| Simultaneous evolution of multiple dispersal components and kernel S Tung, A Mishra, PM Shreenidhi, MA Sadiq, S Joshi, VRS Sruti, S Dey Oikos 127 (1), 34-44, 2018 | 38 | 2018 |
| Pre‐dispersal context and presence of opposite sex modulate density dependence and sex bias of dispersal A Mishra, S Tung, VRS Sruti, MA Sadiq, S Srivathsa, S Dey Oikos 127 (11), 1596-1604, 2018 | 22 | 2018 |
| Sex differences in dispersal syndrome are modulated by environment and evolution A Mishra, S Tung, PM Shreenidhi, M Aamir Sadiq, VR Shree Sruti, ... Philosophical Transactions of the Royal Society B: Biological Sciences 373 …, 2018 | 22 | 2018 |
| Evolution of dispersal syndrome and its corresponding metabolomic changes S Tung, A Mishra, N Gogna, M Aamir Sadiq, PM Shreenidhi, ... Evolution, 2018 | 21 | 2018 |
| A comparison of six methods for stabilizing population dynamics S Tung, A Mishra, S Dey Journal of Theoretical Biology 356, 163-173, 2014 | 21 | 2014 |
| Complex interaction of resource availability, life-history and demography determines the dynamics and stability of stage-structured populations S Tung, M Rajamani, A Joshi, S Dey Journal of theoretical biology 460, 1-12, 2019 | 13 | 2019 |
| Mate-finding dispersal reduces local mate limitation and sex bias in dispersal A Mishra, S Tung, VR Shree Sruti, SV Srivathsa, S Dey Journal of Animal Ecology 89 (9), 2089–2098, 2020 | 10 | 2020 |
| Stabilizing the dynamics of laboratory populations of Drosophila melanogaster through upper and lower limiter controls S Tung, A Mishra, S Dey Ecological complexity 25, 18-25, 2016 | 10 | 2016 |
| Simultaneous enhancement of multiple stability properties using two-parameter control methods in Drosophila melanogaster S Tung, A Mishra, S Dey Ecological complexity 26, 128-136, 2016 | 8 | 2016 |
| The genetic basis of differential autodiploidization in evolving yeast populations S Tung, CW Bakerlee, AM Phillips, AN Nguyen Ba, MM Desai G3 11 (8), jkab192, 2021 | 6 | 2021 |
| Insights into the mechanistic underpinnings for the evolution of population stability in Drosophila, based on modeling of laboratory populations S Tung Indian Institute of Science Education and Research Kolkata, 2012 | 3 | 2012 |
| Desiccation Stress Acts as Cause as well as Cost of Dispersal in Drosophila melanogaster A Mishra, S Tung, VRS Sruti, PM Shreenidhi, S Dey The American Naturalist 199 (4), E111-E123, 2022 | 2 | 2022 |
| Diet‐induced plasticity of life‐history traits and gene expression in outbred Drosophila melanogaster population A Mudunuri, M Chandrakanth, S Khan, C Sura, N Kumar, S Tung Ecology and Evolution 14 (2), e10976, 2024 | 1 | 2024 |
| Comparison of six methods for stabilizing metapopulation dynamics and for their robustness against census noise A Singh, S Tung bioRxiv, 2024.02. 04.578847, 2024 | | 2024 |
| Selection for greater dispersal in early life leads to faster age-dependent decline in locomotor activity and shorter lifespan B Ruchitha, N Kumar, C Sura, S Tung | | 2022 |
| Selection for greater dispersal in early life leads to increased rate of age-dependent decline in locomotor activity and shorter lifespan BG Ruchitha, N Kumar, C Sura, S Tung bioRxiv, 2022.07. 03.498422, 2022 | | 2022 |
| Desiccation Stress Acts as Cause as well as Cost of Dispersal in Drosophila melanogaster S TUNG, A MISHRA, S DEY, VRS SRUTI, PM SHREENIDHI University of Chicago Press, 2022 | | 2022 |
| Theoretical and empirical investigations on population stability and dispersal evolution using laboratory populations of Drosophila melanogaster S Tung Dept. of Biology, 2018 | | 2018 |
Abhishek MishraUniversity of Wisconsin-MadisonVerified email at wisc.edu
