麻豆传媒高清版

Research Interests

My research group focuses on the cognitive processes and sensory mechanisms by which animals navigate and migrate. While my principle focus is at the level of the whole organism I also incorporate aspects of neurobiology, molecular biology, and physics to identify the听 environmental cues, sensory pathways and mechanisms used by animals to decide how, when and where to move. My work also operates in a comparative framework as I compare and contrast across species, taxa, age class, spatial scale and sensory mechanisms to reveal how natural selection has acted to shape navigation behaviour in different animal groups. I can offer postgraduate and postdoctoral projects (subject to funding) in the following areas:

The navigation map of migratory birds

The answer to the question of how migratory birds return to the same nest every year after journeys of thousands of miles continues to elude scientists. So far, because it is difficult to study migration in the field, most work has been done in laboratory settings using directed migratory restlessness in Emlen funnels as a proxy for migratory behaviour. Our lab addresses this challenge directly however, and we have developed methods to successfully study aspects of migration in the wild. This has resulted in significant breakthroughs in bridging the gap between field and laboratory. We use a range of tracking methods to study behaviour in response to sensory manipulations; from global satellite tracking of complete migration, to radio tracking the departure directions of small songbirds at stop over sites, in addition to calling on the 鈥渃ontrolled鈥� environment of the Emlen funnel. We have established model systems for work on migratory passerines at field sites across Europe and have demonstrated a crucial role for olfactory cues in the migration of adult songbirds and gulls, as well as age and location specific reliance on magnetic cues. Additionally, we have demonstrated that juvenile songbirds, previously thought to navigate based purely on an inherited compass direction, are capable of correcting for displacements in some circumstances. A BBSRC responsive mode grant explored how the magnetic field is used to calculate location, building on our discovery that declination (the difference between geographical and magnetic north) is a component in the navigational map (Chernetsov et al. 2017). A new project is exploring the movement of birds of prey tracked with GPS in relation to the magnetic field.

Orientation and Navigation in bats

Bats are remarkably under studied with regard to orientation, navigation and spatial memory, but I have re-launched the study of long distance navigation in this taxa I have demonstrated that bats use the Earth鈥檚 magnetic field as a compass, and that this magnetic compass sense is calibrated through an interaction with the sunset. We are now investigating the sensory basis of magnetoreception in these animals. Whilst in birds, it is know that magnetoreception is visually dependent; in bats no such mechanism has been demonstrated, but we have produced evidence of a mechanism based on magnetite: magnetic iron particles in sensory cells. Additionally, through a NERC new investigator grant we demonstrated that bats use polarized light cues as part of their compass system to calibrate the magnetic compass. Work funded by the Leverhulme Trust has investigated the navigation mechanisms of migratory bats, with reference to the impact of electromagnetic pollution on their ability to orient.

The magnetic sense in bees

A collaboration with the National Grid and Queen Mary University of London aims to investigate the function of the magnetic sense in bees, and its vulnerability to electromagnetic pollution.

Sensory systems and spatial memory

In contrast to navigation from unfamiliar areas, in a familiar place, animals learn and remember spatial locations by constructing a 鈥渃ognitive map鈥� of the relationship between landmarks in their environment.听 The theory of the cognitive map has been studied extensively by testing rats in mazes and by observing brain scans of humans, but has focused almost exclusively on the visual sense. There are sensory systems other than vision that can tell the animal the location of landmarks in space, for example, electro-location in weakly electric fish. My lab has started to investigate the way these fish build up a picture of their environment using their electric sense, and how this compares and contrasts with the way they learn about space using vision. This has implications for understanding the way the brain integrates information from different sensory modalities.听

Ageing and spatial memory

Spatial memory tasks have been used in animals to investigate ageing and understanding the interaction between ageing, sensory systems and memory. We are investigating this using homing pigeons (e.g. Griffiths et al. 2021), a rare example of a model species that allows the investigation of this phenomenon outside the laboratory setting. Using gps trackers we can compare the way pigeons learn and remember routes and how this changes with age. It has the potential to advance our understanding of mental health and wellbeing.

The impact of sensory pollution on animal behaviour

Our lab is starting to explore how electromagnetic noise and artificial light at night disrupt animal's ability to detect the cues they use for navigation. This is relevant across all the areas we study, from migration in birds, to homing in pigeons and spatial cognition in fish and insects, but remarkably little is known about the impact of these pollutants on animal navigation.

Current lab members

Sara Bariselli (PhD student: the magnetic sense in bees). Co-Supervision with Dr Hayley Tripp (National Grid), Dr Paul Cross, Professor Lars Chittka (Queen Mary University of London), .

Noah Church (MScRES student: the role of circadium rhythms in spatial cognition). Co-supervision with Dr Amy Ellison.

Previous lab members

Dr. Will Schneider (Postdoctoral researcher: bat navigation)

Sarah Stachowski (MScRes student: bird navigation)

Jess Hey (PhD student: Bird behaviour and antimicrobial resistence)

Dr. Charlotte Griffiths (PhD student: bird navigation)

James Blane (MScRes student: fish cognition)

Dr. Oliver Lindecke (Marie Sk艂odowska-Curie research fellow: bat navigation)

Dr. Florian Packmor (Postdoctoral researcher: bird navigation)

Dr. Ingo Schiffner (Marie Sk艂odowska-Curie research fellow)

Dr. Stefan Greif (Postdoctoral researcher, Queen鈥檚 University Belfast)

Dr. Lorrain Chivers (Postdoctoral researcher, Queen鈥檚 University Belfast)

Dr. Dmitry Kishkinev (Postdoctoral researcher, Queen鈥檚 University Belfast, 麻豆传媒高清版)

Dr. Katherine Snell (Co-supervisor, PhD student Copenhagen University)

Dr. Kyriacos Kareklas (PhD student, Queen鈥檚 University Belfast)

Dr. Claire McAroe (PhD Student, Queen鈥檚 University Belfast)

Current collaborators

Professor Christian Voigt, IZW Berlin, Germany

Dr. Anna Gagliardo, University of Pisa, Italy

Dr. Chris Hewson, BTO, UK

Dr. Dmitry Kishkinev, Keele University

Dr. Oliver Lindecke, Oldenburg University

Room: 531 Brambell

Email: r.holland@bangor.ac.uk

Phone: +44 (0)1248 382344

Web: 听

听

My research and teaching interests fall broadly in the area of animal behaviour and sensory biology. I am the course co-ordinator for the Zoology with Animal Behaviour degree (C3D3) and teach on several animal behaviour focused modules, as well as ornithology. My research questions focus the cognitive processes and sensory mechanisms by which animals navigate and migrate. While my principle focus is at the level of the whole organism I also incorporate aspects of neurobiology, molecular biology, and physics to identify the听 environmental cues, sensory pathways and mechanisms used by animals to decide how, when and where to move. My work also operates in a comparative framework as I compare and contrast across species, taxa, age class, spatial scale and sensory mechanisms to reveal how natural selection has acted to shape navigation behaviour in different animal groups. New avenues my lab is exploring include the impact of artificial light and electromagnetic noise on navigation and spatial cognition, and the impact of antimicrobial resistant bacteria on bird behaviour.

Biography:

2021-2024, Director of Research, School of Natural Sciences

2020-current, Professor in Animal Behaviour

2017-2020, Senior Lecturer, 麻豆传媒高清版

2016-2017, Lecturer, 麻豆传媒高清版

2011-2016, Lecturer, Queen鈥檚 University Belfast

2009-2010, Research scientist, Max Planck Institute for Ornithology

2006-2008, Marie Curie Outgoing International fellow, Princeton University and University of Leeds

2002-2005, Postdoctoral research fellow, University of Leeds

1999-2002, Postdoctoral research fellow, University of Nebraska

1994-1998, DPhil, Oxford University

1990-1993, BSc (Hons), University of Nottingham

Research Area

Zoology

Teaching

Course co-ordinator, Zoology with Animal Behaviour

BNS 3004, Advances in Behaviour (Module co-ordinator)

BSX 3157 Ornithology

BSC 3070 Dissertation

BSX 2018 Behavioural Ecology

BSX1030 Practical skills 1

BSC 1028 Tutorials

Supervision

Charlotte Griffiths, PhD

James Blane, MScRes

Sara Bariselli, PhD

Sarah Stachowski, MScRes

I can offer projects on animal navigation and migration. Example projects that I can supervise MScRES students or PhDs on are:

The role of spatial memory in homing pigeon navigation.

Migratory behaviour in raptors with reference to the geomagnetic field.

Magnetic navigation in bees.

Spatial cognition in fish.

The effect of sensory pollution (artificial light and electromagnetic noise) on animal behaviour.

2024

• Published
  Karwinkel, T., Peter, A., Holland, R., Thorup, K., Bairlein, F. & Schmaljohann, H., Aug 2024, In: Biological Reviews. 99, 4, p. 1576-1593 18 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Karwinkel, T., Winklhofer, M., Allenstein, D., Burst, V., Christoph, P., Holland, R., Huppop, O., Steen, J., Bairlein, F. & Schamaljohann, H., 15 May 2024, In: Journal of the Royal Society: Interface. 21, 214
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Accepted/In press
  Packmor, F., Kishkinev, D., Zechmeister, T., Mouritsen, H. & Holland, R., 14 Oct 2024, (Accepted/In press) In: Proceedings of the Royal Society B: Biological Sciences.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Schneider, W., Wynn, J., Packmor, F., Lindecke, O. & Holland, R., 27 May 2024, In: Communications Biology. 7, 1, p. 651 1 p., 651.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Blane, J. C. & Holland, R. A., Apr 2024, In: Behavioural Processes. 217, 105021.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2023

• Published
  Schneider, W. T., Holland, R. A., Kei拧s, O. & Lindecke, O., Nov 2023, In: Biology letters. 19, 11, 20230181.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Schneider, W., Holland, R. & Lindecke, O., Mar 2023, In: The European Physical Journal Special Topics. 232, 2, p. 269-278 10 p.
  Research output: Contribution to journal 鈥� Review article 鈥� peer-review
• Published
  Schneider, W., Holland, R., Packmor, F. & Lindecke, O., 20 Feb 2023, In: Communications Biology. 6, 1, 8 p., 187.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2022

• Published
  Morton Williams, S., Bariselli, S., Palego, C., Holland, R. & Cross, P., 1 Dec 2022, In: Smart Agricultural Technology. 2, 100038.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2021

• Published
  Packmor, F., Kishkinev, D., Bittermann, F., Kofler, B., Machowetz, C., Zechmeister, T., Zawadzki, L., Guilford, T. & Holland, R., Nov 2021, In: Journal of Experimental Biology. 224, 22, 10 p., 243337.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Lindecke, O., Holland, R., Petersons, G. & Voigt, C. C., 5 May 2021, In: Communications Biology. 4, 1, 522.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Holland, R., 30 Dec 2021, The Conversation.
  Research output: Contribution to specialist publication 鈥� Article
• Published
  Kishkinev, D., Packmor, F., Thomas, Z., Hans, W., Mouritsen, H., Chernetsov, N. & Holland, R., 12 Apr 2021, In: Current Biology. 31, 7, p. 1563-1569
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Griffiths, C., Schiffner, I., Price, E., Charnell-Hughes, M., Kishkinev, D. & Holland, R., Jul 2021, In: Animal Behaviour. 177, p. 159-170
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2020

• Published
  Kishkinev, D., Anashina, A., Ishchenko, I. & Holland, R. A., Jan 2020, In: Journal of Ornithology. 161, 1, p. 47-57
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Griffiths, C., Holland, R. & Gagliardo, A., 5 May 2020, In: Symmetry. 12, 5, 740.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2019

• Published
  Lindecke, O., Elksne, A., Holland, R. A., Petersons, G. & Voigt, C. C., 22 Apr 2019, In: Current Biology. 29, p. 1369-1373
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Lindecke, O., Elksne, A., Holland, R., Petersons, G. & Voigt, C. C., 1 May 2019, In: Journal of Zoology. 308, 1, p. 56-65
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2018

• Published
  Kareklas, K., Elwood, R. W. & Holland, R., 2018, In: Biology Open. 2018, 7, bio033613.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Kareklas, K., Elwood, R. W. & Holland, R. A., 1 Mar 2018, In: Behavioural Processes. 148, p. 41-45
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Kareklas, K., Elwood, R. W., Arnott, G. & Holland, R., Jul 2018, In: Animal Behaviour. 141, p. 127-135
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2017

• Published
  van Toor, M., Arriero, E., Holland, R., J. Huttunen, M., Juvaste, R., M眉ller, I., Thorup, K., Wikelski, M. & Safi, K., 18 Jan 2017, In: Royal Society Open Science. 4, 160164.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Chernetsov, N., Pakhomov, A., Kobylkov, D., Kishkinev, D., Holland, R. & Mouritsen, H., 11 Sept 2017, In: Current Biology. 27, 17, p. 2647-2651
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Kareklas, K., Elwood, R. W. & Holland, R., 2017, In: Ethology.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Voigt, C. C., Frick, W., Holland, R., Holdereid, M., Kerth, G., Mello, M., Plowright, R., Swartz, S. & Yovel, Y., Sept 2017, In: Quarterly Review of Biology. 92, 3, p. 267-287 20 p.
  Research output: Contribution to journal 鈥� Review article 鈥� peer-review
• Published
  Juvaste, R., Arriero, E., Gagliardo, A., Holland, R., Huttunen, M. J., Mueller, I., Thorup, K., Wikelski, M., Penttinen, M.-L., Hannila, J. & Wistbacka, R., Apr 2017, In: Global Ecology and Conservation. 10, p. 220-230
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  McAroe, C. L., Craig, C. M. & Holland, R., 2017, In: BMC Zoology. 2, 10
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2016

• Published
  McAroe, C. L., Craig, C. M. & Holland, R., Jan 2016, In: Animal Cognition. 19, 1, p. 153-161
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Kareklas, K., Arnott, G., Elwood, R. W. & Holland, R., 6 Jun 2016, In: Frontiers in Zoology. 13, 22
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2015

• Published
  Lindecke, O., Voigt, C. C., Petersons, G. & Holland, R., 16 Sept 2015, In: Biology Letters. 11, 9, p. 1-4
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Wikelski, M., Arriero, E., Gagliardo, A., Holland, R. A., Huttunen, M. J., Juvaste, R., Mueller, I., Tertitski, G., Thorup, K., Wild, M., Alanko, M., Bairlein, F., Cherenkov, A., Cameron, A., Flatz, R., Hannila, J., Hueppop, O., Kangasniemi, M., Kranstauber, B., Penttinen, M.-L., Safi, K., Semashko, V., Schmid, H. & Wistbacka, R., 24 Nov 2015, In: Scientific Reports. 5, 17061.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2014

• Published
  Greif, S., Borissov, I., Yovel, Y. & Holland, R., 2014, In: Nature Communications. 5, 4488.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Holland, R., May 2014, In: Journal of Zoology. 293, 1, p. 1-15
  Research output: Contribution to journal 鈥� Review article 鈥� peer-review

2013

• Published
  Holland, R., Filannino, C. & Gagliardo, A., 29 May 2013, In: Journal of Experimental Biology. 216, 12, p. 2192-2200 9 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Holland, R. A. & Helm, B., 6 Apr 2013, In: Journal of the Royal Society, Interface. 10, 81, 20121047.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  van Toor, M. L., Hedenstrom, A., Waldenstrom, J., Fiedler, W., Holland, R. A., Thorup, K. & Wikelski, M., 30 Aug 2013, In: PLoS ONE. 8, 8, e72629.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2012

• Published
  Thorup, K., Ortvad, T., Holland, R., Rab酶l, J., Kristensen, M. & Wikelski, M., 1 Oct 2012, In: Journal of Ornithology. 153, 4, p. 1261-1265 5 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2011

• Published
  Holland, R. A., Meyer, C. F. J., Kalko, E. K. V., Kays, R. & Wikelski, M., Dec 2011, In: Acta Chiropterologica. 13, 2, p. 399-404 6 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Thorup, K., Ortvad, T. E., Rabol, J., Holland, R., Tottrup, A. P. & Wikelski, M., 2011, In: PLoS ONE. 6, 3, e17903.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Guilford, T., Akesson, S., Gagliardo, A., Holland, R. A., Mouritsen, H., Muheim, R., Wiltschko, R., Wiltschko, W. & Bingman, V. P., Nov 2011, In: Journal of Experimental Biology. 214, 22, p. 3705-3712 8 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2010

• Published
  Holland, R., Borissov, I. & Siemers, B. M., 13 Apr 2010, In: Proceedings of the National Academy of Sciences of the USA. 107, 15, p. 6941-6945 5 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Holland, R., 6 Nov 2010, In: Journal of the Royal Society, Interface. 7, 52, p. 1617-1625 9 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Wikelski, M., Moxley, J., Eaton-Mordas, A., Lopez-Uribe, M. M., Holland, R., Moskowitz, D., Roubik, D. W. & Kays, R., 2010, In: PLoS ONE. 5
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Holland, R., 2010, Encyclopedia of Animal Behaviour. Academic Press, Vol. 2. p. 177-185 9 p.
  Research output: Chapter in Book/Report/Conference proceeding 鈥� Chapter
• Published
  Thorup, K., Holland, R., Tottrup, A. & Wikelski, M., 2010, In: Integrative and Comparative Biology. 50, 3, p. 315-322 8 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2009

• Published
  Bisson, I. A., Safi, K. & Holland, R., 21 Oct 2009, In: PLoS ONE. 4, 10
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Holland, R. & Wikelski, M., 15 Dec 2009, In: Journal of Mammalogy. 90, 6, p. 1324-1329 6 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Holland, R., Thorup, K., Gagliardo, A., Bisson, I. A., Knecht, E., Mizrahi, D. & Wikelski, M., 15 Dec 2009, In: Journal of Experimental Biology. 212, 24, p. 4065-4071 7 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Holland, R., Wikelski, M., Kummeth, F. & Bosque, C., 2009, In: PLoS ONE. 4, 12, e8264.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Thorup, K. & Holland, R., 15 Nov 2009, In: Journal of Experimental Biology. 212, 22, p. 3597-3604 8 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2008

• Published
  Holland, R., Kirschvink, J. L., Doak, T. G. & Wikelski, M., 27 Feb 2008, In: PLoS ONE. 3, 2
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Holland, R., 2008, In the neurobiology of Umwelt: how animals perceive the world. Springer, p. 125-139
  Research output: Chapter in Book/Report/Conference proceeding 鈥� Chapter

2007

• Published
  Thorup, K., Bisson, I. A., Bowlin, M. S., Holland, R., Wingfield, J. C., Ramenofsky, M. & Wikelski, M., 13 Nov 2007, In: Proceedings of the National Academy of Sciences of the USA. 104, 46, p. 18115-18119 5 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Holland, R., Mar 2007, In: Behavioral Ecology and Sociobiology. 61, 5, p. 653-660 8 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Holland, R. & Waters, D. A., 1 Sept 2007, In: Behaviour. 144, 9, p. 1053-1064 12 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Holland, R., Thorup, K. & Wikelski, M., 2007, In: Biologist. 54, p. 2-7 6 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2006

• Published
  Holland, R., Wikelski, M. & Wilcove, D. S., 11 Aug 2006, In: Science. 313, 5788, p. 794-796 3 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Holland, R., Thorup, K., Vonhof, M. J., Cochran, W. W. & Wikelski, M., 7 Dec 2006, In: Nature. 444, 7120, p. 702 1 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2005

• Published
  Holland, R. & Waters, D. A., 2005, In: Acta Chiropterologica. 7, 1, p. 83-90 8 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Holland, R., Winter, P. & Waters, D. A., Aug 2005, In: Ethology. 111, 8, p. 715-725 11 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2004

• Published
  Holland, R., Waters, D. A. & Rayner, J. M. V., Dec 2004, In: Journal of Experimental Biology. 207, 25, p. 4361-4369 9 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2003

• Published
  Holland, R., Jun 2003, In: Journal of Experimental Biology. 206, 11, p. 1773-1778 6 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2000

• Published
  Holland, R., Bonadonna, F., Dall'antonia, L., Benvenuti, S., De Perera, T. B. & Guilford, T., Jan 2000, In: Ibis. 142, 1, p. 111-118 8 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review
• Published
  Bonadona, F., Holland, R., Dall'Antonia, L., Guilford, T. & Benvenuti, S., Jan 2000, In: Journal of Experimental Biology. 203, 2, p. 207-212 6 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

1998

• Published
  Guilford, T., Gagliardo, A., Chappell, J., Bonadonna, F., De Perera, T. B. & Holland, R., 1998, In: Journal of Experimental Biology. 201, 6, p. 895-900 6 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

1997

• Published
  Burt, T., Holland, R. & Guilford, T., Jun 1997, In: Animal Behaviour. 53, p. 1203-1209 7 p.
  Research output: Contribution to journal 鈥� Article 鈥� peer-review

2024

• Songbird Survival

  1 Apr 2024 鈫�

  Activity: Membership of committee (Chair)

• Songbird Survival Charity scientific advisary board

  1 Apr 2024

  Activity: Membership of committee (Chair)

2022

• A comparison of machine-learning assisted optical and thermal camera systems for beehive activity counting

  24 Jan 2022

  Activity: Publication peer-review (Editorial board member)

2021

• Editorial Board Member, Communications Biology

  1 Aug 2021 鈫�

  Activity: Editorial activity (Editorial board member)

• 01/03/2021 鈥� 17/08/2024 (Finished)

• 01/09/2020 鈥� 31/03/2024 (Finished)

• 01/09/2019 鈥� 01/08/2022 (Finished)

• 01/06/2018 鈥� 21/07/2020 (Finished)

  Description

  This project is part of the NAV MAP project and will allow prospective students to work on a biological problem in a interdisciplinary context, mixing field work and analytical work. The project can be split into two subparts - Compass mechanisms and Map components - allowing up to two students to work simultaneously on the same project.

  Links:

• 01/03/2018 鈥� 01/08/2022 (Finished)

  Description

  The way in which migratory birds are able to navigate between breeding and wintering grounds thousands of miles apart with such remarkable precision remains a mystery despite 50 years of research under the dominant paradigm of the "map and compass" theory. In light of the lack of progress under this theory, this research proposal aims to develop a new paradigm for addressing the mystery. This is built around the new discovery that birds use declination, i.e. the difference between the magnetic and celestial compasses, to calculate their position. This requires that birds use the radical pair magnetic compass sense, located in their visual system, to calculate their position. This suggests that the map and compass may not be separate entities, and the cues that birds use for navigation may have been hiding in plain sight. In light of this the sun, the stars and magnetic inclination, previously thought to be only used to calculate direction, must be reassessed as this discovery presents the possibility that they are integrated into the map component of birds navigational map This proposal will address this to discover the extent to which information thought to be directional actually provides information on location, how this is learned and the spatial scale of this mechanism. This will be acheived by a combination of cue conflict experiments, virtual displacements using Helmholz coils, and disruption of the magnetic sense using broadband RF fields, a diagnostic test of the radical pair magnetic sense.

  Layman's description

  The ability to orient and navigate in space is a vital adaptation for all animals and many strategies have evolved to allow animals to return to a known goal. 麻豆传媒高清版ing spatial navigation has revealed much about the structure and function of the brain, how it is impacted by age, damage and disease. It has also revealed much about how sensory systems are integrated to provide information for locating position within the environment. Among the most remarkable navigators are small migratory songbirds. These animals travel thousands of kilometres between breeding areas and winter sites, and show remarkable precision, being able to return to the same breeding site, sometimes even nest, year after year. These small birds also show remarkable flexibility, being able to correct for large displacements from their normal migratory path, to places they could not have been to before, and return to their normal breeding or winter area. This appears to be learned during their first migratory journey from the breeding area they were born in, to the winter ground that they reach after their first migration. Scientists hypothesise that they navigate in this way using something akin to a map and a compass. The map step of this process is crucial, as it allows them to determine their location in relation to their desired goal and is thought to function essentially like our Cartesian coordinate system, providing latitude and longitudinal information. This is an ability that seems to be beyond humans without resorting to technology, and yet birds can do this based on cues sensed in the environment. Whilst much research effort has been expended in trying to discover how they achieve this, it remains essentially unsolved, as we do not fully understand what environmental cues are used to determine their position. Received wisdom has it that the cues and senses used in the map are separate from those used in the compass. Thus celestial cues such as the sun and stars provide compass directions, but not location. The exception to this is the Earth's magnetic field. However, It has been argued that birds require and possess two separate magnetic sensory systems, one for the compass step, located in the eye, and a second for the map step, located in the beak. However, recent evidence has called into question whether the beak based sense exists. In addition to this, new evidence indicates that one cues that is used in locating the birds' position is declination, which varies from east to west in some parts of the world, i.e. It provides a cue to longitude?. This is calculated by comparing magnetic north detected by the magnetic compass with geographic (true) north detected by a celestial compass (the sun or stars). This means that contrary to previous expectations, the sensory systems used in the map are not separate from the compass, but may be integrated into it. This discovery leaves many open questions however. How exactly to birds calculate declination? As the majority of birds are night migrants it makes sense that the star compass is the primary candidate, but some studies suggest that these birds calibrate the magnetic compass with sunset, not the stars. Do birds need two magnetic senses? If birds can calculate their longitudinal position with the magnetic sense in the eye, do they also calculate their latitudinal position with this sensory system? Do celestial cues, long relegated to the role of compass, actually play a greater role in the map, as they also could provide information on latitude. How do birds learn these cues? Birds must learn these cues on their first migratory journey, but the precise way in which they build this map is still entirely unknown. This research project will investigate these questions using a small songbird, the Eurasian reed warbler, to provide new insights into how it is able to navigate between its breeding grounds in Europe and winter grounds in Sub Saharan Africa.

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• 01/02/2016 鈥� 10/10/2017 (Finished)

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