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[23] Lussich, F., Dhaliwal, J. K., Faiia, A. M., Jagadamma, S., Schaeffer, S. M., & Saha, D. (2024). Cover crop residue decomposition triggered soil oxygen depletion and promoted nitrous oxide emissions. Scientific Reports, 14(1), 8437.

[22] Dhaliwal, J.K., Anderson, S.H., Lee, J., Sindhu, J., & Saha, D. (2024). Computed tomography scanning of intact soil cores revealed macropore-controlled N2O emissions under long-term soil health practices. Science of The Total Environment.


[21] Panday, D., Saha, D., Lee, J., Jagadamma, S., Adotey, N., & Mengistu, A. (2022). Cover crop residue influence on soil N2O and CO2 emissions under wetting‐drying intensities: An incubation study. European Journal of Soil Science, 73(5).

[20] Dhaliwal, J.K., Panday, D., Saha, D., Lee, J., Jagadamma, S., Schaeffer, S., & Mengistu, A. (2022). Predicting and interpreting cotton yield and its determinants under long-term conservation management practices using machine learning. Computers and Electronics in Agriculture, 107107.


[19] Saha, D., Kaye, J. P., Bhowmik, A., Bruns, M. A., Wallace, J., Kemanian, A. R. 2021. Organic fertility inputs synergistically increase denitrification-derived nitrous oxide emissions in agroecosystems. Ecological Applications, e02403.

[18] Yoder, D., Jagadamma, S., Saha, D., Adotey, N., Lee, J., Schaeffer, S., Walker, F. R., Budipradigdo, M., Nouri, A., Singh, S., Xu, S. 2021. Soil health: Meaning, measurement, and value through a critical zone lens. Journal of Soil and Water Conservation. https://doi:10.2489/jswc.2022.00042.

[17] Littrell, J., Xu, S., Omondi, E., Saha, D., Lee, J., Jagadamma, S. 2021. Long-term organic management combined with conservation tillage enhanced soil organic carbon accumulation and aggregation. Soil Science Society of America Journal, 85, 1741-1754.

[16] Morris, A.H., Isbell, S.A., Kaye, J.P., and Saha, D. 2021. Mitigating nitrogen pollution with under-sown legume-grass cover crop mixtures in winter cereals. Journal of Environmental Quality,


[15] Saha, D., Basso, B., and Robertson, G. P. 2020. Machine learning reveals simplified path for predicting N2O fluxes from agriculture. Environmental Research Letters,

[14] Berardi, D., Brzostek, E., Blanc-Betes, E., Davidson, B., DeLucia, E. H., Hartman, M. D., Kent, J., Parton, W., Saha, D., and Hudiburg, T. W. 2020. 21st century biogeochemical modeling: Challenges for Century-based models and where do we go from here? Global Change Biology Bioenergy,


[13] McDaniel, M.D., Saha, D., Dumont, M.G., Hernández, M., Adams, M.A. 2019. The effect of land-use change on soil CH4 and N2O fluxes: a meta-analysis. Ecosystems, [invited co-author]

[12] Rau, B. M., Adler, P. R., Dell, C., Saha, D., and Kemanian, A. R. 2019. Herbaceous perennial biomass production on marginal soils: influence on N2O emissions and shallow groundwater. Biomass & Bioenergy, 122, 90-98.

[11] Bhowmik, A., Kukal, S. S., Saha, D., Sharma, H., Kalia, A., Sharma, S., 2019. Potential Indicators of Soil Health Degradation in Different Land Use-Based Ecosystems in the Shiwaliks of Northwestern India. Sustainability, 11, 1-17.

2018 and earlier

[10] Saha, D., Kemanian, A. R., Montes, F., Gall, H., Rau, B. M., and Adler, P. R. 2018. Lorenz curve and Gini coefficient reveal hot spots and hot moments for nitrous oxide emissions. Journal of Geophysical Research: Biogeochemistry.

[9] Zanella, A., Bolzonella, C., Lowenfels, J., Ponge, J. F., Bouché, M., Blouin, M., Saha, D., Kukal, S. S., Fritz, I., Fukuoka, M., Savory, A., Juilleret, J., Sartori, L., Tatti, D., Kellerman, L., Trachsel, P.,Bourgos, S., Minasny, B., McBratney, A. 2018. Humusica 2, Article 19: Techno humus systems and global change – conservative agriculture and 4/1000 proposal. Applied Soil Ecology, 122 (2), 271-296.

[8] Saha, D., Kemanian, A. R., Rau, B. M., Adler, P. R., and Montes, F. 2017. Designing efficient nitrous oxide sampling strategies in agroecosystems using simulation models. Atmospheric Environment, 155, 189-198.

[7] Saha, D., Rau, B. M., Kaye, J. P., Montes, F., Adler, P. R., and Kemanian, A. R. 2017. Landscape control of nitrous oxide emissions during the transition from conservation reserve program to perennial grasses for bioenergy. Global Change Biology Bioenergy, 9, 783-795, *Cover of the GCB Bioenergy issue 9.4.

[6] Kukal, S. S., Saha, D., Sharma, P., and Sharma, B. D. 2016. Profile distribution of carbon fractions under long-term rice-wheat and maize-wheat production in Alfisols and Inceptisols of northwest IndiaLand Degradation and Development, 27, 1205-1214.

[5] Saha, D., and Kukal, S. S. 2015. Soil structural stability and water retention characteristics under different land uses of degraded lower Himalayas of North-West IndiaLand Degradation and Development, 26, 263-271.

[4] Saha, D., Kukal S. S., and Bawa, S. S. 2014. Soil organic carbon stock and fractions in relation to land use and soil depth in the degraded Shiwaliks hills of lower Himalayas. Land Degradation and Development, 25, 407-416,

[3] Mriganka De., Saha, D., and Chakraborty, S. 2014. Soil structure and strength characteristics in relation to slope segments in a degraded Typic Ustochrepts of North-West India. Soil Horizons,

[2] Kukal S. S., Saha, D., Bhowmik, A., and Dubey, R. K. 2012. Water retention characteristics of soil bio-amendments used as growing media in pot culture. Journal of Applied Horticulture, 14, 92-97.

[1] Saha, D., Kukal, S. S., and Sharma, S. 2011. Land use impacts on SOC fractions and aggregate stability in Typic Ustochrepts of Northwest India. Plant and Soil, 339, 457-470.