Climate-dependent effectiveness of nonpharmaceutical interventions on COVID-19 mitigation.

Environmental factors have a significant impact on the transmission of infectious diseases. Existing results show that the novel coronavirus can persist outside the host. We propose a susceptible–exposed–presymptomatic–infectious–asymptomatic–recovered–susceptible (SEPIARS) model with a vaccination compartment and indirect incidence to explore the effect of environmental conditions, temperature and humidity, on the transmission of the SARS-CoV-2 virus. Using climate data and daily confirmed cases data in two Canadian cities with different atmospheric conditions, we evaluate the mortality rates of the SARS-CoV-2 virus and further estimate the transmission rates by the inverse method, respectively. The numerical results show that high temperature or humidity can be helpful in mitigating the spread of COVID-19 during the warm summer months. Our findings verify that nonpharmaceutical interventions are less effective if the virus can persist for a long time on surfaces. Based on climate data, we can forecast the transmission rate and the infection cases up to four weeks in the future by a generalized boosting machine learning model. • Temperature and humidity affect the transmission of COVID-19. • Mortality rates of SARS-CoV-2 virus in two Canadian cities are evaluated. • The transmission rates in two Canadian cities are estimated by inverse method. • The transmission rates and infection cases up to 4 weeks are forecasted. • NPIs are less effective if the virus can persist for a long time on surfaces. [ABSTRACT FROM AUTHOR]