1Department of Agronomy, Institute of Agricultural Sciences, Siksha ‘O’ Anusandhan (Deemed to be University), Bhubaneswar - 751 030, Odisha, India, E-mail: jagadishjena@soa.ac.in
2Department of Entomology, College of Agriculture, Parul University, Vadodara - 391 760, Gujarat, India, E-mail: mukesh.laichattiwar91094@paruluniversity.ac.in
3Department of Agriculture, Noida International University, Greater Noida, Gautam Buddha Nagar - 201 310, Uttar Pradesh, India, E-mail: shailesh.solanki@niu.edu.in
4Krishna Institute of Science and Technology, Krishna Vishwa Vidyapeeth “Deemed to be University”, Karad, Satara - 415 539, Maharashtra, India, E-mail: njsuryawanshi1981@gmail.com
Department of Pharmaceutical Chemistry, Krishna Institute of Pharmacy, Krishna Vishwa Vidyapeeth “Deemed to be University”, Karad, Satara - 415 539, Maharashtra, India
*Corresponding authors' E-mail: patilsnehal5121@gmail.com
Online published on 26 September, 2025.
Insect pests are so adjusting to climate change in both physical and behavioural respects. These comprise alterations in their movement, reproduction speed, and rate of growth. These developments let them reside in more locations than they might have in past times. There have been observed microevolutionary changes including the choice of species resistant to pesticides. Case studies of pests such as aphids and locusts reveal how fast evolution may occur and how variations in the quality and quantity of host plants resulting from temperature impact the survival and population increase of pests.
Adaptation, Behavior, Climate, Crop damage, Evolution, Host-plant, Insect, Microevolution, Migration, Pest management, Pests, Pesticide-resistance, Phenology, Physiology, Temperature