| Estimating epidemic exponential growth rate and basic reproduction number J Ma Infectious Disease Modelling 5, 129-141, 2020 | 365 | 2020 |
| Generality of the final size formula for an epidemic of a newly invading infectious disease J Ma, DJD Earn Bulletin of mathematical biology 68, 679-702, 2006 | 344 | 2006 |
| Cholera epidemic in Haiti, 2010: using a transmission model to explain spatial spread of disease and identify optimal control interventions AR Tuite, J Tien, M Eisenberg, DJD Earn, J Ma, DN Fisman Annals of internal medicine 154 (9), 593-601, 2011 | 298 | 2011 |
| Effective degree network disease models J Lindquist, J Ma, P Van den Driessche, FH Willeboordse Journal of mathematical biology 62 (2), 143-164, 2011 | 259 | 2011 |
| Epidemic threshold conditions for seasonally forced SEIR models J Ma, Z Ma Mathematical Biosciences and Engineering 3 (1), 161, 2006 | 204 | 2006 |
| Inferring the causes of the three waves of the 1918 influenza pandemic in England and Wales D He, J Dushoff, T Day, J Ma, DJD Earn Proceedings of the Royal Society B: Biological Sciences 280 (1766), 20131345, 2013 | 167 | 2013 |
| Estimating initial epidemic growth rates J Ma, J Dushoff, BM Bolker, DJD Earn Bulletin of mathematical biology 76 (1), 245-260, 2014 | 151 | 2014 |
| Survival and stationary distribution analysis of a stochastic competitive model of three species in a polluted environment Y Zhao, S Yuan, J Ma Bulletin of mathematical biology 77 (7), 1285-1326, 2015 | 113 | 2015 |
| Reconstructing influenza incidence by deconvolution of daily mortality time series E Goldstein, J Dushoff, J Ma, JB Plotkin, DJD Earn, M Lipsitch Proceedings of the National Academy of Sciences 106 (51), 21825-21829, 2009 | 108 | 2009 |
| Age-specific mortality risk from pandemic influenza J Ma, J Dushoff, DJD Earn Journal of theoretical biology 288, 29-34, 2011 | 88 | 2011 |
| Mechanistic modelling of the three waves of the 1918 influenza pandemic D He, J Dushoff, T Day, J Ma, DJD Earn Theoretical Ecology 4 (2), 283-288, 2011 | 64 | 2011 |
| Vaccination against 2009 pandemic H1N1 in a population dynamical model of Vancouver, Canada: timing is everything JM Conway, AR Tuite, DN Fisman, N Hupert, R Meza, B Davoudi, ... BMC public health 11 (1), 932, 2011 | 50 | 2011 |
| The importance of contact network topology for the success of vaccination strategies J Ma, P van den Driessche, FH Willeboordse Journal of theoretical biology 325, 12-21, 2013 | 42 | 2013 |
| Effective degree household network disease model J Ma, P van den Driessche, FH Willeboordse Journal of mathematical biology 66 (1-2), 75-94, 2013 | 42 | 2013 |
| The evolution of resource adaptation: how generalist and specialist consumers evolve J Ma, SA Levin Bulletin of mathematical biology 68 (5), 1111-1123, 2006 | 42 | 2006 |
| Epidemic dynamics on semi-directed complex networks X Zhang, GQ Sun, YX Zhu, J Ma, Z Jin Mathematical biosciences 246 (2), 242-251, 2013 | 39 | 2013 |
| Network evolution by different rewiring schemes J Lindquist, J Ma, P Van den Driessche, FH Willeboordse Physica D: Nonlinear Phenomena 238 (4), 370-378, 2009 | 30 | 2009 |
| Edge-based epidemic spreading in degree-correlated complex networks Y Wang, J Ma, J Cao, L Li Journal of theoretical biology 454, 164-181, 2018 | 29 | 2018 |
| Model for disease dynamics of a waterborne pathogen on a random network M Li, J Ma, P van den Driessche Journal of mathematical biology 71 (4), 961-977, 2015 | 28 | 2015 |
| Edge removal in random contact networks and the basic reproduction number D Koch, R Illner, J Ma Journal of mathematical biology 67 (2), 217-238, 2013 | 27 | 2013 |
David EarnProfessor of Mathematics, McMaster UniversityVerified email at math.mcmaster.ca
