Peer-reviewed articles

[18] Geldsetzer, T., Yackel, J., Tomar, K., Mahmud, M., Nandan, V. and Kumar, S. (2023). Melt pond detection on landfast sea ice using dual co-polarized Ku-band backscatter. Remote Sensing of Environment. 296. 113725.

[17] Nandan, V., Willatt, R., Mallett, R., Stroeve, J., Geldsetzer, T., Scharien, R., ... & Hoppman, M. (2023). Wind Transport of Snow Impacts Ka-and Ku-band Radar Signatures on Arctic Sea Ice. The Cryosphere,17, 2211–2229.

[16] Mahmud, M., Nandan, V., Singha, S., Geldsetzer, T., Howell, S. E. L. and Yackel, J. (2022). C- and L-band SAR signatures of Arctic sea ice during freeze-up. Remote Sensing of Environment. 279, 113129.

[15] Nicolus, M. et al. (2022). Overview of the MOSAiC expedition: Snow and sea ice. Elementa: Science of the Anthropocene 10(1). 000046.

[14] Saha, M., Sauda, S. S., Real, H. R. K., & Mahmud, M. (2022). Estimation of annual rate and spatial distribution of soil erosion in the Jamuna basin using RUSLE model: A geospatial approach. Environmental Challenges, 8, 100524.

[13] Scharien, R. K., Geldsetzer, T., Mead, J., Nandan, V., Mahmud, M., and Tavri, A. (2021, August). Surface-based and Fully Polarimetric L-band Frequency Scatterometer System for Field Measurements of Sea Ice. In 2021 IEEE 19th International Symposium on Antenna Technology and Applied Electromagnetics (ANTEM) (pp. 1-2). IEEE.

[12] Mahmud, M., Nandan, V., Howell, S.E., Geldsetzer, T. and Yackel, J. (2020). Seasonal evolution of L-band SAR backscatter over landfast Arctic sea ice. Remote Sensing of Environment, 251, 112049.

[11] Nandan, V., Scharien, R. K., Geldsetzer, T., Kwok, R., Yackel, J. J., Mahmud, M., ... & Stroeve, J. (2020). Snow property controls on modelled Ku-band altimeter estimates of first-year sea ice thickness: Case studies from the Canadian and Norwegian Arctic. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 13, 1082-1096.

[10] Moon, W., Nandan, V., Scharien, R. K., Wilkinson, J., Yackel, J. J., Barrett, A., Mahmud, M., ... & Duke, P. J. (2019). Physical length scales of wind-blown snow redistribution and accumulation on relatively smooth Arctic first-year sea ice. Environmental Research Letters, 14(10), 104003.

[9] Howell, S.E., Small, D., Rohner, C., Mahmud, M., Yackel, J and Brady, M. (2019). Estimating melt onset over Arctic sea ice from multi-sensor Sentinel-1 and Radarsat-2 normalized gamma naught backscatter. Remote Sensing of Environment. 229, 48-59.

[8] Yackel, J., Geldsetzer, T., Mahmud, M., Nandan, V., Howell, S. E., Scharien, R. K., & Lam, H. M. (2019). Snow Thickness Estimation on First-Year Sea Ice from Late Winter Spaceborne Scatterometer Backscatter Variance. Remote Sensing, 11(4), 417.

[7] Mahmud, M., Geldsetzer, T., Howell, S. E., Yackel, J. J., Nandan, V., & Scharien, R. K. (2018). Incidence Angle Dependence of HH-Polarized C-and L-Band Wintertime Backscatter Over Arctic Sea Ice. IEEE Transactions on Geoscience and Remote Sensing, 56(11), 6686-6698.

[6] Yackel, J. J., Nandan, V., Mahmud, M., Scharien, R., Kang, J. W., & Geldsetzer, T. (2018). A spectral mixture analysis approach to quantify Arctic first-year sea ice melt pond fraction using QuickBird and MODIS reflectance data. Remote Sensing of Environment, 204, 704-716.

[5] Howell, S. E., Komarov, A. S., Dabboor, M., Montpetit, B., Brady, M., Scharien, R. K. Mahmud, M., ... & Yackel, J. J. (2018). Comparing L-and C-band synthetic aperture radar estimates of sea ice motion over different ice regimes. Remote Sensing of Environment, 204, 380-391.

[4] Nandan, V., Geldsetzer, T., Yackel, J., Mahmud, M., Scharien, R., Howell, S., ... & Else, B. (2017). Effect of snow salinity on CryoSat‐2 Arctic first‐year sea ice freeboard measurements. Geophysical Research Letters, 44(20).

[3] Mahmud, M., Howell, S. E., Geldsetzer, T., & Yackel, J. (2016). Detection of melt onset over the northern Canadian Arctic Archipelago sea ice from RADARSAT, 1997–2014. Remote Sensing of Environment, 178, 59-69.

[2] Al Jaber, S., Ghosh, A. K., & Mahmud, M. S. (2014). Using time series of satellite images to detect vegetation cover change in dhaka city. Journal of Geographic Information System, 6(06), 653.

[1] Mahmud, M. S., Masrur, A., Ishtiaque, A., Haider, F., & Habiba, U. (2011). Remote sensing & GIS based spatio-temporal change analysis of wetland in Dhaka city, Bangladesh. Journal of Water Resource and Protection, 3(11), 781.