Indian Institute of Technology Guwahati  

Department of Civil Engineering

 

 

 

Dr. Sreeja Pekkat
Associate Professor
Water Resources Engineering & Management

 
 sreeja@iitg.ac.in

91-361-2582408

 

 

 

 

 

 
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Journals

  1. Rattan, B., Shankar, M., Garg, A.,  Sahoo, L., Pekkat, S., and  Sreedeep, S. (2025). A field study integrating plant physiology-soil response for quantifying wilting and plant survival time in a polymer-amended soil. Soil and Tillage Research, 106371, Elsevier.

  2. Shejule, P. A., and S. Pekkat, (2024). Hybrid Model for Multistep-Ahead Rainfall Forecast in Northeast India: A Comparative Study. J. Hydrometeor., 25, 1221–1236, https://doi.org/10.1175/JHM-D-23-0173.1.

  3. Rahman, A., and Pekkat, S. (2024). Identifying and ranking of CMIP6‑global climate models for projected changes in temperature over Indian subcontinent. Scientific Reports, 14:3076. https://doi.org/10.1038/s41598-024-52275-1.

  4. Shejule, P. A., and S. Pekkat, (2024). Performance assessment of rainfall forecasting models for urban Guwahati City using machine learning techniques and singular spectrum analysis. Journal of Water and Climate Change, 15 (4), 1565, IWA Publishing, doi: 10.2166/wcc.2024.465.

  5. Naik, A. P., Norbu, T. and Pekkat, S. (2024). Comparison of flux-based and head-based methods for determination of near-surface saturated hydraulic conductivity. Hydrological Sciences Journal, DOI: 10.1080/02626667.2024.2305745.

  6. Suresh, A., and Pekkat, S. (2023). Importance of copula based bivariate rainfall intensity duration frequency curves for an urbanized catchment incorporating climate change. Journal of Hydrologic Engineering, 28 (7),  ASCE, https://doi.org/10.1061/JHYEFF.HEENG-5577

  7. Suresh, A., Pekkat, S., Subbiah, S. (2023). Quantifying the efficacy of Low Impact Developments (LIDs) for flood reduction in micro-urban watersheds incorporating climate change. Sustainable Cities and Society, 95, 104601.

  8. Naik, A. P., and Pekkat, S. (2023). An appraisal on the soil wetting water retention characteristic curve determined from mini disk infltrometer and sensor measurements. Acta Geophysica, 71:961-982, https://doi.org/10.1007/s11600-022-00932-2.

  9. Bora, M. J., Cai, W., Pekkat, S., Garg, A., and Sreedeep, S. (2023). Development of a simplified theoretical model to determine erodibility of compacted soil in hole erosion test based on fluid energy transformation. Acta Geotechnica, 18:5441-5455, https://doi.org/10.1007/s11440-023-01877-6.

  10. Shejule, P. A., and Pekkat, S. (2022). A systematic quantitative review on the performance of some of the recent short-term rainfall forecasting techniques. Journal of Water and Climate Change, IWA Publishing, https://doi.org/10.2166/wcc.2022.302.

  11. Naik, A. P., and Pekkat, S. (2022). Time Dependence of Hydraulic Parameters Estimation from Transient Analysis of Mini Disc Infiltrometer Measurements. European Journal of Soil Science, https://doi.org/10.1111/ejss.13228.

  12. Ghosh, B., AP Naik, and Pekkat, S. (2022). Rectangular Hyperbola Method for the Estimation of Soil Near Surface Hydraulic Conductivity Based on Short Term Infiltration Measurements. Eurasian Soil Science, 55 (12), 1761-1769.

  13. Bora, M., J., Bordoloi, S., Pekkat, S., Garg, A., and Sreedeep, S. and Rakesh, R., R. (2022). Assessment of soil erosion models for predicting soil loss in cracked vegetated compacted surface layer. Acta Geophysica, 70:333-347, https://doi.org/10.1007/s11600-021-00698-z.

  14. Cai, W., Bora, M.J., Pekkat, S., Bordoloi, S., Garg, A., and Sekharan, S. (2022). A new and simple model for predicting soil erosion based on hole erosion tests. Acta Geophysica, https://doi.org/10.1007/s11600-022-00904-6.

  15. Bora, M. J., Bordoloi, S., Kumar, H., Gogoi, N. Zhu, H-H, Sarmah, A. K., Pekkat, S., Sekharan, S., and Mei, G. (2021). Influence of biochar from animal and plant origin on the compressive strength characteristics of degraded landfill surface soils. International Journal of Damage Mechanics, 30 (4), 484-501, SAGE Journal, https://doi.org/10.1177/1056789520925524.

  16. Huang, S., Huang, D., Garg, A., Jiang, M., Mei, G., and Pekkat, S. (2020). Stormwater management of biochar-amended green roofs: Peak flow and hydraulic parameters using combined experimental and numerical investigation. Biomass Conversion and Biorefinery, https://doi.org/10.1007/s13399-020-01109-x.

  17. Cai, W., Bora, M. Pekkat, S. Bordoloi, S., Garg, A., and Sekharan, S. (2020). A novel analytical model for determining erosion from hole erosion tests. Authorea. DOI: 10.22541/au.159569155.55654761.

  18. Ghosh, B. and Sreeja P. (2019). Effect of Initial Compaction State on Near-Saturated Hydraulic Conductivity, Journal of Irrigation and Drainage Engineering, ASCE, 145 (12), 04019028.

  19. Ghosh, B. and Sreeja P. (2019). A critical evaluation of measurement induced variability in infiltration characteristics for a river sub-catchment, Measurement, Elsevier, 132, 47-59, DOI: 10.1016/j.measurement.2018.09.018.

  20. Ghosh, B. and Sreeja P. (2019). An Appraisal on the Interpolation Methods Used for Predicting Spatial Variability of Field Hydraulic Conductivity. Water Resources Management, Springer, 33 (6), 2175-2190.

  21. Ghosh, B. and Sreeja P. (2019). A critical evaluation of the variability induced by different mathematical equations on hydraulic conductivity determination using disc infiltrometer, Acta Geophysica, Springer, 67(3), 863-877.

  22. Ghosh, B., Sreeja P., and Yamsani, S. K. (2019). Evaluation of Infiltrometers and Permeameters for Measuring Hydraulic Conductivity. Advances in Civil Engineering Materials, ASTM, 8(1), https://doi.org/10.1520/ACEM20180056.

  23. Naik, A. P., Ghosh, B. and Sreeja P. (2019). Estimating soil hydraulic properties using mini disc infiltrometer. ISH Journal of Hydraulic Engineering, Taylor and Francis, 25 (1), 62-70.

  24. Sahoo, S. N. and Sreeja, P. (2018). Detention ponds for managing flood risk due to increased imperviousness: A case study in an urbanizing catchment of India. Natural Hazards Review, ASCE, 19(1): 05017008.

  25. Sahoo, S. N. and Sreeja, P. (2017). Sensitivity of imperviousness determination methodology on runoff prediction. ISH Journal of Hydraulic Engineering, Taylor and Francis, 23 (3), 276-282.

  26. Sahoo, S. N. and Sreeja, P. (2016). Relationship between peak rainfall intensity (PRI) and maximum flood depth (MFD) in an urban catchment of Northeast India. Natural Hazards, Springer, 83:1527-1544 DOI:10.1007/s11069-016-2374-1.

  27. Sahoo, S. N. and Sreeja, P. (2016). Determination of Effective Impervious Area for an Urban Indian Catchment. Journal of Hydrologic Engineering, ASCE, 05016004 (1-10).

  28. Sahoo, S. N. and Sreeja, P. (2015). Development of Flood Inundation Maps and Quantification of Flood Risk in an Urban Catchment of Brahmaputra River. Journal of Risk and Uncertainty in Engineering Systems, Part A: Civ. Eng., ASCE-ASME, A4015001(1-11).

  29. Sahoo, S. N. and Sreeja, P. (2014). Determination of urbanization based on imperviousness, Urban Design and Planning. ICE Publishing, Thomas Telford, 167 (2), 49-57.

  30. Sahoo, S. N. and Sreeja, P. (2014). A methodology for determining runoff based on imperviousness in an un-gauged peri-urban catchment. Urban Water Journal, Taylor and Francis, 11(1), 42-54.

  31. Sahoo, S. N. and Sreeja, P. (2013). A review of Decision Support System Application in Flood Management. International Journal of Hydrology Science and Technology, Inderscience Publication, 3 (3), 206-220.

  32. Sahoo, S. N. and Sreeja, P. (2013). Role of rainfall events and imperviousness parameters in urban runoff modeling.  ISH Journal of Hydraulic Engineering, Taylor and Francis, 19 (3), 329-334.

  33. Bhave, S. and Sreeja, P. (2013). Influence of initial soil condition on infiltration characteristics determined using a disk infiltrometer.  ISH Journal of Hydraulic Engineering, Taylor and Francis, 19 (3), 291-296.

  34. Chandan Kumar and Sreeja, P. (2013). Reply to Discussion on Evaluation of selected equations for predicting scour at downstream of ski-jump spillway using laboratory and field data. Engineering Geology, Elsevier Publication, 155, 96.

  35. Chandan Kumar and Sreeja, P. (2013). Reply to Discussion on "Evaluation of selected equations for predicting scour at downstream of ski-jump spillway using laboratory and field data". Engineering Geology, Elsevier Publication, 152, 212.

  36. Sahoo, S. N., and Sreeja, P. (2012). Application of Geospatial Technologies to Determine Imperviousness in Peri-Urban Areas. International Journal of Remote Sensing Applications, 2(4), 47-51.

  37. Chandan Kumar and Sreeja, P. (2012). Evaluation of selected equations for predicting scour at downstream of ski-jump spillway using laboratory and field data. Engineering Geology, Elsevier Publication, 129-130, 98-103.

  38. Sahoo, S. N. and Sreeja, P. (2011). Determination of infiltration parameters for urban flood modeling. Journal on Civil Engineering, imanager publications, India, 1 (3), 7-12.

  39. Sahoo, S. N. and Sreeja, P (2011). Total and Effective Impervious Area from low resolution satellite imageries.  International Journal of Earth Sciences and Engineering, 4 (6), 334-337.

  40. Sreeja, P. and Gupta, K. (2008). Transfer Function Formulation of Saint Venant' s Equations for Modeling Drainage Channel Flow : An Experimental Evaluation. Water Resources Management,  22 (12), 1881-1898.

  41. Sreeja, P. and Gupta, K. (2007). An Alternate Approach for Transient Flow Modeling in Urban Drainage Systems. Water Resources Management, Springer Publication, 21(7), 1225-1244.

  42. Sreeja, P. and Gupta, K. (2006). Modeling of Detention Tank-Gate System using Frequency and Time Domain Approach. ISH Journal of Hydraulic Engineering, 12(1), 110-120.

  43. Sreeja, P. and Gupta, K. (2006). Time and frequency domain approaches for dynamic modeling of detention tank systems. Journal of Applied Hydrology, XIX (4).

  44. Sreeja, P. and Jyothis Thomas (2006). Evaluation of Linear Perturbation Model for Rainfall-Runoff Transformation. Journal of Applied Hydrology, XIX (1-2), 46-58.

 

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