. Rudimentary thumb with reduced claw almost entirely embedded in propatagium. 1d. Tail emerges from dorsal surface of the uropatagium. 2a. Upper lip drooping, split frontally; feet/claws very large. 2b. Chin with bumps or folds of skin; upper lip not split, feet/ claws not particularly enlarged. 2c. Enlarged muzzle; glandular sac present in tail or FA (sometimes vestigial in females). 1e. Tail enclosed and extending to the edge of pointed uropatagium. 1f. Tail extending well beyond the edge of the uropatagium. 2a. Short legs and slim wings; fur quite short and oily. 2b. Ears large, funnel-shaped; depressed face; fur ranges from yellowish to orangish; tail equal to or longer than body length.

1a

1d

22

1a

1e

Thyropteridae (p. 72) Furipteridae (p. 76)

Noctilionidae (p. 78)

Mormoopidae (p. 82)

Emballonuridae (p. 86) Vespertilionidae (p. 96)

Molossidae (p. 106)

Natalidae (p. 118)

1f

Field Guide to Amazonian Bats

1a

1a

1b

1d

1e

1f

1d 2a

1d 2b

1d 2a

1d 2c

1d 2c (closed)

1d 2c (open)

1f 2a

1f 2a

1f 2b

1c

1d 2b

1f 2b 23

Field Guide to Amazonian Bats

Phyllostomidae The New World leaf-nosed bats constitute one of the most extraordinary examples of adaptive radiation in the natural world. The nearly 200 recognized species have most probably evolved from an insectivorous ancestor; nevertheless, although insectivory is still the predominant dietary strategy amongst Phyllostomidae, numerous species have evolved to exploit other food sources such as fruit, nectar, pollen, small vertebrates, and, in the case of the three vampire bat species, even blood. Phyllostomids range in size from the small white-shouldered bat Ametrida centurio (FA averages 26 mm) to the carnivorous false vampire bat Vampyrum spectrum (FA averages 106 mm), the largest bat native to the Neotropics. Their morphological features are quite variable, reflecting this family’s diverse diet and foraging behaviours; even so, most species have an often large, bladeshaped noseleaf, from which both the scientific and common names of this family derive. This noseleaf is thought to act as an acoustic pointer and magnifier that concentrates echolocation calls into a narrow beam.

Lophostoma silvicola

24

Field Guide to Amazonian Bats

25

Field Guide to Amazonian Bats

Phyllostomidae

1a. Noseleaf greatly reduced; incisors blade-like; thumbs greatly enlarged.

Desmodontinae

1b. Elongated muzzle; tongue remarkably long, sometimes protruding from mouth.

Glossophaginae

1c. Either whitish stripes on face or head (crown) or whitish patches on shoulders or uropatagium absent.

Stenodermatinae

1d. Chin with warts in V/Y shape, similar in size, with no large central wart; ears often very large.

Phyllostominae

1e. Chin with large central and rounded wart surrounded by smaller protuberances or 2 enlarged bumps.

1a

1d

1e 26

Carolliinae

1d

1e

Field Guide to Amazonian Bats

1a

1a

1a

1b

1b

1c

1c

1c

1d

1d

1e

1e

1d

1d

1e

1e

Dermanura gnoma

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Field Guide to Amazonian Bats

Phyllostomidae / Desmodontinae

1a. Thumb < 13 mm; no pad under thumb. Diphylla

1b. Thumb > 13 mm; one or two pads under thumb. 2a. Calcar absent; one long pad under thumb, whitish tips on wings.

Diaemus

2b. Tiny calcar present; two rounded pads under thumb; darker tips on wings.

Desmodus

Diphylla (Hairy-legged vampire bat) 1a. Only one species in the genus.

Diaemus (White-winged vampire bat) 1a. Only one species in the genus.

Desmodus (Common vampire bat) 1a. Only one species in the genus.

1a 28

Diphylla ecaudata (50-56 mm)

Diaemus youngi (50-56 mm)

Desmodus rotundus (52-63 mm)

1b

1c

1b

1b

Diphylla ecaudata

Field Guide to Amazonian Bats

1b 2b

Diaemus youngii

1b 2b

Desmodus rotundus

Desmodus rotundus

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Field Guide to Amazonian Bats

Phyllostomidae / Glossophaginae

1a. Lower incisors absent. 2a. Uropatagium hairy and small, does not enclose the knees. 2b. Uropatagium naked and encloses the knees. 3a. Dorsal fur tricoloured: dark brown-pale-dark brown.

Lichonycteris

3b. Fur bicoloured. 4a. 1st phalanx of thumb shorter than 2nd. 4b. 1st and 2nd phalanxes of thumb the same length.

1a

1a 2a 30

Anoura

1b

1a 2b

Scleronycteris Choeroniscus

Field Guide to Amazonian Bats

1a

1b

1a 2a

1a 2b

1a 2b 3a

1a 2b 3b

1a 2b 3b 4a

1a 2b 3b 4b

Lonchophylla thomasi

31

Field Guide to Amazonian Bats

Phyllostomidae / Glossophaginae

1b. Lower incisors present (although sometimes surrounded by the gum). 2a. Upper incisors roughly similar in size, forming an arc.

Glossophaga

2b. Upper central incisors much larger than lateral ones. 3a. Dorsal fur strongly bicoloured; wing attached to ankle. 3b. Dorsal fur unicoloured; wing attached near base of toe.

Lionycteris

1b 2a

1b 2b 3a 32

Lonchophylla

1b 2b

1b 2b 3b

Field Guide to Amazonian Bats

1a

1b

1b 2a

1b 2b

1b 2b 3a

1b 2b 3a

1b 2b 3b

1b 2b 3b

Lonchophylla thomasi

33

Field Guide to Amazonian Bats

Phyllostomidae / Glossophaginae

Anoura (Hairy-legged long-tongued bats) 1a. Tail small but present.

Anoura caudifer (34-39 mm)

1b. Tail absent; dorsal fur bicoloured; venter uniform brown.

Anoura geoffroyi (39-47 mm)

Lichonycteris (Dark long-tongued bat) 1a. Only one species in the Amazon.

Lichonycteris degener (30-36 mm)

Scleronycteris (Ega’s long-tongued bat) 1a. Only one species in the genus.

34

Scleronycteris ega (33-35 mm)

1a (Anoura)

1b (Anoura)

Field Guide to Amazonian Bats

Lichonycteris obscura

Scleronycteris ega

Lonchophylla thomasi

35

Field Guide to Amazonian Bats

Phyllostomidae / Glossophaginae

Choeroniscus (Long-nosed long-tongued bats) 1a. Only one species complex in the Amazon. Choeroniscus godmani (31-38 mm) / minor (26-39 mm) *

Glossophaga (Long-tongued bats) 1a. Lower incisors unspaced, large and weakly cusped. 1b. Lower incisors unspaced, peg-like.

Glossophaga longirostris (35-42 mm)

Glossophaga soricina (31-40 mm) 1c. Lower incisors small and medially separated by small gap. Glossophaga commissarisi (31-38 mm)

Lonchophylla (Thomas’ nectar bat) 1a. Only one species in the Amazon.

Lonchophylla thomasi (29-35 mm)

Lionycteris (Chestnut long-tongued bat) 1a. Only one species in the genus.

1a

Lionycteris spurrelli (32-38 mm)

1b

1c

* We recommend classification as C. godmani / minor until more external morphological data are available for reliable identification in the field.

36

1a (Choeroniscus godmani)

1a (Choeroniscus minor)

Field Guide to Amazonian Bats

Lonchophylla thomasi

Glossophaga soricina

37

Field Guide to Amazonian Bats

Phyllostomidae / Stenodermatinae

1a. Uropatagium absent; shoulders orangish/yellowish.

Sturnira

1b. Uropatagium present; shoulders with white patch. 2a. Noseleaf clearly distinct. ♂ has two glands on breast / ♀ greatly enlarged clitoris! 2b. Noseleaf not distinct; protuberance emerging from the face. 1c. Uropatagium present; shoulders without coloured patch.

Ametrida Sphaeronycteris

2a. Inner upper incisors bifid. 3a. Dorsal stripe present.

Uroderma

3b. Dorsal stripe absent. 4a. FA < 43 mm. 5a. Base of noseleaf joined to lip.

Enchistenes

5a. Base of noseleaf separate from lip.

Dermanura

4b. FA > 43 mm.

Artibeus

2b. Inner upper incisors not bifid.

1c 2a 38

1c 2b

1c 2a 3b 4a 5a

1c 2a 3b 4a 5b

Field Guide to Amazonian Bats

1a

1b & 1c

1a

1b

1c

1b 2a

1b 2b (male)

1b 2b (female)

1b 2a

1b 2a 3b

1b 2a 3b

1c 2a

1c 2b

1c 2a 3a

1c 2a 3b

1c 2a 3b 4a 5a 1c 2a 3b 4a 5b 39

Field Guide to Amazonian Bats

Phyllostomidae / Stenodermatinae

3a. Uropatagium only furry at edges.

Vampyrodes & Platyrrhinus

3b. Uropatagium furry dorsally; always four lower incisors.

Chiroderma

3c. Uropatagium not furred; two or four lower incisors. 4a. Facial stripes present; fur dark brown.

Vampyressa & Vampyriscus

4b. Facial stripes very indistinct; fur pale, almost whitish.

3a

40

Mesophylla

3b 4a

3b 4b

3b 4a

3b 4b

3a

3b

3c

3b

3c

3c 4a

Field Guide to Amazonian Bats

3c 4b

Mesophylla macconnelli

41

Field Guide to Amazonian Bats

Phyllostomidae / Stenodermatinae

Sturnira (Yellow-shouldered bats) 1a. FA < 45 mm; inner upper incisors pointed; fur bicoloured. 1b. FA 44-48 mm; inner upper incisors flattened; fur tricoloured. 1c. FA > 55 mm.

Ametrida (Little white-shouldered bat) 1a. Only one species in the genus.

Sphaeronycteris (Visored bat) 1a. Only one species in the genus.

Uroderma (Tent-making bats)

1b. Facial stripes indistinct; ears with brownish edges.

42

1b (Sturnira)

Sturnira tildae (44-48 mm) Sturnira magna (55-60 mm)

Ametrida centurio (24-33 mm)

Sphaeronycteris toxophyllum (37-42 mm)

1a. Facial stripes distinct; ears with white edges.

1a (Sturnira)

Sturnira lilium (36-45 mm)

Uroderma bilobatum (39-45 mm) Uroderma magnirostrum (39-45 mm)

1a (Sturnira)

Ametrida centurio

1a (Uroderma)

1b (Sturnira)

Sphaeronycteris toxophyllum (♂)

1b (Uroderma)

Field Guide to Amazonian Bats

1a (Sturnira)

1b (Sturnira)

Sphaeronycteris toxophyllum (♀)

1a (Uroderma)

1b (Uroderma)

Sturnira tildae

43

Field Guide to Amazonian Bats

Phyllostomidae / Stenodermatinae

Enchistenes (Velvety fruit-eating bat) 1a. Only one species in the genus.

Enchisthenes hartii (36-42 mm)

Dermanura (Fruit-eating bats) 1a. Uropatagium furry.

Dermanura anderseni (38-40 mm)

1b. Uropatagium bare. 2a. Facial stripes indistinct; V-shaped uropatagium.

Dermanura glauca (37-42 mm) 2b. Facial stripes distinct; U-shaped uropatagium; ears and base of noseleaf with white-to-yellow edges. Dermanura gnoma / cinerea * (34-42 mm)

1a

1b 2a

1b

1b 2b

* We recommend classification as D. gnomus / cinerea until more external morphological data are available for reliable identification in the field.

44

1a

1b

1b 2a

1b 2b

1b 2a

1b 2b

1b 2b

Enchistenes hartii

Field Guide to Amazonian Bats

1a 2b

Dermanura gnoma

45

Field Guide to Amazonian Bats

Phyllostomidae / Stenodermatinae

Artibeus (Fruit-eating bats) 1a. FA < 55 mm.

Artibeus concolor (43-52 mm)

1b. FA > 55 mm. 2a. Facial stripes indistinct. 3a. Presence of a few hairs longer than fur. 3b. Absence of hairs longer than fur.

2b. Facial stripes evident. 3a. Uropatagium dorsally furry. 3b. Uropatagium not furry.

Artibeus obscurus (55-65 mm)

Artibeus lituratus (65-78 mm)

4a. Bottom of noseleaf separate from lip.

Artibeus planirostris (56-73 mm)

4b. Bottom of noseleaf embraces the lip.

1b 2b 3a

Artibeus planirostris (56-73 mm)

Artibeus amplus (65-74 mm)

1b 2b 3b

Notice the bottom part of the noseleaf embracing the lip.

1b 2b 3b 4a 46

1b 2b 3b 4b

1b 2a

1b 2b

1b 2b 3b 4a

1b 2b 3b 4b

1b 2b 3a

Field Guide to Amazonian Bats

Thy

1b 2b 3b

Artibeus obscurus

47

Field Guide to Amazonian Bats

Phyllostomidae / Stenodermatinae

Platyrrhinus & Vampyrodes (White-lined fruit bats & Great stripe-faced bat) 1a. FA > 54 mm. 1b. FA 43-55 mm.

1c. FA < 42 mm

Platyrrhinus infuscus (54-62 mm) Platyrrhinus aurarius (51-54 mm) / Vampyrodes caraccioli (46-57 mm) Platyrrhinus lineatus (43-52 mm) *

2a. V-shaped uropatagium. 2b. U-shaped uropatagium.

Platyrrhinus fusciventris (35-40 mm)

Platyrrhinus incarum (33-42 mm) / Platyrrhinus brachycephalus (33-42 mm)

1c 2a

1c 2b

* We recommend classification as P. aurarius / V. caraccioli / P. lineatus and P. incarum / P. brachycephalus until more external morphological data are available for reliable identification in the field.

48

1c 2a

1c 2b

Field Guide to Amazonian Bats

Thy

Vampyrodes caraccioli

Fieldwork (Central Amazon)

49

Field Guide to Amazonian Bats

Phyllostomidae / Stenodermatinae

Chiroderma (Big-eyed bats) 1a. FA > 44 mm; facial stripes faint; dorsal stripe absent. 1b. FA < 43 mm; facial stripes distinct; dorsal stripe present.

Chiroderma villosum (44-50 mm) Chiroderma trinitatum (38-43 mm)

Vampyressa & Vampyriscus (Yellow-eared bats) 1a. Two lower incisors.

Vampyriscus bidens (34-38 mm)

1b. Four lower incisors. 2a. Dorsal line faint. 2b. Dorsal line absent; FA < 34 mm.

1a

Vampyriscus brocki (29-35 mm) Vampyressa pusilla / thyone * (30-36 mm)

1b

Mesophylla (Macconnell’s bat) 1a. Only one species in the genus.

Mesophylla macconnelli (29-34 mm)

* We recommend classification as V. pusilla / thyone until more external morphological data are available for reliable identification in the field.

50

Field Guide to Amazonian Bats

1a (Chiroderma)

1b (Chiroderma)

1a (Chiroderma)

1b (Chiroderma)

1a (Vampyr.)

1b (Vampyr.)

1b 2a

1b 2b

Thy

Mesophylla macconnelli

Mesophylla macconnelli

51

Field Guide to Amazonian Bats

Phyllostomidae / Phyllostominae

1a. Well-developed protuberances on lips and chin. Trachops

1b. Cup-shaped noseleaf; FA > 75 mm. 2a. FA > 100 mm; tail absent.

Vampyrum

2b. FA < 100 mm; tail present.

Chrotopterus

1c. Two lower incisors. 2a. Noseleaf long and blade-shaped; furry ears.

Mimon

2b. Noseleaf not as above; ears bare.

Lophostoma / Tonatia

1d. Four lower incisors. 2a. Tail extending to the edge of the uropatagium. 3a. FA > 40 mm; noseleaf length > 3 times its width; uropatagium pointed with no rows of dots.

3b. FA < 40 mm; noseleaf length < 3 times its width; uropatagium squarish with rows of dots.

Lonchorhina

Macrophyllum

2b. Tail not extending to the edge of the uropatagium.

1c 52

1d

1d 2a

1d 2b

Field Guide to Amazonian Bats

1a

1b

1c

1d

1d

1b 2b

1c 2a

1c 2a

1c 2b

1c 2b

1d 2a

1d 2b

1d 2a 3a

1d 2a 3b

1d 2a 3b

53

Field Guide to Amazonian Bats

Phyllostomidae / Phyllostominae

3a. FA > 58 mm; chin with flat round bumps. 4a. Wing tips dark; face furry.

Phyllostomus

4b. Wing tips whitish; face bare.

Phylloderma

3b FA < 58 mm; chin with smooth elongated pads in V-shape. 4a. Inner upper incisors length equal to canines.

Glyphonycteris

4b. Upper incisors clearly shorter than canines. 5a. FA < 35 mm.

Neonycteris

5b. FA > 35 mm.

54

3a

3b

3b 4a

3b 4b

Field Guide to Amazonian Bats

3a

3b

3a 4a

3a 4b

3a 4a

3a 4b

3b 4a

3b 4b

Phylloderma stenops

55

Field Guide to Amazonian Bats

Phyllostomidae / Phyllostominae

6a. Ears rounded and connected by an interauricular band of skin.

Micronycteris

6b. Ears pointed but not connected by an interauricular band of skin. 7a. Fur bicoloured; ear length < 16 mm; calcar > or = foot; upper incisors blade-like and aligned with canines. 7b. Fur tricoloured; ear length > 16 mm; calcar < foot; upper incisors not bladelike and project forward.

6b 7a

56

6b 7b

Lampronycteris

Trinycteris

Field Guide to Amazonian Bats

6a

6b

6a

6b

6b 7a

6b 7b

6b 7a

6b 7b

6b 7a

6b 7b

6b 7b

Trinycteris nicefori

57

Field Guide to Amazonian Bats

Phyllostomidae / Phyllostominae

Trachops (Frog-eating bat) 1a. Only one species in the genus.

Trachops cirrhosus (57-66 mm)

Vampyrum (Spectral bat) 1a. Only one species in the genus.

Chrotopterus (False vampire bat) 1a. Only one species in the genus.

Mimon (Gray’s spear-nosed bats)

Vampyrum spectrum (88-114 mm)

Chrotopterus auritus (77-87 mm)

1a. Dorsal stripe absent; noseleaf smooth and bare; wing attached to ankle. 1b. Dorsal stripe present; noseleaf serrated and hairy; wing attached to foot.

1a 58

Mimon bennettii (51-59 mm) Mimon crenulatum (46-55 mm)

1b

Trachops cirrhosus

Field Guide to Amazonian Bats

Vampyrum spectrum

Chrotopterus auritus

1a

1b

1a

1b

Trachops cirrhosus

1a

1b 59

Field Guide to Amazonian Bats

Phyllostomidae / Phyllostominae

Lophostoma & Tonatia (Round-eared bats) 1a. Venter pure white. 1b. Venter pale brown to brown.

Lophostoma carrikeri (43-50 mm)

2a. FA < 49 mm. 3a. Small warts on forearm. 3b. No warts on forearm. 2b. FA > 50 mm.

Lophostoma schulzi (42-45 mm) Lophostoma brasiliense (32-36 mm)

3a. Forearm furry; ears separate. 4a. Faint stripe between ears. 4a. No stripe between ears. 3b. Forearm bare; ears connected by band.

Lonchorhina (Sword-nosed bats) 1a. FA 52-57 mm; long muzzle. 1b. FA > 47-54 mm; short muzzle.

60

Tonatia saurophila (51-59 mm) Tonatia bidens (48-60 mm) Lophostoma silvicola (49-60 mm)

Lonchorhina inusitata (52-57 mm) Lonchorhina aurita (47-54 mm)

Field Guide to Amazonian Bats

1a (Lop. & Ton.)

1b (Lop. & Ton.)

1b 2a 3a

1b 2a 3b

1b 2b 3a

1b 2b 3b

1b 2b 3a

1b 2b 3b

1b 2b 3a 4a

1b 2b 3a 4b

1a (Lonchorhina)

1b (Lonchorhina)

Lophostoma carrikeri

61

Field Guide to Amazonian Bats

Phyllostomidae / Phyllostominae

Macrophyllum (Long-legged bat) 1a. Only one species in the genus.

Macrophyllum macrophyllum (32-40 mm)

Phyllostomus (Spear-nosed bats) 1a. FA > 75 mm.

1b. FA < 75 mm. 2a. Calcar < Hindfoot.

2b. Calcar > Hindfoot.

Phyllostomus hastatus (77-93 mm)

Phyllostomus discolor (55-69 mm)

3a. FA 61–69 mm; tibia > 24 mm; venter dark with no frosting. Phyllostomus elongatus (61-71 mm) 3b. FA 56–61 mm; tibia < 24 mm; venter dark with frosting. Phyllostomus latifolius (56-61 mm)

Phylloderma (Pale-faced bat) 1a. Only one species in the genus.

Phylloderma stenops (65-83 mm)

Glyphonycteris (Gray-bearded bats) 1a. FA > 50 mm; two upper incisors. 1b. FA < 45 mm; four upper incisors.

1a 62

Glyphonycteris daviesi (52-59 mm) Glyphonycteris sylvestris (37-44 mm)

1b

Macrophyllum macrophyllum

1b 2b 3a

Phylloderma stenops

1b 2b 3b

Field Guide to Amazonian Bats

1b 2a

1b 2b

1a (Glyphonycteris)

Phyllostomus discolor

63

Field Guide to Amazonian Bats

Phyllostomidae / Phyllostominae

Neonycteris (Least big-eared bat) 1a. Only one species in the genus.

Micronycteris (Big-eared bats)

Neonycteris pusilla (33-35 mm)

1a. Dark venter. 2a. FA > 41 mm; lower incisors narrow. 2b. FA < 37 mm. 3a. Ears < 22 mm. 3b. Ears > 22 mm. 1b. Venter white or pale.

1a 2a 64

Micronycteris hirsuta (40-46 mm)

Micronycteris megalotis (31-36 mm) Micronycteris microtis (32-37 mm)

1a 2b

1a

1b

1a 2a

Field Guide to Amazonian Bats

1a 2b

Micronycteris microtis

65

Field Guide to Amazonian Bats

Phyllostomidae / Phyllostominae

2a. Calcar > Hindfoot. 3a. FA 33–38 mm; tibia > 14.5 mm.

Micronycteris schmidtorum (33-38 mm)

3b. FA 31-34 mm; tibia < 14.5 mm.

Micronycteris brosseti (31-34 mm)

2b. Calcar ≤ Hindfoot. 3a. Digit IV: 1st > 2nd phalanx. 3b. Digit IV: 1st = 2nd phalanx.

Micronycteris homezorum (34-37 mm) Micronycteris minuta / sanborni (31-37 mm) *

Trinycteris (Niceforo’s big-eared bat) 1a. Only one species in the genus.

Trinycteris nicefori (35-41 mm)

Lampronycteris (Yellow-throated big-eared bat) 1a. Only one species in the genus.

1b 2a

Lampronycteris brachyotis (38-44 mm)

1b 2b

1b 2c

* We recommend classification as M. minuta / sanborni until more external morphological data are available for reliable identification in the field.

66

2a

2b

Trinycteris nicefori

Field Guide to Amazonian Bats

2b

Lampronycteris brachyotis

Temporal lake in the Amazon

67

Field Guide to Amazonian Bats

Phyllostomidae / Carolliinae

1a. Tail short but present; dorsal fur bi- or tricoloured.

Carollia

1b. Tail absent; dorsal fur unicoloured.

1a

Rhinophylla

1b

Carollia (Short-tailed fruit bats) 1a. Faint banding pattern on dorsal fur; tibia 14–17 mm. Carollia castanea / benkeithi * (34-39 mm) 1b. Clear banding pattern on dorsal fur. 2a. FA < 39; tibia 16–17 mm. 2b. FA > 39; tibia 17–21 mm.

Carollia brevicauda ** (27-42 mm) Carollia perspicillata ** (38-44 mm)

* We recommend classification as C. castanea / benkeithi until more external morphological data are available for reliable identification in the field. ** We recommend classification as C. brevicauda / perspicillata in doubtful cases until more external morphological data are available for reliable identification in the field.

68

1a

1b

1a (Carollia)

1b (Carollia)

1a

Field Guide to Amazonian Bats

1b

Carollia perspicillata

69

Field Guide to Amazonian Bats

Phyllostomidae / Carolliinae

Rhinophylla (Little fruit bats) 1a. Uropatagium with bare edge; legs very furry; no gap between upper incisor and canine.

Rhinophylla pumilio (33-36 mm) 1b. Uropatagium with furry edge; legs bare; gap between upper incisor and canine. Rhinophylla fischerae (29-34 mm)

1a

1a 70

1b

1b

1a

Field Guide to Amazonian Bats

1a

Rhinophylla pumilio

71

Field Guide to Amazonian Bats

Thyropteridae (Disc-winged bats)

The family Thyropteridae is composed of five species of small-sized aerial insectivorous bats, all belonging to the genus Thyroptera. The common name, disc-winged bats, derives from the characteristic fleshy pads (“suckers�) present at the base of the thumbs and ankles that are used to cling to the smooth walls of unfurling leaves of Heliconia and related bananalike plants in which they roost. As these leaves change from folded-up to flat, bats have to find another leaf with the proper shape in which to roost, so their small colonies are constantly on the move. Disc-winged bats tend to inhabit moist tropical rainforests and are found from southern Mexico to southern Brazil. The family is regarded as primitive and its members have a domed skull, a slender muzzle and, like the Natalidae and Furipteridae, funnelshaped ears. Their small thumbs are also characteristic, and a short tail extends beyond the interfemoral membrane. The dorsal fur is brownish-to-black and some species have whitish ventral fur. Thyroptera tricolor

72

Field Guide to Amazonian Bats

73

Field Guide to Amazonian Bats

Thyropteridae (Disc-winged bats)

Thyroptera (Disc-winged bats) 1a. Thumb with oval disk; ventral fur bicoloured or tricoloured. 2a. FA > 35; ventral fur bicoloured; FA barely haired near the body. 3a. Ventral fur clearly frosted; hairs dark brown-toblackish at the base, with pale-brown-to-whitish tips; calcar without lobes (sometimes just a single faintly developed lobe). 3b. Ventral fur bicoloured, not frosted; calcar with one welldeveloped lobe. 2b. FA < 34.5; ventral fur tricoloured; FA densely hairy. 1b. Thumb with round disk; ventral fur unicoloured.

1a 74

1b

Thyroptera lavali (37-41 mm)

Thyroptera wynneae (33-35 mm)

2a. Ventral fur white or pale grey; FA slightly hairy near the body. 2b. Ventral fur yellowish-brown; FA densely hairy.

Thyroptera devivoi (35-38 mm)

Thyroptera tricolor (33-40 mm)

Thyroptera discifera (32-35 mm)

1a 2a 3a

1a 2a 3b

1a

1b

Field Guide to Amazonian Bats

1b 2a

Potential Thyroptera roost

75

Field Guide to Amazonian Bats

Furipteridae (Smoky bats)

The Furipteridae, known as smoky bats, is one of the smallest bat families and only contains two species: the smoky bat Amorphochilus schnablii and the thumbless bat Furipterus horrens. These small insectivorous bats have relatively long wings, domed skulls, funnel-shaped ears, and a delicate appearance, and resemble bats from the Thyropteridae and Natalidae to which they are closely related. The family’s characteristic feature is the minute and functionless thumb, which is partly enveloped by the wing membrane. Its common name arises from the greyish color of its fur. Of these two species, only the thumbless bat Furipterus horrens is known from the Amazon.

Furipterus (Thumbless bat) 1a. Only one species in the genus.

76

Furipterus horrens (30-40 mm)

Field Guide to Amazonian Bats

77

Field Guide to Amazonian Bats

Noctilionidae (Bulldog bats)

Commonly known as bulldog or fishing bats, the Neotropical family Noctilionidae is represented by a single genus, Noctilio, containing two largely sympatric species, Noctilio leporinus and Noctilio albiventris. However, recent genetic evidence suggests that N. albiventris in fact consists of three lineages and that there is much cryptic diversity within this taxon. Noctilionidae are found near water bodies from Mexico to Argentina (including the Caribbean Islands). They are medium-sized bats, with large drooping lips (hence the name ‘bulldog bats’) and relatively long legs. Their fur varies from orange to dark brown in color and their wings are long and narrow. The lesser bulldog bat Noctilio albiventris is mostly insectivorous, unlike the greater bulldog bat Noctilio leporinus. This latter species uses echolocation to detect ripples in water made by moving fish, which it then catches with its long legs and claws. Fish are eaten whilst perched and are sometimes stored in cheek pouches, an unusual feature in bats. This bat forages above coastal waters, rivers, and lakes, and can swim and even take off from the water surface.

78

Noctilio leporinus

Field Guide to Amazonian Bats

79

Field Guide to Amazonian Bats

Noctilionidae (Bulldog bats)

Noctilio (Bulldog bats) 1a. FA < 70 mm; feet and claws shorter than uropatagium. 1b. FA > 70 mm; feet and claws extend past the uropatagium.

1a

80

Noctilio albiventris (54-70 mm) Noctilio leporinus (70-90 mm)

1b

1a

Field Guide to Amazonian Bats

1b

Amazon River

81

Field Guide to Amazonian Bats

Mormoopidae (Moustached bats)

The family Mormoopidae is composed of two genera, the mustached or nakedbacked (Pteronotus) and the ghost-faced (Mormoops) bats. They are small to medium-sized and have characteristic wart-like projections above their nostrils and a small tail emerging from the dorsal surface of the uropatagium. Mormoopids are found from humid tropical to semiarid and arid sub-tropical habitats below 3,000 m throughout the New World, from the southwestern USA to southeastern Brazil, including the Greater Antilles. The family’s two genera can be separated by the presence of narrow (Pteronotus) or funnel-shaped (Mormoops) ears. The common names of Pteronotus are due to a peculiar fringe of long hairs around the mouth and to its wing membranes that, in some species, join over the middle of the back, giving an impression of hairlessness. The combination of hairs around the mouth and flaps on the lower lip are thought to funnel insects into the bat’s mouth and focus echolocation pulses.

Pteronotus parnellii

82

Field Guide to Amazonian Bats

83

Field Guide to Amazonian Bats

Mormoopidae (Moustached bats)

Pteronotus (Moustached bats) 1a. Bare back; wings attached on the middle of dorsum. 2a. FA < 49 mm.

Pteronotus davyi (40-49 mm)

2b. FA > 49 mm. 1b. Furry back; wings attached to the side of body. 2a. FA > 50 mm.

Pteronotus gymnonotus (50-55 mm)

Pteronotus cf parnellii * (50-63 mm)

2b. FA < 50 mm.

Pteronotus cf personatus (40-48 mm)

1a

1b

* Cryptic species complex. We recommend using acoustic and/or genetic data for species identification (see also echolocation keys at the end of this guide).

84

1a

Field Guide to Amazonian Bats

1b

Pteronotus cf. parnellii

85

Field Guide to Amazonian Bats

Emballonuridae (Sac-winged bats)

The Emballonuridae is a pantropical family that in the New World is found from northern Mexico to southern Brazil. Some Neotropical species of this family possess sac-shaped glands near their shoulders, which explains the origin of the family’s common name (sac-winged bats). These glands are usually more prominent in males and are used to produce pheromones. Emballonurids are small aerial insectivorous bats, with relatively large eyes and long, narrow wings. These wings are so long that at rest they have one more fold than other bats. Most species are brown, but the four Diclidurus species, known as ghost bats, can vary from pale brownish to white and have distinctive pink wings, ears, and face. Most members of the genus Saccopteryx have two thin dorsal stripes that are especially evident in the greater sac-winged bat S. bilineata. Some, like the water-associated proboscis bat Rhynchonycteris naso, take advantage of their pale grey and yellowish fur to camouflage themselves on lichen-covered branches and wooden beams, and roost in a curious straight-lined, nose-to-tail formation. 86

Saccopteryx leptura

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Emballonuridae (Sac-winged bats)

1a. Fur white or whitish; wing sac on the uropatagium.

Diclidurus

1b. Fur not whitish; no wing sacs on the uropatagium. 2a. Wing sacs absent. 3a. Ears rounded; fur dark grey; small thumb.

Cyttarops

3b. Combination not as above. 4a. Muzzle long; forearm with several clusters of hair; fur grizzly brown; two pale stripes on back; wings attached to ankle. 4b. Muzzle not long; forearm bare; fur yellowish or brownish; parallel rows of dots on the uropatagium; wings attached to base of toes. 2b. Wing sacs present in the propatagium.

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1a

1b

1b 2a 3a

1b 2a 3b

Rhynchonycteris

Centronycteris

1c (both types)

1b 2a 3b 4a

1b 2a 3b 4b

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1a

1b

1b 2a

1b 2b

1b 2a 3a

1b 2a 3b

1b 2a 3b 4a

1b 2a 3b 4b

1b 2a 3b 4a

1b 2a 3b 4b

1b 2a 3b 4a

1b 2a 3b 4b

1b 2a 3b 4a

1b 2a 3b 4b

1b 2a 3b 4b

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Emballonuridae (Sac-winged bats)

3a. Wing sac perpendicular to the FA; fur on back without stripes. 4a. Faint wing sacs not reaching (few mm) the edge of propatagium; wings attached near base of toe.

Cormura

4b. Wing sacs prominent, reaching the anterior edge of wing; wings attached above ankle. 3b. Wing sac close to the elbow and parallel to the FA; two white lines on back (faint or absent in one species).

3a 4a

3a 4b

3a 4a 90

Peropteryx Saccopteryx

3b

3a 4b

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3a

3b

3a

3b

3a 4a

3a 4b

3a 4a

3a 4b

3a 4a

3a 4b

Saccopteryx leptura

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Emballonuridae (Sac-winged bats)

Diclidurus (Ghost bats) 1a. Wings pale brown; large thumb; fur sometimes dirty white.

Diclidurus isabellus (41-44 mm)

1b. Wings white or pale pink; small thumb; fur white. 2a. FA > 69 mm.

Diclidurus ingens (70-73 mm)

2b. FA < 69 mm. 3a. FA > 60 mm.

Diclidurus albus (63-69 mm)

3b. FA < 60 mm.

Diclidurus scutatus (51-59 mm)

Cyttarops (Short-eared bat) 1a. Only one species in the genus.

Rhynchonycteris (Proboscis bat) 1a. Only one species in the genus.

Cyttarops alecto (45-47 mm)

Rhynchonycteris naso (35-41 mm)

Centronycteris (Shaggy bats) 1a. Body length < 65 mm. 1b. Body length > 65 mm.

Cormura (Chestnut sac-winged bat) 1a. Only one species in the genus.

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Centronycteris maximiliani (41-45 mm) Centronycteris centralis (42-48 mm)

Cormura brevirostris (41-50 mm)

1a 2a

1a

1b

1a 2a 3a

1a 2a 3b

Centronycteris centralis

Field Guide to Amazonian Bats

Centronycteris maximilani

Cyttarops alecto

1a 2b

Rhynchonycteris naso

Cormura brevirostris

Rhynchonycteris naso

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Emballonuridae (Sac-winged bats)

Peropteryx (Dog-like sac-winged bats) 1a. Wings white. 2a. Ears connected by band.

Peropteryx leucoptera (41-46 mm)

2b. Ears not connected by band.

Peropteryx pallidoptera (37-43 mm)

1b. Wings dark. 2a. FA > 43 mm.

Peropteryx kappleri / macrotis * (43-52 mm)

2b. FA < 43 mm.

Peropteryx trinitatis (36-43 mm)

Saccopteryx (Two-lined sac-winged bats) 1a. FA > 45 mm.

Saccopteryx bilineata (45-51 mm)

1b. FA < 43 mm. 2a. Dorsal fur clearly bicoloured and frosted. 2b. Dorsal fur unicoloured or faintly bicoloured.

Saccopteryx canescens (35-40 mm)

3a. FA < 36 mm; faint stripes on back; ventral fur unicoloured. Saccopteryx gymnura (33-36 mm) 3b. FA > 36 mm; distinct pale stripes on back; ventral fur bicoloured. Saccopteryx leptura (36-42 mm)

1a 2a

1a 2b

* We recommend classification as P. kappleri / macrotis until more external morphological data are available for reliable identification in the field.

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1a 2a (Peropteryx)

1a 2b (Peropteryx) 1b (Peropteryx)

1a (Saccopteryx)

1b (Saccopteryx)

1b 2a

1b 2b

1b 2b 3a

1b 2b 3b

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Rhynchonycteris naso

1b 2b 3a

1b 2b 3b

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Vespertilionidae (Evening bats)

Vespertilionids, commonly known as vesper or evening bats, are the largest bat family. This near cosmopolitan family harbours more than 300 species and is present on all continents except Antarctica, as such being one of the most widespread of all mammalian groups. Five vesper bat genera are known from South America, of which four – Eptesicus, Lasiurus, Myotis, and Rhogeessa – have been reported from the Amazon. They are small to large in size, have no noseleaf, and have ears with a simple tragus and usually large tail membranes that they use to capture the insects they prey upon. Vesper bats are mostly insectivorous but some Old World species have been reported to capture and consume fish and birds. The genera Eptesicus, Myotis, and Rhogeessa are mostly brown and black. However, the hairy-tailed bats of the genus Lasiurus are unusually colorful, and have long dense fur that can vary from bright yellow to red-orange. Another peculiarity of this genus is the extra pair of nipples (four in total) that allow females to give birth on occasions to quadruplets. They thrive in a wide range of habitats and exploit virtually all types of available roost sites.

Lasiurus sp.

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Vespertilionidae (Evening bats)

1a. Ears large 28–32 mm.

Histiotus

1b. Ears small < 27 mm. 2a. Uropatagium furry.

Lasiurus

2b. Uropatagium bare. 3a. Two upper incisors.

Rhogeessa

3b. Four upper incisors. 4a. No gap after upper canine; tragus somewhat curved.

Eptesicus

4b. Gap after upper canine; tragus straight and pointed.

Myotis

1a

1b 2b 3a 98

1b

1b 2b 3b

1b 2a

1b 2b 3b 4a

1b 2b

1b 2b 3b 4b

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1a

1b

1b 2a

1b 2b

1b 2b 3a

1b 2b 3b

1b 2b 3b 4a

1b 2b 3b 4b

1b 2b 3b 4a

1b 2b 3b 4b

Myotis riparius

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Vespertilionidae (Evening bats)

Histiotus (Evening big-eared bat) 1a. Only one species in the Amazon.

Lasiurus (Hoary bats)

Histiotus velatus (42-50 mm)

1a. Dorsal fur reddish. 2a. Dorsal and ventral fur reddish. 2b. Dorsal fur reddish; venter brownish or greyish buff; wings reddish along the metacarpals.

Lasiurus egregius (48-50 mm)

Lasiurus blossevillii (36-43 mm) 2c. Dorsum reddish; venter blackish (sometimes with some white); wings completely black. Lasiurus castaneus / atratus * (43-47 mm) 1b. Dorsal fur yellowish. 2a. Fur without frosting; FA < 51 mm. 2b. Fur with frosted tips; FA > 50 mm.

Rhogeessa (Little yellow bats) 1a. FA < 30 mm. 1b. FA > 29 mm.

Lasiurus ega (40-52 mm) Lasiurus cinereus (50-57 mm)

Rhogeessa io (27-30) Rhogeessa hussoni (29-31)

* We recommend classification as L castaneus / atratus until more external morphological data are available for reliable identification in the field.

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1a

1b

1a 2a

1a 2b

1a 2b

1a 2c

1a 2c

1a 2c

1b 2a

1b 2a

1b 2b

Histiotus velatus

Lasiurus egregius

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Vespertilionidae (Evening bats)

Eptesicus (Big brown bats) 1a. Dorsal hair relatively short < 7 mm. 2a. FA < 37 mm. 2b. FA 36-43 mm; venter yellowish. 2c. FA > 41 mm; venter brownish.

Eptesicus diminutus * (30-37 mm) Eptesicus furinalis * (36-43 mm) Eptesicus brasiliensis * (40-47 mm)

1b. Dorsal hair relatively long > 7 mm. 2a. FA < 44 mm. 2b. FA > 43 mm.

Eptesicus andinus * (37-44 mm) Eptesicus chiriquinus * (42-49 mm)

* In cases where measurements overlap, we recommend classification as E. diminutus / furinalis, E. furinalis / brasiliensis and E. andinus / chiriquinus, until more external morphological data are available for reliable identification in the field.

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1a

1b

1b 2a

1b 2b

1a 2b

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1a 2c

Eptesicus brasiliensis

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Vespertilionidae (Evening bats)

Myotis (Little brown bats) 1a. Wings attached along the tibia.

Myotis simus (36-41 mm)

1b. Wings not attached along the tibia. 2a. Dorsal fur very black and frosted; venter whitish. 2b. Combination not as above. 3a. Second upper premolar not aligned with other premolars. 3b. Second upper premolar aligned with other premolars.

1a 104

1b

1b 2b 3b 4a

Myotis albescens (31-37 mm)

Myotis riparius (31-38 mm) Myotis nigricans (30-38 mm)

1b 2b 3b 4b

1a

1b

1b 2b 3a

1b 2b 3b

1b 2a

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1b 2b

Myotis riparius

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Molossidae (Free-tailed bats)

The Molossidae is a near cosmopolitan family that, like the Vespertilionidae, is present on all continents. They are divided into two sub-families, the Molossinae and the Tomopeatinae, the latter including just one species, the blunt-eared bat Tomopeas ravus that is endemic to Peru. Molossids have relatively long narrow wings and are adapted to rapid flight in open spaces. They are strong fliers and can cover large distances every night in search of food. Their common name, free-tailed bats, comes from their long tails that project beyond the uropatagium. Their wing and tail membranes are usually very tough, their ears tend to be tilted forward, stiff, and joined along part of their length, their legs are short and robust, and their feet have long sensory hairs. Neotropical species are mostly brown or black, although there are some exceptions such as the black mastiff bat Molossus rufus, which can be reddish in colour. Several species have throat glands that are less conspicuous in females.

Cynomops

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Molossidae (Free-tailed bats)

1a. Upper lip with deep vertical lines; ears joined.

Nyctinomops

1b. Upper lip with no vertical lines. 2a. Muzzle between eyes and nose with a ridge. 3a. Four lower incisors; lower posterior edge of ear thin and narrow. 3b. Two lower incisors; lower posterior edge of ear flattened laterally. 2b. Muzzle flat, almost horizontal. 3a. Squarish mouth when viewed ventrally, ears long and joined, reaching the nose when flattened. 3b. Triangular mouth when viewed ventrally; ears not joined, and do not reach the nose when flattened. 4a. Muzzle and ears both pointed; dorsal fur continues onto face. 4b. Muzzle and ears both rounded; dorsal fur behind the ears.

1b 2a 3a 108

1b 2a 3b

1b 2b 3b 4b 5a

Promops Molossus

Eumops

Molossops Cynomops

1b 2b 3b 4b 5b

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1a

1b

1b 2a

1b 2b

1b 2a 3a

1b 2a 3b

1b 2a 3a

1b 2a 3b

1b 2b 3a

1b 2b 3b

1b 2b 3a

1b 2b 3b

1b 2b 3a

1b 2b 3b

1b 2b 3b 4a

1b 2b 3b 4b

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Molossidae (Free-tailed bats) Nyctinomops (Broad-eared free-tailed bats) 1a. FA 58–65. 1b. FA 48-53. 1c. FA 40–48.

Promops (Crested mastiff bats) 1a. FA ≤ 51. 1b. FA ≥ 51.

Temporary lake in the Amazon

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Nyctinomops macrotis (58-65 mm) Nyctinomops aurispinosus (48-53 mm) Nyctinomops laticaudatus (40-48 mm)

Promops nasutus (45-51) Promops centralis (51-57)

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Molossidae (Free-tailed bats)

Molossus (Common mastiff bats) (There is great uncertainty regarding the taxonmy of this group. Here we follow the nomenclature of Nogueira et al. 2014+) 1a. Dorsal fur unicoloured* 2a. FA 46–54 mm; face and membranes black (orangish-toblackish fur).

Molossus rufus * (46-54 mm) 2b. FA 41–49 mm; face and membranes not black, somewhat paler. Molossus pretiosus * (41-49 mm) 1b. Dorsal fur faint to clearly bicoloured. 2a. Dorsal fur faintly bicoloured. 3b. FA 35-37 mm. 2b. Dorsal fur bicoloured. 3a. FA > 46 mm. 3b. FA 37-46 mm. 3c. FA < 36 mm.

Molossus coibensis (35-37 mm)

Molossus sinaloae (46-50 mm) Molossus molossus / currentium ** (37-46 mm) Molossus sp. *** (33-36 mm)

* Highly varied fur colour. The photographs highlight some of the range of colours. ** We recommend classification as M. molossus / currentium until more external morphological data are available for reliable identification in the field. *** Some records of smaller Molossus sp. exist that are awaiting phylogenetic and morphometric revision to determine their true taxonomic status. + Nogueira, M.R., et al. 2014. Checklist of Brazilian bats, with comments on original records. Check List, 10(4), pp.808-821.

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1a

1a

1b

1a 2a

1a 2a

1a 2b

1b 2a

1b 2b

Molossus rufus

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Molossidae (Free-tailed bats)

Eumops (Bonnetted bats) 1a. FA < 55 mm. 2a. Band of pure white fur along the venter/wing border. Eumops maurus (51-53 mm) 2b. No band of pure white fur along the venter/wing border. 3a. FA < 41 mm.

Eumops hansae * (37-41 mm)

3b. FA > 43 mm.

Eumops bonariensis / delticus ** (46-50 mm)

1b. FA > 55 mm. 2a. Ear > 35 mm. 3a. FA > 74 mm.

Eumops perotis (75-84 mm)

3b. FA < 74 mm.

Eumops trumbulli (58-75 mm)

2b. Ear < 35 mm. 3a. Tragus pointed.

Eumops auripendulus (54-68 mm)

3b. Tragus broad and square.

1b 2b 3a

Eumops glaucinus (56-65 mm)

1b 2b 3b

* Sometimes considered as a cryptic species complex including E. nanus. ** We recommend classification as E. bonariensis / delticus until more external morphological data are available for reliable identification in the field.

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1a 2a

1a 2b

1b 2b 3a

1a

1b 2a

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1b 2b

Eumops maurus

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Molossidae (Free-tailed bats)

Molossops (Dog-faced bats) 1a. FA with tiny bumps.

Neoplatymops mattogrossensis (27-33 mm)

1b. FA with no bumps. 2a. FA > 34 mm; venter dark.

Molossops neglectus (34-37 mm)

2b. FA < 33 mm; venter frosted.

Cynomops (Dog-like bats)

Molossops temminckii (27-32 mm)

1a. FA > 40 mm.

Cynomops abrasus (40-52 mm)

1b. FA < 40 mm.

2a. Four lower incisors; dorsal fur dark brown, venter pale. Cynomops planirostris / paranus * (29-37 mm) 2b. Four lower incisors; dorsal and ventral fur uniformly dark brown 2c. Two lower incisors; dorsal fur chestnut.

1b 2a

Cynomops milleri (30-33 mm)

Cynomops greenhalli (33-39 mm)

1b 2b

* We recommend classification as C. planirostris / paranus until more external morphological data are available for reliable identification in the field.

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1b 2b 3b 4a

1b 2b 3b 4b

1b 2a (Molossops 1b 2b (Molossops neglectus)

temminckii)

1b 2a

1b 2a

1b 2a

1b 2c

Cynomops abrasus

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Natalidae (Funnel-eared bats)

Natalus macrourus

This Neotropical family comprises three genera containing six species of small, delicate, insectivorous bats. The family’s common name, funnel-eared bats, derives from their large forward-pointing, funnel-like ears. These bats are characterised by their short thumbs and unusually long legs and tails. Their wings are broad, thereby giving good maneuverability that facilitates their gleaning foraging strategy. Funnel-eared bats roost colonially in humid caves. Natalidae are distributed from Paraguay to northern Mexico and the West Indies, where they reach their greatest diversity. Only two species, Natalus stramineus and N. tumidirostris, are known to occur in South America and both have been recorded in the Amazon.

1a. Rostrum swollen. 1b. Rostrum not swollen.

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Natalus tumidirostris (36-42) Natalus macrourus (35-41)

1a

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1b

Maroaga Cave - Presidente Figueiredo, Amazonas State, Brazil

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Echolocation

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keys

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Field Guide to Amazonian Bats

Echolocation keys Across most of the Neotropics, aerial insectivorous bats remain poorly studied. Aerial-hawking insectivorous bats are usually difficult to capture by mistnetting and the best technique for studying them is the use of ultrasound recording devices. However, the echolocation calls of many Neotropical aerial insectivorous bats are still inadequately described. Thus, intensified research efforts are urgently required to fill gaps in knowledge so that acoustic sampling can be used to its full potential in environmental impact assessments and monitoring programs. In terms of acoustic sampling techniques, the advent of automatic and fully autonomous recording stations has opened up new avenues for studying Neotropical aerial insectivorous bats. However, reliable analysis of the data generated by acoustic surveys and monitoring studies requires the creation of a good call reference library for the bats of the study region. Currently, this kind of information is largely lacking for areas such as the Amazon. It is well known that some species’ echolocation calls are often similar and have considerable overlap in frequencies, which can complicate identification and even render findings unreliable. In addition, factors such as weather conditions, geographic location, habitat structure, flight height, and various other physiological and environmental factors can give rise to great variation in call structure within a particular species. Sex, age and reproductive status are other sources of variation, as has been found for several species. Thus, it is essential to quantify differences in echolocation call structure within and among tropical species to allow accurate acoustic assessments. It is also well known that handling and processing bats after capture can alter call properties due to the stress caused to individuals, and this is one of the main problems that arises when attempting to obtain high-quality recordings for reference libraries.

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Rhynchonycteris naso

Several techniques such as discriminant function analysis, as well as, more recently, the use of synergetic pattern recognition algorithms in real time and artificial neural networks, have been employed in species identification based on echolocation call data. However, in order to develop and successfully use these techniques, an accurate description of the characteristics of the echolocation calls of all species known to occur in the study area is paramount. In the end, even with the development of new algorithms and techniques for automatic call identification, manual cross-checking and revision of results by experts remain essential.

How and what to measure?

In order to use this key properly, it is essential to understand and standardize how measurements of calls are taken. Firstly, all measurements must be taken from the harmonic that concentrates most energy, which, although varying from family to family, is usually the first or the second. All harmonics will be integer multiples of the “fundamental� frequency (first harmonic).

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Echolocation keys Bat calls are highly variable due to numerous factors such as the type of activity and surrounding environmental clutter. This variation often exacerbates overlap in the characteristics of the calls of certain species that can complicate the use of identification keys.

How should measurements be taken? The peak frequency is extracted from the power spectrum as the frequency that is recorded at the moment of greatest call intensity. Maximum and minimum frequencies can be measured on the power spectrum or on the spectrogram at the moment that the pulse differs most from the background noise. Thus, bandwidth should be calculated as the difference between the maximum and the minimum frequencies. Start and end frequencies must be measured at the point where the amplitude of the oscillogram begins to consistently rise or decrease above the background noise. This can be obtained from the spectrogram when the intensity of the call is 20dB above the background noise. Accordingly, the call duration is measured between the start and the end point of the pulse. Although not commonly referred to in other available keys, pulse intervals may be of interest and are defined as the time between the start of one pulse and the start of the subsequent one.

CF: Constant frequency QCF: Quasi-constant frequency FM: Frequency modulated FME: Frequency of maximum energy EF/SF: End frequency / Start frequency

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u: Upward modulated d: Downward modulated BW: Bandwidth MinFreq: Minimum frequency MaxFreq: Maximum frequency

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Echolocation keys Some important issues to consider before deciding to work with echolocation data Identification of Neotropical bat species by their echolocation calls is a challenging task. As stated at the beginning of this key, calls are very plastic. Some species have distinctive calls that are easy to identify, while others substantially overlap with those of other taxa, thereby making reliable species identification difficult, if not impossible. It is thus essential that anyone aiming to analyze bat acoustic data takes part in appropriate TRAINING SESSIONS to minimize data misinterpretation. This is true for both scientific studies and environmental impact assessments carried out by local consultants. Bat acoustic assessments heavily depend on the quality of the recordings since poor recordings can negatively affect identification success and the reliability of results. Thus, it is vital to understand not only how to analyze acoustic recordings but also how to properly set up detectors, calibrate microphones, and use specific recording settings (e.g. background filtering and frequency triggers). Due to the rapid increase in the number of people using acoustics as a tool for bat monitoring, several automatic algorithms are now available that can speed up classification work. The positive aspect of these algorithms is that they can generate standardized results from massive datasets with little researcher-time commitment. On the other hand, even though call analysis by experienced researchers is subjective and much more time consuming, manual call classification can give more accurate results in terms of identifying rare species, quantifying true diversity, and the presence of feeding buzzes and social calls, which are neglected in all available automatic identification software. The best processing method will clearly depend on the type of data that is hoped to be extracted from recordings and the objectives of the study. Remember that the amount of bat activity is fairly correlated with the true amount of bats flying in the area. However, bat activity is RARELY comparable between species due to differences in the detectability of their calls and dissimilarities in the structure of their calls. In conclusion: 1. Understand, prepare and place correctly your equipment in the field (attend training sessions if necessary). 2. Store your data adequately (labeled, georeferenced, and including a description of the relevant metadata). 3. State the details of the specific detector settings that were used and calibrate the microphones. 4. If you aim to quantify relative abundance, specify how exactly you will quantify it. 5. Decide which species or species-group categories will be used to classify the recordings. 6. If you combine automatic and manual classifications, explain in detail how the manual verification was undertaken and the reasoning behind your choice of specific speciesgroups and the limitations of your analysis. 8. Understand the limitations of your equipment, take special care when analyzing the data and exercise caution when interpreting your results. 9. Due to often substantial differences in species detectability (e.g. quieter vs. louder calls), activity levels between species are rarely comparable.

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Some notes on identification at family level The following pages contain two acoustic keys, one for when harmonics are clearly recorded and the other for when they are not. If the harmonics cannot be distinguished in the sonograms, try to adjust the gain and filters on your bioacoustics software in order to detect weaker harmonics and thus be able to use the first key (much simpler and reliable). If you cannot find the harmonics, follow the second key step-by-step, but be very careful with confusing or faint pulses. Do not worry about leaving many recordings as either “unidentified” or classified in “phonic groups” (including multiple species). This is preferable to ending up with a large number of incorrect species identifications. Misidentifications can lead to bad management decisions and therefore it is always better to rely on fewer, but good-quality data rather than a massive amount of low-quality data. Take into account the shape of pulses and the type of environment in which bats are recorded. Bats in highly cluttered habitats tend to greatly modulate their pulses. On the other hand, in open habitats calls tend to lose their modulated component and pulses may resemble emballonurid or molossid calls due to their almost constant-frequency components. The calls of the Molossidae and Vespertilionidae families are the most variable and can easily lead to misidentifications.

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Echolocation keys Main phonic-group selection (if you DO have harmonics recorded) 1a. FME located in the first harmonic. 2a. Pulses with at least one CF section. 2b. Mostly QCF (at least in one of the pulse types, when call sequences include alternating pulse types); sometimes with small FM cues. 2c. FM with final QCF part (very variable proportions of each type). 1b. FME located in any other harmonic. 2a. Pulses with at least one CF section. 2b. Mostly QCF, sometimes with small FM cues. 2c. FM with final QCF part with FME > 110kHz. 2d. Only FM (extremely modulated pulses). 3a. FME: 130-170kHz. 3b. FME: 100-120kHz; sometimes only first harmonic present (60kHz)

* Be aware of the great variability found in this group.

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Noctilionidae

Molossidae * Vespertilionidae *

Mormoopidae Emballonuridae Natalidae

Furipteridae

Thyropteridae

1a

1a 2a / 1b 2a

Vespertilionidae

Field Guide to Amazonian Bats

1a 2a / 1b 2b

Furipteridae

1b

1a 2a / 1b 2c

Thyropteridae 129

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Echolocation keys Main phonic-group selection (if you DO NOT have harmonics recorded) 1a. Pulses with at least one CF section.

Mormoopidae - Noctilionidae 1b. Mostly QCF (at least in one of the pulse type, when call sequences include alternating pulse types); sometimes with small FM cues. 2a. QCF/ FMd. 2b. Convex QCFu with two FMd.

Emballonuridae A

Emballonuridae B 2c. Convex QCFd with at least one FMd (one or two types of pulses). * Emballonuridae C 2d. Sinuous QCFd (two types of pulses). Molossidae A 2e. Convex QCFd with two FMu (three types of pulses). * Molossidae B 2f. Convex QCFu and concave QCFd. Molossidae C 2g. Convex QCFd and concave QCFd. Molossidae D 2h. Concave QCF (FME < 30kHz). Molossidae E

...continued on next page

* Be careful with the third upper pulses, as they sometimes cannot be properly recorded due to their low intensity, which can lead to misidentification.

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1a

Emballonuridae A

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1b

Emballonuridae B

1c

Emballonuridae C

Molossidae B

Molossidae A

Molossidae C

Molossidae D

Molossidae E 131

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Echolocation key 1c. FM with final QCF (very variable proportions of each type). FME (30 - 100kHz). 1d. FM with final QCF with FME > 110kHz. 1e. Only FM (extremely modulated pulses). 2a. FME: 130-170kHz.

Vespertilionidae Natalidae

Furipteridae 2b. FME: 100-120kHz; sometimes only first harmonic present (60kHz). Thyropteridae

Detector hanging in the forest canopy 132

Vespertilionidae

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Furipteridae

Thyropteridae

Cynomops planirostris 133

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Echolocation keys Some notes on the identification of Mormoopidae Some genera of mormoopid bats can contain several cryptic species, and geographic variation may turn out to be greater in mormoopid bats than in other families. Specifically, Pteronotus parnellii seems to be a complex, comprising more than two sympatric species in the Amazon that can be easily separated by non-overlapping peak frequencies.

Mormoopidae 1a. FMu / CF / FMd 2a. FME ≈ 55 kHz 2b. FME ≈ 60 kHz 1b. CF / FMd; SF(CF) ≈ 55 kHz * 1c. CF / FMd / CF; SF(CF) > 60 kHz 2a. SF (CF) ≈ 68-69kHz

Pteronotus cf parnellii 55kHz Pteronotus cf parnellii 60kHz Pteronotus gymnonotus

Pteronotus cf personatus

* Be careful with P. gymnonotus, as its echolocation may resemble that of P. parnellii-55kHz, especially when faint.

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Mormoopidae

Pteronotus cf parnellii 55kHz

Pteronotus cf parnellii 60kHz

Pteronotus cf parnellii 55kHz

Pteronotus gymnonotus

Pteronotus gymnonotus

Pteronotus cf personatus

Pteronotus cf parnellii 60kHz

Pteronotus cf personatus

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Echolocation keys Noctilionidae 1a. CF / FMd, sometimes alternating with QCF. ST(CF) = (68-76kHz)

Noctilio albiventris

1b. CF / FMd, sometimes alternating with QCF. ST(CF) = (53-61kHz)

Noctilio leporinus

Mormoopidae - Noctilionidae 1a. FMu / CF / FMd. 2a. FME ≈ 55 kHz. 2b. FME ≈ 60 kHz. 1b. CF / FMd; SF(CF) ≈ 55 kHz. 1c. CF / FMd; SF(CF) = (68-76 kHz). 1d. CF / FMd / CF; SF(CF) > 60 kHz. 2a. SF (CF) ≈ 68-69kHz.

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Pteronotus cf parnellii 55kHz Pteronotus cf parnellii 60kHz Pteronotus gymnonotus / Noctilio leporinus Noctilio albiventris

Pteronotus cf personatus

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Noctilionidae

Mormoopidae - Noctilionidae

Pteronotus cf parnellii 55kHz

Pteronotus cf parnellii 60kHz

Pteronotus gymnonotus / Noctilio leporinus

Pteronotus cf personatus 137

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Echolocation keys Some notes on the identification of Emballonuridae One of the most useful features for separating emballonurid species and phonic groups is the alternation of different call frequency types. However, this can be a double-edged sword and a source of misidentification. The problem lies in the fact that the last upper pulse is sometimes not recorded due to its low intensity or simply because some bats might not emit it under certain conditions. Again, it is thus recommendable to adjust the gain to try to highlight these faint pulses. If one fails to take this into account, the activity of the genus Centronycteris or of species such as Saccopteryx gymnura/canescens could be greatly overestimated, whereas the relative abundance of Saccopteryx leptura or Saccopteryx bilineata could be underestimated. Another point to bear in mind is how to determine the slope angle when separating the groups Centronycteris/Saccopteryx from Diclidurus/Peropteryx spp. Low-quality recordings with a lot of confusing background noise and faint calls are common and to avoid this it is sometimes a good idea to switch your full spectrum sonograms to a zero-crossing representation to improve the detection of the angle of the pulses.

Emballonuridae 1a. QCF/ FMd; QCF ≈ 100 kHz. 1b. Convex QCFu with 2 FMd. 1c. Convex QCFd with 2 FMd.

Emballonuridae A 1a. Only one species with this type of pulse.

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Emballonuridae A Emballonuridae B Emballonuridae C

Rhynchonycteris naso

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Emballonuridae

Emballonuridae A

Emballonuridae B

Emballonuridae C

Emballonuridae A & B

Emballonuridae C

Rhynchonycteris naso 139

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Echolocation keys Emballonuridae B 1a. One single pulse type. 2a. FME ≈ 54 kHz. Emballonuridae I (Saccopteryx gymnura / canescens) 2b. FME ≈ 40 kHz. Emballonuridae II (Centronycteris centralis / maximiliani) 2c. FME ≈ 35 kHz. Cyttarops alecto 1b. Two alternating types of pulses. * 2a. Lower pulse FME ≈ 48 kHz. Higher pulse FME ≈ 55 kHz. Saccopteryx leptura 2b. Lower pulse FME ≈ 42 kHz. Higher pulse FME ≈ 45 kHz. Saccopteryx bilineata 1c. Three alternating types of pulses. * 2a. Lower pulse FME ≈ 25 kHz. Middle pulse FME ≈ 28 kHz. Higher pulse FME ≈ 30 kHz.

Cormura brevirostris

* Be careful with the second and third upper pulses, as they sometimes cannot be properly recorded due to their low intensity, which can lead to misidentification.

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Emballonuridae I

Emballonuridae II

Saccopteryx leptura

Saccopteryx bilineata

Cormura brevirostris 141

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Echolocation keys Emballonuridae C 1a. One type of pulse. 2a. FME ≈ 42-44 kHz. Peropteryx trinitatis 2b. FME ≈ 37-39 kHz. Peropteryx macrotis 2c. FME ≈ 29-33 kHz. Peropteryx kappleri 1b. Two alternating types of pulses 2a. Lower pulse FME ≈ 26 kHz Higher pulse FME ≈ 30 kHz Diclidurus albus / scutatus 2b. Lower pulse FME ≈ 19 kHz Higher pulse FME ≈ 22 kHz Diclidurus ingens

How to separate Diclidurus and Peropteryx from molossid calls Identification of species emitting low-frequency calls is challenging as calls are highly variable even within a single sequence. Due to the great overlap between the calls of some emballonurids (Diclidurus and Peropteryx) and molossid bats it is sometimes difficult to separate them into their families. We suggest following these steps: 1st. Try to find the fundamental harmonic by adjusting the gain. If successful, genus separation is straightforward and clear. 2nd. Try to identify an obvious downturn at the end of the pulses, which is different from those in emballonurid species. 3rd. If it is impossible to record any harmonic, check the shape, angle, and type of pulse alternation. 4th. If the calls overlap or show no clear patterns, it is recommended to classify them as “unidentified” which in such cases is the most conservative way of processing your data. 5th. If you are not completely certain about an identification, consult a more experienced specialist.

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Peropteryx trinitatis

Diclidurus albus

Field Guide to Amazonian Bats

Peropteryx macrotis

Diclidurus scutatus

Peropteryx kappleri

Diclidurus ingens

How to separate Diclidurus and Peropteryx from Molossidae calls 143

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Echolocation keys Molossidae 1a. Sinuous QCFd (two types of pulses). *

Molossidae A 1b. Convex QCFd with one initial FMu (three types of pulses). ** Molossidae B 1c. Convex QCFu and concave QCFd. Molossidae C 1d. Convex QCFd and concave QCFd. Molossidae D 1e. Concave QCF (FME < 30kHz). Molossidae E

Molossidae A 1a. Lower pulse EF ≈ 21 kHz. Higher pulse EF ≈ 24 kHz. 1b. Lower pulse EF ≈ 17 kHz. Higher pulse EF ≈ 21 kHz.

Cynomops I (Cynomops planirostris / paranus) *

Cynomops II (Cynomops greenhalli /abrasus) *

* Sometimes difficult to distinguish from Molossidae B. ** Be careful with the second and third upper pulses, as they sometimes cannot be properly recorded due to their low intensity, which can lead to misidentification. The first FMu part might not be present if the pulse is too faint.

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Molossidae B

Molossidae A

Molossidae C

Molossidae D

Molossidae E

Molossidae A & B

Molossidae C

Cynomops I & II 145

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Echolocation keys Molossidae B 1a. Lower pulse FME ≈ 33-35 kHz. Intermediate pulse FME ≈ 35-40 kHz. Higher pulse FME ≈ 40-45 kHz. Molossus I * Molossus molossus 1b. Lower pulse FME 25-30kHz. Intermediate pulse FME 30-35 kHz. Higher pulse FME 35-40 kHz. Molossus II * Molossus sinaloae / currentium / rufus

* Be careful with the second and third upper pulses, as they sometimes cannot be properly recorded due to their low intensity, which can lead to misidentification! Molossus I & II can sometimes overlap. In some cases the higher pulse can be strongly modulated and might be followed by sequences of several similar modulated concave pulses (see figure).

Molossidae C 1a. Lower pulse < 40kHz. 2a. Lower pulse, EF ≈ 34 kHz. * Higher pulse, EF ≈ 37 kHz. * Promops nasutus 2a. Lower pulse, EF ≈ 28 kHz. * Higher pulse, EF ≈ 30 kHz. * Promops centralis 1b. Lower pulse > 40kHz. 2a. Lower pulse, EF ≈ 54 kHz. * Higher pulse, EF ≈ 55 kHz. * Molossops temminckii 2a. Lower pulse, EF ≈ 44 kHz. * Higher pulse, EF ≈ 46 kHz. * Molossops neglectus * These groups can sometimes overlap. Then we recommend classification as Molossus spp., Promops spp or Molossops spp.

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Molossus I & II

Molossus I & II feeding buzz.

Promops centralis

Molossops temminckii

Molossops neglectus 147

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Echolocation keys Molossidae D 1a. Only one species with this type of pulse. Neoplatymops mattogrossensis

Molossidae E 1a. Only one type of pulse.

Nyctinomops macrotis 1b. Two alternating types of two pulse. 2a. Lower pulse, EF ≈ 18 kHz. Higher pulse, EF≈ 22 kHz. Molossidae I Eumops auripendulus / glaucinus / dabbenei / hansae * / maurus Nyctinomops laticaudatus, Tadarida brasiliensis

Natalidae 1a. Only one type of pulse.

Furipteridae 1a. Only one species with this type of pulse.

Thyropteridae 1a. Only one genus with this type of pulse.

* Sometimes considered as a cryptic species complex with E. nanus.

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Natalus sp.

Furipterus horrens

Thyroptera sp.

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Neoplatymops mattogrossensis

Nyctinomops macrotis

Molossidae I

Natalidae

Furipteridae - Thyropteridae 149

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Echolocation keys Vespertilionidae 1a. Pulse mainly FMd; EF 25-45 kHz with irregular and alternating sequences. * 2a. EF: 25-35 kHz. Vespertilionidae I Lasiurus ega / castaneus / egregius / atratus 2b. EF 40-45 kHz. Vespertilionidae II Rhogeessa io / Lasiurus blossevillii 1b. Pulse initially FM, but with a considerable QCFd part. Generally regular low frequencies.

2a EF > 45 kHz; pulses ending with a QCF tail. 3a. EF > 55 kHz.

Myotis riparius

3b. EF: 45-50 kHz.

Myotis nigricans

2b. EF: 25-39 kHz.

2c. EF: 35-45 kHz.

Eptesicus I Eptesicus brasiliensis / chiriquinus Eptesicus furinalis *

* This species can sometimes overlap with other vespertilionid bats (Vespertilionidae I and II).

Myotis riparius 150

Myotis nigricans

Eptesicus I

Eptesicus furinalis

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Vespertilionidae I & II

Myotis riparius

Myotis nigricans

Eptesicus I

Eptesicus furinalis 151

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Appendix I. Species rostra Phyllostomidae sf. Desmodontinae

Desmodus rotundus

Diaemus youngi

Diphylla ecaudata

Phyllostomidae sf. Glossophaginae

Anoura caudifer

Anoura geoffroyi

Choeroniscus godmani

Choeroniscus minor

Glossophaga commissarisi

Glossophaga longirostris

Glossophaga soricina

Lonchophylla thomasi

Lichonycteris obscura

Lionycteris spurrelli

Scleronycteris ega

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Phyllostomidae sf. Stenodermatinae

Ametrida centurio

Artibeus amplus

Artibeus concolor

Artibeus lituratus

Artibeus obscurus

Artibeus planirostris

Chiroderma trinitatum

Chiroderma villosum

Dermanura anderseni

Dermanura cinerea

Dermanura glauca

Dermanura gnoma

Enchisthenes hartii

Mesophylla macconnelli

Platyrrhinus aurarius

Platyrrhinus brachycephalus

Platyrrhinus fusciventris

Platyrrhinus incarum

Platyrrhinus infuscus

Platyrrhinus lineatus

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Appendix I. Species rostra

Sphaeronycteris toxophyllum

Sphaeronycteris toxophyllum

Sturnira lilium

Sturnira magna

Sturnira tildae

Uroderma bilobatum

Uroderma magnirostrum

Vampyriscus bidens

Vampyriscus brocki

Vampyressa melissa

Vampyressa pusilla/thyone

Vampyrodes caraccioli

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Phyllostomidae sf. Phyllostominae

Chrotopterus auritus

Glyphonycteris daviesi

Glyphonycteris sylvestris

Lampronycteris brachyotis

Lonchorhina aurita

Lonchorhina inusitata

Lophostoma brasiliense

Lophostoma carrikeri

Lophostoma schulzi

Lophostoma silvicola

Macrophyllum macrophyllum

Micronycteris brosseti

Micronycteris hirsuta

Micronycteris homezorum

Micronycteris megalotis

Micronycteris microtis

Micronycteris minuta

Micronycteris sanborni

Micronycteris schmidtorum

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Appendix I. Species rostra

Mimon bennettii

Mimon crenulatum

Neonycteris pusilla

Phylloderma stenops

Phyllostomus discolor

Phyllostomus elongatus

Phyllostomus hastatus

Phyllostomus latifolius

Tonatia bidens

Tonatia saurophila

Trachops cirrhosus

Trinycteris nicefori

Vampyrum spectrum

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Phyllostomidae sf. Carollinae

Carollia benkeithi

Carollia brevicauda

Rhinophylla fischerae

Rhinophylla pumilio

Carollia castanea

Carollia perspicillata

Thyroptera lavali

Thyroptera tricolor

Thyropteridae

Thyroptera devivoi

Thyroptera wynneae

Thyroptera discifera

Furipteridae

Furipterus horrens

Noctilionidae

Noctilio albiventris

Noctilio leporinus

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Appendix I. Species rostra Mormoopidae

Pteronotus gymnonotus

Pteronotus parnellii 55

Pteronotus parnellii 60

Centronycteris centralis

Centronycteris maximiliani

Cormura brevirostris

Cyttarops alecto

Diclidurus albus

Diclidurus ingens

Diclidurus isabellus

Diclidurus scutatus

Pteronotus davyi

Pteronotus personatus

Emballonuridae

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Peropteryx kappleri

Peropteryx pallidoptera

Peropteryx leucoptera

Peropteryx macrotis

Peropteryx trinitatis

Rhynchonycteris naso

Saccopteryx bilineata

Saccopteryx canescens

Saccopteryx gymnura

Saccopteryx leptura

Vespertilionidae

Eptesicus andinus

Eptesicus brasiliensis

Eptesicus chiriquinus

Eptesicus diminutus

Eptesicus furinalis

Histiotus velatus

Lasiurus atratus

Lasiurus blossevillii

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Appendix I. Species rostra

160 160

Lasiurus castaneus

Lasiurus cinereus

Lasiurus ega

Lasiurus egregius

Myotis albescens

Myotis nigricans

Myotis riparius

Myotis simus

Rhogeessa hussoni

Rhogeessa io

Field Guide to Amazonian Bats

Molossidae

Cynomops abrasus

Cynomops greenhalli

Cynomops paranus

Cynomops milleri

Cynomops planirostris

Eumops auripendulus

Eumops bonariensis

Eumops glaucinus

Eumops hansae

Eumops maurus

Eumops trumbulli

Eumops perotis

Molossops neglectus

Molossops temminckii

Molossus rufus

Molossus coibensis

Molossus currentium

Molossus molossus

Molossus pretiosus

Molossus sinaloae

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Appendix I. Species rostra

Neoplatymops mattogrossensis

Nyctinomops laticaudatus

Promops centralis

Promops nasutus

Natalidae

Natalus macrourus

162 162

Natalus tumidirostris

Nyctinomops macrotis

Nyctinomops aurispinosus

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Megascops watsonii, a predator of bats in the Amazon

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Authors

Adrià López-Baucells Adrià started working with the Bat Research Group, Granollers Museum of Natural Sciences (Catalonia), in 2005. Since then he has collaborated on several projects in fields such as habitat selection, biogeography, behavior, and migration. He finished his BSc in Biology at the University of Barcelona in 2010 with a final project on Neotropical bats based on fieldwork undertaken in Colombia. His MSc thesis was carried out in Sydney (Australia) on behavioral ecology and physiology in megachiroptera. Currently, he is studying as a PhD student under the supervision of Dr. Christoph Meyer, and Prof. Jorge Palmeirim. His PhD project uses autonomous ultrasound recording stations as a means of investigating the long-term impact of forest fragmentation on aerial insectivorous bats.

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Ricardo Rocha BSc in Biology by the University of Lisbon and MSc in Conservation Science by Imperial College London with thesis dedicated to São TomÊ endemic birds’ response to agricultural intensification. Following his MSc, he worked on the ecology of seabirds and endemic reptiles of the Selvagens archipelago (Portugal) and then moved to the Metapopulation Research Centre (Finland) to investigate the efficiency of Malagasy protected areas in reducing deforestation. He has since worked with bird and bat ecology in Madagascar, Kenya and Brazil. His PhD, based at the Universities of Lisbon and Helsinki and supervised by Christoph Meyer, Jorge Palmeirim and Mar Cabeza, addresses the effects tropical forest fragmentation on the spatio-temporal dynamics of phyllostomid bat communities. He has recently moved to the University of Madeira where he lectures biosystematics and zoology.

Oriol Massana Valeriano Oriol studied Biological Sciences at the University of Barcelona but then started working as an illustrator of educational, scientific, and cultural books and magazines. In 2010 he began to focus on 3D design and animation, which led to a career in nature documentaries. Another facet of his professional work focuses on photography, an interest that has been increasing since 2004. He has contributed to a number of publications and has received a number of awards. Since 2011 he has worked with the Bat Research Group at the Granollers Museum of Natural Sciences (Catalonia) as a photographer, while developing a popular exposition on Catalan bats. During 2014 he spent three months in the Amazon rainforest as a volunteer on the bat research projects led by the other authors of this guide.

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Authors & Illustrators Paulo E. D. Bobrowiec

Bat researcher at the National Institute for Amazonian Research (INPA). He undertook a BSc in Biological Science at the Universidade Federal de Uberl창ndia and both a MSc and PhD at INPA. His main area of expertise is bat ecology and community structure, feeding strategies, and bat pollination and seed dispersal. His MSc was focused on the effect of secondary vegetation on bat communities, while his PhD was devoted to the feeding ecology of D. rotundus.

Enrico Bernard

Bat researcher and Professor of Conservation Biology at Universidade Federal de Pernambuco, Brazil. He carried out his BSc in Biology in the Universidade de S찾o Paulo in Ribeir찾o Preto. His MSc was conducted in Ecology at INPA (Manaus), where he worked on the vertical stratification of bat communities. His PhD was obtained from York University, Toronto, Canada, and focused on the effects of forest fragmentation on Amazonian bats.

Jorge Palmeirim

Associate Professor at the University of Lisbon and member of its cE3c research center, where he coordinates the Conservation Ecology. He is also a member of the IUCN Species Survival Commission (Chiroptera Specialist Group). He studied Biology at the Universities of Luanda and Lisbon, followed by an M.A. and PhD in Systematics and Ecology at the University of Kansas. His main research interests are the ecology and conservation biology of bats and birds, and tropical ecology.

Christoph F. J. Meyer

Lecturer in Global Ecology and Conservation at the University of Salford, United Kingdom, and external collaborator of cE3c, University of Lisbon, Portugal. He holds an MSc degree from the University of W체rzburg and a PhD from the University of Ulm (Germany).

His research centers on investigating the effects of habitat fragmentation and land-use change on tropical bats, and he has a considerable track record of conducting ecological and conservation-related studies on bats in various tropical countries, including Brazil.

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Blanca Martí de Ahumada Blanca graduated in History of Art from the University of Barcelona in 2004, specializing in illustration in 2003–2006 in the Francesca Bonnemaison school. Her keen interest in nature and animal biology led her to scientific illustration and enrollment on several courses at the Universities of Barcelona and Valencia, and the Galanthus Association. Carles Puche and Rosa Vidal are her two main mentors. After publishing a number of books and many popular science articles, she is currently working as an art teacher on master courses on Ethology and Primatology at the Universities of Girona and Cordoba, and on courses at the Mona Foundation, University of Granada, and the Eventur Darwin and Sigantus Associations.

Eva Sánchez Gómez Eva graduated in Fine Arts from the University of Barcelona in 2009, specializing in illustration for four years in the Francesca Bonnemaison school: Here, she illustrated her first album, Onades i Flors, followed by many other children’s and poetry books such as, most recently, L’Attente, published by Âne Bâté Éditions. Her work has been exhibited in several collective exhibitions, and was selected for the IV Ibero-American Catalogue in 2013 and Hipermerc’Art, an exhibition and market of contemporary art, for the last four editions (2011-2014), She is greatly interested in science and nature, which influence much of her work.

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References MORPHOLOGICAL KEY MAIN REFERENCE: Lim, B. & Engstrom. (2001). Species diversity of bats (Mammalia: Chiroptera) in Iwokrama Forest, Guyana, and the Guianan subregion: implications for conservation. Biodiversity & Conservation 10:613-657. Aguirre, L.F. & Anderson, S. (2009). Clave de campo para la identificación de los murciélagos de Bolivia. Centro de Estudios en Biología Teórica y Aplicada. Cochabamba, Bolivia. Bernard, E. et al. (2011). Compilação atualizada das espécies de morcegos (Chiroptera) para a Amazônia Brasileira. Biota Neotropica 11(1):35-46. Charles-Dominique, P. (2001). Les chauve-souris de Guyane. Muséum National d’Histoire naturelle. Laboratoire d’Écologie générale. París. France. Gardner, A. L. et al. (2007). Mammals of South America. Volume I Marsupials, Xenarthrans, Shrews, and bats. University of Chicago Press. Chicago and London. United Kingdom. Gregorin, R. & Taddei, V.A. (2002). Chave artificial para a identificação de molossídeos brasileiros (Mammalia, Chiroptera). Mastozoologia Neotropical 9(1):13-32. López-González, C. (2005). Murciélagos del Paraguay. Biosfera. Madrid, Spain. Medellin, R. A. et al. (1997). Identificación de los murciélagos de México. Clave de campo. Instituto de Ecología. Universidad Nacional Autónoma de México. Mexico City. Mexico Miranda, J. M. D. et al. (2011). Chave ilustrada para determinação dos morcegos da Região Sul do Brasil. Laboratório de Biodiversidade, Conservação e Ecologia de Animais Silvestres (UFPR). Curitiba. Brazil. Reis, N. (2007). Morcegos do Brasil. UNESP. Universidade Estadual de Londrina. Londrina. Brazil. Reis N. et al. (2013). Morcegos do Brasil. Guia de Campo. Technical Books Editora. Rio de Janeiro. Brazil. SPECIFIC FAMILIES, GENERA AND SPECIES Aires, C. (2008). Caracterização das espécies brasileiras de Myotis Kaup, 1829 (Chiroptera: Vespertilionidae) e ensaio sobre filogeografia de Myotis nigricans (Schinz, 1821) e Myotis riparius Handley, 1960. PhD thesis, Universidade de São Paulo. São Paulo. Brazil. Genoways, H. H. et al. (1986). Bats of the genus Micronycteris (Mammalia: Chiroptera) in Suriname. Annals of Carnegie Museum 55(13):303-324. Gregorin, R. et al. (2006). New species of Disk-winged bat Thyroptera and range estension for T. discifera. Journal of Mammalogy 87(2):238–246. Nogueira, M. R. et al. (2014). Checklist of Brazilian bats, with comments on original records. Check List 10(4):808-821. Porter, C. A. et al. (2007). Molecular phylogenetics of the phyllostomid bat genus Micronycteris with descriptions of two new subgenera. Journal of Mammalogy 88(5):1205-1215. Siles, L. et al. (2013). A new species of Micronycteris (Chiroptera: Phyllostomidae) from Bolivia. Journal of Mammalogy, 94(4):881–896. Simmons, J. B. et al. (2002). A new amazonian species of Micronycteris (Chiroptera : Phyllostomidae) with notes on the roosting behavior of sympatric congeners. American Museum Novitates 3358:1-14. Velazco, P. M. & Patterson, B. (2014). Two new species of yellow-shouldered bats, genus Sturnira Gray, 1842 (Chiroptera, Phyllostomidae)from Costa Rica, Panama and western Ecuador. ZooKeys 402:43–66. Velazco, P. M. et al. (2014). Extraordinary Local Diversity of Disk-Winged Bats (Thyropteridae: Thyroptera) in Northeastern Peru, with the Description of a New Species and Comments on Roosting Behavior. American Museum Novitates 3795:1-28. William, S. L. et al. (1995). Review of the Tonatia bidens complex (Mammalia: Chiroptera), with descriptions of two new subspecies. Journal of Mammalogy 76(2):612-626. BIOACOUSTIC KEY Audet, D. et al. (1993). Morphology, Karyology, and Echolocation Calls of Rhogeessa (Chiroptera: Vespertilionidae) from the Yucatán Peninsula. Journal of Mammalogy 74(2):498-502. Barataud, M. et al. (2013). Identification et écologie acoustique des chiroptères de Guyane française. Le Rhinolophe 19:43. Bayefsky-Anand, S. (2006). Echolocation calls of the greater Sac-Winged Bat (Saccopteryx bilineata) in different amounts of clutter. Bat Research News 47(1):4. Borloti, I. S. et al. (2014). Repertório Sonoro de Ecolocalização de Molossus molossus (Chiroptera, Molossidae). III Simposio sobre a biodiversidade da mata atlántica. Santa Teresa. Brazil.

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Bradbury, J. W. & Emmons, L.H. (1974). Social Organization of some Trinidad Bats. Zeitschrift für Tierpsychologie 36:137183. Clare et al. (2013). Diversification and reproductive isolation: cryptic species in the only New World high-duty cycle bat, Pteronotus parnellii. BMC Evolutionary Biology 13(26):1-18. Clement, M. J. et al. (2014). The effect of call libraries and acoustic filters on the identification of bat echolocation. Ecology and Evolution 4(17):3482-3493. Cormier, A. C. A. (2014). Species diversity and activity of insectivorous bats in three habitats in La Virgen de Sarapiquí, Costa Rica. Revista De Biologia Tropical 62(3):939-946. Fenton, M. B. & Bell, G.P. (1981). Recognition of Species of Insectivorous Bats by Their Echolocation Calls. Journal of Mammalogy 62(2):233-243. Fenton, M. B. et al. (1999). Constant-frequency and frequency-modulated components in the echolocation calls of three species of small bats (Emballonuridae, Thyropteridae, and Vespertilionidae). Canadian Journal of Zoology 77(12):1891-1900. Gillam, E. H. & Chaverri, G. (2012). Strong individual signatures and weaker group signatures in contact calls of Spix’s discwinged bat, Thyroptera tricolor. Animal Behaviour 83(1):269-276. Griffin, D. R. & Novick, A. (1955). Acoustic orientation of neotropical bats. Journal of Experimental Zoology 130(2):251-299. Heer, K. et al. (2015). Effects of land use on bat diversity in a complex plantation-forest landscape in northeastern Brazil. Journal of Mammalogy 96(4):720-731. Ibáñez, C. et al. (1999). Echolocation Calls of Pteronotus davyi (Chiroptera: Mormoopidae) from Panama. Journal of Mammalogy, 80(3):924-928. Jung, K. et al. (2007). Echolocation calls in Central American emballonurid bats: signal design and call frequency alternation. Journal of Zoology 272(2):125-137. Jung, K. & Kalko, E.K. (2010). Where forest meets urbanization: foraging plasticity of aerial insectivorous bats in an anthropogenically altered environment. Journal of Mammalogy 91(1):144-153. Jung, K. & Kalko, E.K. (2011). Adaptability and vulnerability of high flying Neotropical aerial insectivorous bats to urbanization. Diversity and Distributions 17(2):262-274. Jung, K. et al. (2014). Driving Factors for the Evolution of Species-Specific Echolocation Call Design in New World FreeTailed Bats (Molossidae). PLoS ONE 9(1): e85279. MacSwiney G. M. C. et al. (2009). Insectivorous Bat Activity at Cenotes in the Yucatan Peninsula, Mexico. Acta Chiropterologica 11(1):139-147. Miller, B. W. (2003). Community Ecology of the Non-phyllostomid bats of Northwestern Belize, with a landscape level assessment of the bats of Belize. PhD thesis. Institute of Conservation and Ecology. University of Kent Durrell. Canterbury. United Kingdom. Mora, E. C. et al. (2002). Aplicación de métodos bioacústicos y convencionales en la caracterización de la comunidad de murciélagos de la Cueva del Indio, Tapaste, la Habana, Cuba, Revista biología. 16(2):159-166. Moratelli, R. & Oliveira, J.A.D. (2011). Morphometric and morphological variation in South American populations of Myotis albescens (Chiroptera: Vespertilionidae). Zoologia 28(6):789-802. Novick, A. & Vaisnys, J.R. (1964). Echolocation of Flying Insects by the Bat, Chilonycteris parnellii. Biological Bulletin 127(3):478-488. O’Farrell, M. J. & Miller, B.W. (1997). A New Examination of Echolocation Calls of Some Neotropical Bats (Emballonuridae and Mormoopidae). Journal of Mammalogy 78(3):954-963. O’Farrell, M. J. et al. (1999). Qualitative identification of free-flying bats using the Anabat detector. Journal of Mammalogy 80(1):11-23. Rodhouse, T. J. et al. (2011). A practical sampling design for acoustic surveys of bats. The Journal of Wildlife Management 75(5):1094-1102. Rodriguez, A. et al. (2014). Temporal and spatial variability of animal sound within a neotropical forest. Ecological Informatics 21(0):133-143. Rodríguez, A. & Rodríguez, A. (2011). Acoustic identification of Nycticeius cubanus (Gundlach, 1867) and Eptesicus fuscus dutertreus (Gervais, 1837)(Chiroptera: Vespertilionidae) in western Cuba. Revista Cubana de Ciencias Biológicas 19:1-2. Rodríguez, A. & Mora, E.C. (2006). The echolocation repertoire of Eptesicus fuscus (Chiroptera: Vespertilionidae) in Cuba. Caribbean Journal of Science 42(1):121. Rodríguez-San Pedro, A. & Simonetti, J.A. (2013). Acoustic identification of four species of bats (Order Chiroptera) in central Chile. Bioacoustics 22(2):165-172. Rodríguez-San Pedro, A. & Simonetti, J.A. (2014). Does understory clutter reduce bat activity in forestry pine plantations? European Journal of Wildlife Research 61(1):177-179. Rydell, J., et al. (2002). Acoustic identification of insectivorous bats (order Chiroptera) of Yucatan, Mexico. Journal of Zoology 257(1):27-36. Schnitzler, H., et al. (1991). Comparative studies of echolocation and hunting behaviour in the four species of mormoopid bats of Jamaica. Bat Research News 32:22-23. Siemers, B. et al. (2001). Echolocation behavior and signal plasticity in the Neotropical bat Myotis nigricans (Schinz, 1821) (Vespertilionidae): a convergent case with European species of Pipistrellus? Behavioral Ecology and Sociobiology 50(4):317328. Thoisy, B. D. et al. (2014). Cryptic Diversity in Common Mustached Bats Pteronotus cf. parnellii (Mormoopidae) in French Guiana and Brazilian Amapa. Acta Chiropterologica 16(1):1-13.

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Do you think identifying bats in Europe or in North America is difficult? Well, try it in the Amazon The planet’s green lung is home to the most diverse bat communities on the planet with more than 160 species currently described. Local species richness often surpasses 100 and for many, their identification in the field is, to say the least, challenging. This task will now become easier with the new Field Guide to Amazonian Bats, a landmark handbook aimed at facilitating species identification in the field. Its new digital dynamic format, continuously updated, might be the future for field guides for the most unexplored regions in the world.

ISBN: 978-85-211-0158-1

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