Publications

Briscoe NJ, Morris SD, Mathewson PD, Buckley LB, Jusup M, Levy O, Maclean IMD, Pincebourde S, Riddell EA, Roberts JA, Schouten R, Sears MW, Kearney MR (2022) Mechanistic forecasts of species responses to climate change: The promise of biophysical ecology. Global Change Biology. 29(6) 1451-1470. pdf

Stark G, Ma L, Zeng Z, Du W, Levy O (2022) Rocks and vegetation cover improve body condition of desert lizards during both summer and winter. Integrative and Comparative Biology. ​62(4): 1031–1041. pdf, code and data

Ma L, Buckley L, Levy O, Du W (2022) Variable impacts on reproductive energetics may render oviparous squamates more vulnerable to climate warming than viviparous species. Ecography. 2022(5): e05624. pdf

Sun B, Ma L, Wang Y, Mi C, Buckley L, Levy O, Lu H, Du W (2021) Latitudinal gradients in embryonic thermal tolerance and developmental plasticity interactively predict lizard responses to climate change. Ecological Monographs. 91(3): e01468. pdf

Huey R, Ma L, Levy O, and Kearney M (2021) Three questions about the eco-physiology of overwintering underground​. Ecology Letters. 24(2): 170-185. pdf

Wheatly R, Pavlik T, Levy O, and Wilson RS (2020) Habitat and performance interact to determine the outcomes of terrestrial predator–prey interactions.  Journal of Animal Ecology. 89(12): 2958-2971. pdf

Wilson† RS, Pavlic T, Wheatley R, Niehaus AC,  Levy† O (2020) Modeling escape success in terrestrial predator–prey interactions. Integrative and Comparative Biology. 60(2): 497-508. pdf
​† equal contribution

Angilletta MJ, Sears MW, Levy O, Youngblood J, and VandenBrooks JM (2019) Fundamental flaws with the fundamental niche. Integrative and Comparative Biology 59(4): 1038-1048. pdf

Levy O, Dayan T, Porter WP, and Kronfeld-Schor N (2019) Time and ecological resilience: can diurnal animals compensate for climate change by shifting to nocturnal activity? Ecological Monographs 89(1): e01334. pdf

Carlo MA, Riddell EA, Levy O, and Sears MW (2018) Recurrent sub-lethal warming decreases embryo survival, inhibits development, and alters species range projections under climate change. Ecology Letters 21(1): 104-116. pdf

Levy† O, Borchert† J, Rusch T, Buckley LB, and Angilletta MJ (2017) Diminishing returns limit energetic costs of climate change. Ecology 98(5): 1217-1228. pdf
† equal contribution.

​Basson CH, Levy O, Angilletta MJ, and Clusella-Trullas S (2017) Lizards paid a greater opportunity cost to thermoregulate in a less heterogeneous environment. Functional Ecology​ 31(4): 856-865. pdf

Telemeco RS, Fletcher B, Levy O, Riley A, Rodriguez-Sanchez Y, Smith CD, Teague C, Waters A, Angilletta MJ, and Buckley LB (2017) Lizards fail to plastically adjust nesting behavior or thermal tolerance as needed to buffer populations from climate change. Global Change Biology 23(3): 1075-1084. pdf

Levy O, Dayan T, Porter WP, and Kronfeld-Schor N (2016) Foraging activity pattern is shaped by water loss rates in a diurnal desert rodent. The American Naturalist 188(2): 205-218. pdf

Levy O, Buckley LB, Keitt TH, and Angilletta MJ (2016) A dynamically downscaled projection of past and future microclimates​. Ecology 97: 1888. data, metadata

Levy O, Buckley LB, Keitt TH, and Angilletta MJ (2016) Ontogeny constrains phenology: opportunities for activity and reproduction interact to dictate potential phenologies in a changing climate. Ecology Letters 19(6): 620-628. pdf

Levy O, Buckley LB, Keitt TH, Smith CD, Boateng KO, Kumar DS, and Angilletta MJ (2015) Resolving the life cycle alters expected impacts of climate change. Proceeding of the Royal Society B 282: 2813. pdf  

Levy† O, Ball† BA, Bond-Lamberty B, Cheruvelil KS, Finley AO, Lottig N, Punyasena S, Xiao J, Zhou J, Buckley LB, Filstrup CT, Kiett TH, Kellner JR, Knapp AK, Richardson AD, Tcheng D, Toomey M, Vargas R, Voordeckers JW, Wagner T, and Williams JW (2014)  Approaches to advance scientific understanding of macrosystems. Frontiers in Ecology and the Environment 12(1): 15–23.  pdf
† equal contribution. 

Levy O, Dayan T, Rotics S, and Kronfeld-Schor N (2012) Foraging sequence, energy intake, and torpor: An individual-based field study of energy balancing in desert golden spiny mice. Ecology Letters 5(11): 1240-1248.  pdf

Levy O, Dayan T, Kronfeld-Schor N, and Porter WP (2012) Biophysical modeling of the temporal niche: from first principles to the evolution of activity patterns. The American Naturalist 179(6): 794-804. pdf 

Gutman† R, Dayan T, Levy† O, Schubert† I, and Kronfeld-Schor N (2011) The effect of the lunar cycle on stress hormone levels and foraging ecology of nocturnally and diurnally active spiny mice. PLoS ONE 6(8): e23446. pdf
† equal contribution. 

Levy O, Dayan T, and Kronfeld-Schor N (2011) Interspecific competition and torpor in golden spiny mice: Two sides of the energy acquisition coin. Integrative and Comparative Biology 51(3): 441-448. pdf 

Levy O, Dayan T, and Kronfeld-Schor N (2011) Adaptive thermoregulation in golden spiny mice: The influence of season and food availability on body temperature. Physiological and Biochemical Zoology 84(2): 175-184. pdf

Rotics S, Dayan T, Levy O, and Kronfeld-Schor N (2011) Light masking in the field: an experiment with nocturnal and diurnal spiny mouse species under semi-natural field conditions. Chronobiology International 28(1): 70-75. pdf

Levy O, Dayan T, and Kronfeld-Schor N (2007) The relationship between the golden spiny mouse circadian system and its diurnal activity: an experimental field enclosures and laboratory study. Chronobiology International 24(4): 599-613. pdf