1Krishna Institute of Science and Technology, Krishna Vishwa Vidyapeeth “Deemed to be University”, Karad, Satara - 415 539, Maharashtra, India, E-mail: njsuryawanshi1981@gmail.com
2Vishwakarma Institute of Technology, Pune - 411 048, Maharashtra, India, E-mail: manohar.kodmelwar@viit.ac.in
3Department of Biotechnology and Microbiology, Noida International University, Greater Noida, Gautam Buddha Nagar - 201 310, Uttar Pradesh, India, E-mail: ved.verma@niu.edu.in
4Department of Entomology, College of Agriculture, Parul University, Vadodara - 391 760, Gujarat, India, E-mail: mukesh.laichattiwar91094@paruluniversity.ac.in
Department of Agricultural Extension and Communication, Institute of Agricultural Sciences, Siksha ‘O’ Anusandhan (Deemed to be University), Bhubaneswar -751 030, Odisha, India
*Corresponding authors’ E-mail: anshumanjena@soa.ac.in
Online published on 18 February, 2026.
Present studies aimed to identify the primary factors influencing the response of pests to climate change particularly changes in temperature, rainfall patterns, and surrounding events. Case studies reveal how complex these connections are by illustrating instances of temperature-related insect outbreaks. Further study also discusses advantages and drawbacks as well as related prediction models using temperature data to project insect behaviour relationship with climate change. The findings make it abundantly evident that we must have flexible management strategies including forecasts of climate change while controlling pests. By applying fresh technology and approaches from several domains, stakeholders may raise their preparedness for next pest outbreaks.
Adaptation, Agriculture, Biodiversity, Climate, Distribution, Ecology, Economy, Lifecycle, Management, Outbreaks, Pests, Resilience, Security, Strategy, Temperature