Land Use/Land Cover Change With Impact On Land Surface Temperature: A Case Study Of Mkda Planning Area, West Bengal, India

The type of surface influences the temperature of a surface. If it is made of concrete or another hard material, the temperature will be higher. Hence it is essential to study the land surface temperature (LST) of urban areas. The LST is an important parameter in the estimation of radiation budgets and heat balance and is a controlling factor of dynamic climate changes. In this work, we made an effort to identify the LST of the Midnapore Kharagpur Development Authority planning region. Multi-temporal images acquired by Landsat 7 ETM+, Landsat 5 TM and Landsat 8 using OLI sensors on 3 May 2001, 7 May 2011 and 29 May 2019, respectively, were corrected for radiometric and geometric errors and processed to extract LULC classes and LST. Thermal remote sensing can be used to monitor the temperature and local climate of urban areas. This study has shown that the temperature varies across the surface according to land use. It was found that the urbanized area increased from 6.79% (40.39 sq. km) to 11.6% (69.2 sq. km) between 2001 and 2011 and from 11.6% (69.2 sq. km) to 17.22 % (102.79 sq. km) between 2011 and 2019. The LST study has shown that there has been a tremendous change in the spatial pattern of the temperature between 2001 and 2019. Whereas in 2001 the highest temperature did not exceed 34°C, by 2019 it had increased by nearly 8°C, reaching 41.29°C. So, the findings of this study are significant.

1. Ahmad A. and Quegan S. (2016). Analysis of Maximum Likelihood Classification on Multispectral Data, (January 2012).

2. Alavipanah S.K. et al. (2007). Land Surface Temperature in the Yardang Region of Lut Desert (Iran) Based on Field Measurements and Landsat Thermal Data, Journal Agriculture Science Technology, 9, 287-303.

3. Amiri R. et al. (2009). Spatial-temporal dynamics of land surface temperature in relation to fractional vegetation cover and land use/ cover in the Tabriz urban area, Iran, Remote Sensing of Environment. Elsevier Inc., 113(12), 2606-2617, DOI: 10.1016/j.rse.2009.07.021.

4. Anandababu D., Purushothaman B. M. and Dr. S. Suresh Babu (2018). Estimation of Land Surface Temperature using LANDSAT 8 Data, INTERNATIONAL JOURNAL OF ADVANCE RESEARCH, IDEAS AND INNOVATIONS IN TECHNOLOGY, 4(2), 177-186.

5. Baba I.I. (2016). ESTIMATION OF LAND SURFACE TEMPERATURE OF KADUNA METROPOLIS, NIGERIA USING LANDSAT IMAGES, 11(3), 36-42.

6. Bokaie M. et al. (2016). Assessment of Urban Heat Island based on the relationship between land surface temperature and Land Use/ Land Cover in Tehran, Sustainable Cities and Society. Elsevier B.V., 23, 94-104, DOI: 10.1016/j.scs.2016.03.009.

7. Buyadi S.N.A., Mohd W.M.N.W. and Misni A. (2013). Impact of Land Use Changes on the Surface Temperature Distribution of Area Surrounding the National Botanic Garden, Shah Alam, Procedia – Social and Behavioral Sciences. Elsevier B.V., 101, 516-525, DOI: 10.1016/j.sbspro.2013.07.225.

8. Chen S.P., Zeng S. and Xie C.G. (2000). Remote sensing and GIS for urban growth analysis in China, Photogrammetric Engineering and Remote Sensing, 66(5), 593-598, DOI: 10.1007/978-94-007-4698-5.

9. Congalton R.G. (1991). A Review of Assessing the Accuracy of Classifications of Remotely Sensed Data, 46 (October 1990), 35-46.

10. Congalton R.G. (1991). A Review of Assessing the Accuracy of Classifications of Remotely Sensed Data, 46(October 1990), 35-46.

11. Fatema S. and Chakrabarty A. (2020). Accident Hotspot Identification on the Midnapore Kharagpur Development Authority Planning Area, (2), 169-174, DOI: 10.35940/ijrte.B3351.079220.

12. Fu P. and Weng Q. (2016). A time series analysis of urbanization induced land use and land cover change and its impact on land surface temperature with Landsat imagery, Remote Sensing of Environment. Elsevier Inc., 175, 205-214, DOI: 10.1016/j.rse.2015.12.040.

13. Ghulam A. and Louis S. (2010). Calculating surface temperature using Landsat thermal imagery, 1-9.

14. Guha S., Govil H. and Diwan P. (2020). Monitoring LST-NDVI Relationship Using Premonsoon Landsat Datasets, 2020(1).

15. Hussain M. et al. (2013). ISPRS Journal of Photogrammetry and Remote Sensing Change detection from remotely sensed images: From pixel-based to object-based approaches, ISPRS Journal of Photogrammetry and Remote Sensing. International Society for Photogrammetry and Remote Sensing, Inc. (ISPRS), 80, 91-106, DOI: 10.1016/j.isprsjprs.2013.03.006.

16. James M.M. and Mundia C.N. (2014). Dynamism of land use changes on surface temperature in Kenya: a case study of Nairobi City. International Journal of Science and Research, 3(4), 38-41.

17. Jiang J. and Tian G. (2010). Analysis of the impact of Land use/Land cover change on Land Surface Temperature with Remote Sensing, Procedia Environmental Sciences, 2(5), 571-575, DOI: 10.1016/j.proenv.2010.10.062.

18. Kayet N. et al. (2016). Spatial impact of land use / land cover change on surface temperature distribution in Saranda Forest, Jharkhand, Modeling Earth Systems and Environment. Springer International Publishing, 2(3), 1-10, DOI: 10.1007/s40808-016-0159-x.

19. Kustas W. and Anderson M. (2009). Agricultural and Forest Meteorology Advances in thermal infrared remote sensing for land surface modeling, 149, 2071-2081, DOI: 10.1016/j.agrformet.2009.05.016.

20. Latif S. (2014). Land Surface Temperature Retrival of Landsat-8 Data Using Split Window Algorithm – A Case Study of Ranchi District, 2(4), 3840-3849.

21. Li S. and Jiang G.M. (2018). Land Surface Temperature Retrieval from Landsat-8 Data with the Generalized Split-Window Algorithm, IEEE Access. IEEE, 6, 18149-18162, DOI: 10.1109/ACCESS.2018.2818741.

22. Lillesand T., Kiefer R.W. and Chipman J. (2015). Remote sensing and image interpretation. John Wiley & Sons.

23. Lv Z. Q. and Zhou Q.G. (2011). Utility of Landsat image in the study of land cover and land surface temperature change, Procedia Environmental Sciences, 10(PART B), 1287-1292, DOI: 10.1016/j.proenv.2011.09.206.

24. Mallick J., Kant Y. and Bharath B.D. (2008). Estimation of land surface temperature over Delhi using Landsat-7 ETM +, (August).

25. Nguyen Q.K., et al. (2019). Land Surface Temperature Dynamics In Dry Season 2015-2016 According To Landsat 8 Data In The South-East Region of Vietnam, Geography, Environment, Sustainability, 12(1), 75-87, DOI: 10.24057/2071-9388-2018-06.

26. Renssen H., et al. (2005). Simulating the Holocene climate evolution at northern high latitudes using a coupled atmosphere-sea iceocean-vegetation model, 23-43, DOI: 10.1007/s00382-004-0485-y.

27. Reuter D.C., et al. (2015). The thermal infrared sensor (tirs) on landsat 8: Design overview and pre-launch characterization, Remote Sensing, 7(1), 1135-1153, DOI: 10.3390/rs70101135.

28. Rozenstein O., et al. (2014). Derivation of Land Surface Temperature for Landsat-8 TIRS Using a Split Window Algorithm, 5768-5780, DOI: 10.3390/s140405768.

29. Saradjian M.R. and Jouybari-Moghaddam Y. (2019). Land Surface Emissivity and temperature retrieval from Landsat-8 satellite data using Support Vector Regression and weighted least squares approach, Remote Sensing Letters. Taylor & Francis, 10(5), 439-448, DOI: 10.1080/2150704X.2019.1569273.

30. Satiprasad S. (2013). Monitoring urban Land use land cover change by Multi-Temporal remote sensing information in Howrah city, India, International Research Journal of Earth Sciences, 1(5), 1-6.

31. Southworth J. (2010). An assessment of Landsat TM band 6 thermal data for analysing land cover in tropical dry forest regions, 1161, DOI: 10.1080/0143116031000139917.

32. USGS (2001). Landsat 7 Science Data Users handbooks.

33. Wan Z. and Li Z. L. (2010). Radiance – based validation of the V5 MODIS land – surface temperature product, 1161, DOI: 10.1080/01431160802036565.

34. White-Newsome J.L., et al. (2013). Measurements: A Public Health Perspective, 121(8), 925-931.