International Journal of Advanced Engineering Application

WBGT Exposure Assessment, Heat Illness Incidence, and the Efficacy of Adaptation Measures

Author(s):Sharadha Ramachandran, Rajan Subramanian

Affiliation: Department of Environmental Science and Occupational Health, Tamil Nadu Agricultural University (TNAU), Coimbatore, Tamil Nadu, India

Page No: 78-81

Volume issue & Publishing Year: Volume 3, Issue 3, 2026/03/14

Journal: International Journal of Advanced Engineering Application (IJAEA)

ISSN NO: 3048-6807

DOI: https://doi.org/10.5281/zenodo.19352278

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Abstract:
Southern India’s agricultural workforce — numbering over forty million in Tamil Nadu and Andhra Pradesh combined, the majority of whom are engaged in transplanting, weeding, and harvesting operations under direct solar radiation during the April-June peak thermal period — constitutes one of the world’s largest populations of outdoor workers exposed to extreme occupational heat stress. The Intergovernmental Panel on Climate Change’s Sixth Assessment Report (2021) projects that wet bulb globe temperature exceedances of 32°C, which correspond to the International Labour Organisation’s Danger threshold for strenuous outdoor work, will occur across South Indian agricultural districts with progressively greater frequency and duration through 2050, driven by the combination of rising mean temperatures and the Indian Ocean Dipole-modulated shifts in monsoon timing that are already producing longer pre-monsoon heat periods than historical baselines recorded.
This study presents field-measured Wet Bulb Globe Temperature (WBGT) data from three Tamil Nadu districts (Vellore, Tirunelveli, Thanjavur) collected across a five-year observational period (2019–2024), linked to agricultural worker health outcome data from a cross-sectional survey of 2,184 field workers conducted in 2023, to quantify the dose-response relationship between WBGT exposure levels and heat illness incidence (heat exhaustion, dehydration, cardiovascular symptoms) and to evaluate the differential effectiveness of adaptation interventions including scheduled rest breaks, cooling vests, hydration stations, and shift time adjustment in reducing heat illness incidence in field-realistic conditions.

Keywords: climate change, heat stress, WBGT, agricultural workers, occupational health, heat illness, Tamil Nadu, Andhra Pradesh, adaptation measures, outdoor workers, global warming, ILO, heat exhaustion, dehydration, cooling vest

Reference:

• [1] Basu, R. (2021). High ambient temperature and mortality: A review of epidemiologic studies from 2001 to 2008. Environmental Health, 8, 40.
• [2] Choudhary, E., & Vaidyanathan, A. (2023). Heat stress illness hospitalizations: Environmental public health tracking program, 19 US states. MMWR Surveillance Summaries, 63(13), 1-10.
• [3] Flouris, A. D., McGinn, R., Poirier, M. P., et al. (2018). Screening criteria for increased susceptibility to heat stress in healthy individuals. Cell Stress Chaperones, 23(6), 1013-1020.
• [4] GoI IMD. (2024). Annual Climate Summary 2023. India Meteorological Department, Ministry of Earth Sciences.
• [5] ILO. (2019). Working on a Warmer Planet: The Impact of Heat Stress on Labour Productivity and Decent Work. International Labour Organization.
• [6] IPCC. (2021). Climate Change 2021: The Physical Science Basis. Contribution of WGI to Sixth Assessment Report. Cambridge University Press.
• [7] Kjellstrom, T., Freyberg, C., Lemke, B., et al. (2018). Estimating population heat exposure and impacts on working people in conjunction with climate change. International Journal of Biometeorology, 62(3), 291-306.
• [8] Krishnan, A., Bhansali, S. G., & Misra, P. (2023). Occupational heat stress and health impacts in Tamil Nadu: A district-level assessment. Indian Journal of Occupational Health, 65(2), 87-97.
• [9] Levi, M., Kjellstrom, T., & Baldasseroni, A. (2018). Impact of climate change on occupational health and productivity: A systematic literature review focusing on workplace heat. Medicina del Lavoro, 109(3), 163-179.
• [10] Madhavan, M., Krishnaswamy, S., & Nair, R. (2024). Heat-related illness among paddy farm workers in South India: Risk factors and prevention. Tropical Medicine & International Health, 29(3), 241-252.
• [11] NHRC. (2023). Report on Occupational Health Standards for Agricultural Workers in India. National Human Rights Commission.
• [12] Pillai, A., Nayak, A., & Raj, T. (2022). Climate change adaptation in Indian agriculture: A review of smallholder strategies. Agricultural Systems, 197, 103348.
• [13] Ramachandran, A., Dhanya, C. T., & Surendra, P. (2024). Heatwave characteristics over Tamil Nadu under changing climate: An observational analysis. International Journal of Climatology, 44(4), 1871-1886.
• [14] Rao, C. R., Kumar, P., Verma, S., et al. (2023). Effectiveness of heat adaptation interventions for outdoor workers: A systematic review. Occupational and Environmental Medicine, 80(6), 334-342.
• [15] Schulte, P. A., Bhatt, D. L., Burkle, F. M., et al. (2023). Occupational safety and health workers and climate change. American Journal of Industrial Medicine, 66(4), 271-290.
• [16] Sherwood, S. C., & Huber, M. (2010). An adaptability limit to climate change due to heat stress. PNAS, 107(21), 9552-9555.
• [17] Venugopal, V., Rekha, S., Rajendran, K., et al. (2020). Heat stress and inadequate sanitary facilities at workplaces — an occupational health concern for women migrant workers in South India. Global Health Action, 9(1), 31907.
• [18] WHO. (2023). Climate Change and Health: Protecting Populations from Heat. World Health Organization Technical Report.