Environmental Degradation and Livestock Productivity under Climate Stress: Implications for Sustainable Agricultural Development
DOI:
https://doi.org/10.29145/eer.91.04Keywords:
Environmental degradation, Livestock productivity, ; Climate stress, CO₂ emissions, Heat stress, Sustainable agricultural development, PakistanAbstract
Environmental degradation is a multifaceted issue that drastically reduces production in Pakistan's agricultural sector. This study aims to investigate how environmental degradation affects cattle production in Pakistan, with implications for sustainable sectoral growth between 1980 and 2022. A data analysis method called the Autoregressive Distributed Lag estimator is used to determine how environmental deterioration (measured by CO2) and other factors, like water availability, heat stress, inflation, floods, and crop and forest productivity, affect livestock output. The results corroborate the substantial and detrimental long-term impacts of inflation and CO2. Livestock productivity is positively and significantly affected by forest area, agricultural land, and water availability. The findings demonstrate that decreasing environmental deterioration and improving resource management and adaptability are necessary for Pakistan's cattle industry to thrive sustainably. The report also highlights the necessity of unified strategies focused on resource optimization, climate resilience, and environmental management.
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Ahmadzai, M. R., Ismail, M. H., Hassan Zaki, P., Magiman, M. M., Bawon, P., Rahmawaty, & Ullah, H. (2025). Transforming livestock production: unraveling the impact of socioeconomic dynamics and land use changes in Khost Province. Journal of Land Use Science, 20(1), 82-97.
Arshad, M., & Abdulai, A. (2025). Heterogeneous impact of adoption intensity of climate-smart agricultural practices on the welfare of livestock farmers in Pakistan. Regional Environmental Change, 25(4), 140.
Awan, N. W., & Abro, A. A. (2021). Do Environmental Degradation and Agricultural Accessories Impact on Agricultural Crops and Land Revenue? Evidence from Pakistan. Sarhad Journal of Agriculture, 37.
Baris-Tuzemen, O., & Lyhagen, J. (2026). Revisiting the role of climate change on crop production: evidence from Mediterranean countries: O. Baris-Tuzemen, J. Lyhagen. Environment, Development and Sustainability, 28(1), 637-650.
Campos‐Requena, N., Rivera, D., Fernández, F. J., Vásquez‐Lavin, F., & Ponce Oliva, R. d. (2026). Eco‐Innovation: Drivers and Obstacles for Agriculture Firms in a Developing Country. Business Strategy and the Environment, 35(3), 3247-3264.
Chandio, A. A., Gokmenoglu, K. K., Joyo, M. A., & Jiang, Y. (2024). Modeling the climate change impacts on major fruits production: Recent evidence from Pakistan. Scientia Horticulturae, 324, 112618.
Dey, S. (2023). Climate change effects on livestock production in Bangladesh and its economic impacts. SAARC Journal of Agriculture, 21(2), 227-238.
Dickey, D. A., & Fuller, W. A. (1979). Distribution of the estimators for autoregressive time series with a unit root. Journal of the American statistical association, 74(366a), 427-431.
[Record #513 is using a reference type undefined in this output style.]
Farooq, B., Farooq, M., Anjum, S., Nazir, A., Hashem, A., & Abd-Allah, E. F. (2025). Sustainable Development and the Global Economy: Pathways to Achieving Food Security. In Environmental Landscape and Sustainable Biodiversity for Healthy Green Growth (pp. 57-62). Springer.
Gerber, P., Vellinga, T., Opio, C., & Steinfeld, H. (2011). Productivity gains and greenhouse gas emissions intensity in dairy systems. Livestock science, 139(1-2), 100-108.
Ghulam Habib, G. H., & Khan, A. (2018). Assessment and mitigation of methane emissions from livestock sector in Pakistan.
Headey, D., & Fan, S. (2008). Anatomy of a crisis: the causes and consequences of surging food prices. Agricultural economics, 39, 375-391.
Hussain, I., & Rehman, A. (2022). How CO2 emission interacts with livestock production for environmental sustainability? evidence from Pakistan. Environment, Development and Sustainability, 24(6), 8545-8565.
Jadhav, G. S., & Sonawane, A. E. (2024). Impact of Environmental, Health, and Economic Factors on Dairy Farmers' Poverty in Shevgaon Tehsil (Dist. Ahmednagar), Maharashtra. Environment, 1(1), 1-6.
Jadoon, A. U., Zhao, Z., Wosene, G., Wondim, D., & Yunxian, Y. (2025). The Impact of Environmental Degradation on Agricultural Crop Productivity: The Case of Pakistan With Simulated ARDL Approach. Food Science & Nutrition, 13(9), e70876.
Jongbo, A. O., de Borba, L. P., Pereira, R. M. M., Bello, Q. O., Gregoratto, L. L., de Souza, D. P., Adeyeye, O. A., & Vieira, F. M. C. (2026). Heat stress in livestock under tropical climates: impacts and mitigation strategies. Tropical Animal Health and Production, 58(2), 65.
Khalifa, J. (2025). The impacts of climate change, agricultural productivity, and food security on economic growth in Tunisia: Evidence from an econometrics analysis. Research on World Agricultural Economy, 577-599.
Khryseva, A. A., Ezangina, I. A., Sazonov, S. P., Kotov, V. V., & Martynov, I. A. (2026). Approaches to Sustainable Food Security in the Face of Climate Transformations. In Smart Transport Systems and the Digital Economy Infrastructure (pp. 315-323). Springer.
Khurshid, N., Ajab, S., Tabash, M. I., & Barbulescu, M. (2023). Asymmetries in climate change and livestock productivity: non-linear evidence from autoregressive distribution lag mode. Frontiers in Sustainable Food Systems, 7. https://doi.org/10.3389/fsufs.2023.1139631
Liu, W., Zhou, J., Ma, Y., Chen, S., & Luo, Y. (2024). Unequal impact of climate warming on meat yields of global cattle farming. Communications Earth & Environment, 5(1), 65.
Malek, Ž., & See, L. (2026). Future heatwave exposure of the European cattle sector. npj Sustainable Agriculture, 4(1), 6.
Monteiro, A., Barreto-Mendes, L., Fanchone, A., Morgavi, D. P., Pedreira, B. C., Magalhães, C. A., Abdalla, A. L., & Eugène, M. (2024). Crop-livestock-forestry systems as a strategy for mitigating greenhouse gas emissions and enhancing the sustainability of forage-based livestock systems in the Amazon biome. Science of the Total Environment, 906, 167396.
Musalia, L. M., Odilla, G. A., Nderi, O. M., & Muleke, V. (2016). Current status of fodder production, conservation and marketing in the arid and semi-arid lands of Tharaka Nithi County, Kenya. African Journal of Agricultural Research, 11(26), 2337-2347.
Neira, M., Georgiades, P., Proestos, Y., Economou, T., Araya, J., Malas, S., Omirou, M., Sparaggis, D., Hadjipavlou, G., & Lelieveld, J. (2026). Climate change and thermal stress in cattle: Global projections with high temporal resolution. PLOS Climate, 5(1), e0000761.
Olsen, H. F., Samsonstuen, S., Mogensen, L., Röös, E., Knudsen, M. T., & Møller, H. (2025). When arable land is the limit: Paths for future livestock production–An example from Norway. Agricultural systems, 229, 104446.
Orach, H., Qianling, S., Arthur, A. A., Ankrah Twumasi, M., & Zhang, S. (2025). Impacts of carbon dioxide emissions on agricultural production indicators in Sub-Saharan African countries: New perspectives from static and dynamic panel models. Environmental Science and Pollution Research, 32(3), 1247-1271.
Otim, J., Watundu, S., Mutenyo, J., Bagire, V., & Adaramola, M. S. (2023). Effects of carbon dioxide emissions on agricultural production indexes in East African community countries: Pooled mean group and fixed effect approaches. Energy Nexus, 12, 100247.
Palandri, C., Frank, E. G., Kimhi, A., Lavon, Y., Ezra, E., & Fishman, R. (2025). High-frequency data reveal limits of adaptation to heat in animal agriculture. Science Advances, 11(27), eadw4780.
Pesaran, M. H., Shin, Y., & Smith, R. J. (2001). Bounds testing approaches to the analysis of level relationships. Journal of applied econometrics, 16(3), 289-326.
Phillips, P. C., & Perron, P. (1988). Testing for a unit root in time series regression. biometrika, 75(2), 335-346.
Samad, H. A., Kumar Eshwaran, V., Muquit, S. P., Sharma, L., Arumugam, H., Kant, L., Fatima, Z., Sharun, K., Aradotlu Parameshwarappa, M., & Latheef, S. K. (2025). Sustainable livestock solutions: Addressing carbon footprint challenges from Indian and global perspectives. Sustainability, 17(5), 2105.
Shahid, Farhat Parveen, Rana Khalid Mehmood, Qamar uz-Zaman, & Raza, H. A. (2021). Emission of carbon warming the climatic change adversely affects the livestock sector: an empirical study of pakistan. Humanities and social sciences 9(2), 530-539.
Sileshi, Z., Tsegahun, A., Yami, A., & Tegegne, A. (2001). Status of livestock research and development in the highlands of Ethiopia.
Tan, D., Adedoyin, F. F., Alvarado, R., Ramzan, M., Kayesh, M. S., & Shah, M. I. (2022). The effects of environmental degradation on agriculture: Evidence from European countries. Gondwana Research, 106, 92-104.
Thornton, P. K., van de Steeg, J., Notenbaert, A., & Herrero, M. (2009). The impacts of climate change on livestock and livestock systems in developing countries: A review of what we know and what we need to know. Agricultural systems, 101(3), 113-127.
Usman, M., Ali, A., Rosak-Szyrocka, J., Pilař, L., Baig, S. A., Akram, R., & Wudil, A. H. (2023). Climate change and livestock herders wellbeing in Pakistan: Does nexus of risk perception, adaptation and their drivers matter? Heliyon, 9(6).
Win, Z. C. (2023). Analysis on the effects of agricultural production on economic growth IN MYANMAR (1987-2021) MERAL Portal].
Zolotnytska, Y., Krupin, V., & Krzyżanowski, J. (2026). Agribusiness Corporations and Family Farms in Ukraine: Impacts on Regional Agricultural and Rural Sustainability and Supply Chain Implications. Sustainability, 18(7), 3629.
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Copyright (c) 2026 Gulalai (Author); Nazish Kanval

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