23.2.21.2 Land Surface Temperature using LandSat

Vlassova, L.[Lidia], Perez-Cabello, F.[Fernando], Nieto, H.[Hector], Martín, P.[Pilar], Riaño, D.[David], de la Riva, J.[Juan],
Assessment of Methods for Land Surface Temperature Retrieval from Landsat-5 TM Images Applicable to Multiscale Tree-Grass Ecosystem Modeling,
RS(6), No. 5, 2014, pp. 4345-4368.
DOI Link 1407
BibRef

Yu, X.L.[Xiao-Lei], Guo, X.L.[Xu-Lin], Wu, Z.C.[Zhao-Cong],
Land Surface Temperature Retrieval from Landsat 8 TIRS: Comparison between Radiative Transfer Equation-Based Method, Split Window Algorithm and Single Channel Method,
RS(6), No. 10, 2014, pp. 9829-9852.
DOI Link 1411
BibRef

Cook, M.[Monica], Schott, J.R.[John R.], Mandel, J.[John], Raqueno, N.[Nina],
Development of an Operational Calibration Methodology for the Landsat Thermal Data Archive and Initial Testing of the Atmospheric Compensation Component of a Land Surface Temperature (LST) Product from the Archive,
RS(6), No. 11, 2014, pp. 11244-11266.
DOI Link 1412
BibRef

Malakar, N.K., Hulley, G.C., Hook, S.J., Laraby, K., Cook, M., Schott, J.R.,
An Operational Land Surface Temperature Product for Landsat Thermal Data: Methodology and Validation,
GeoRS(56), No. 10, October 2018, pp. 5717-5735.
IEEE DOI 1810
Earth, Artificial satellites, Remote sensing, Land surface temperature, Temperature sensors, Ocean temperature, satellites BibRef

Ren, H.Z.[Hua-Zhong], Du, C.[Chen], Liu, R.Y.[Rong-Yuan], Qin, Q.M.[Qi-Ming], Meng, J.J.[Jin-Jie], Li, Z.L.[Zhao-Liang], Yan, G.J.[Guang-Jian],
Evaluation of Radiometric Performance for the Thermal Infrared Sensor Onboard Landsat 8,
RS(6), No. 12, 2014, pp. 12776-12788.
DOI Link 1412
BibRef

Du, C.[Chen], Ren, H.Z.[Hua-Zhong], Qin, Q.M.[Qi-Ming], Meng, J.J.[Jin-Jie], Zhao, S.H.[Shao-Hua],
A Practical Split-Window Algorithm for Estimating Land Surface Temperature from Landsat 8 Data,
RS(7), No. 1, 2015, pp. 647-665.
DOI Link 1502
BibRef

Meng, X.C.[Xiang-Chen], Cheng, J.[Jie], Zhao, S.H.[Shao-Hua], Liu, S.[Sihan], Yao, Y.J.[Yun-Jun],
Estimating Land Surface Temperature from Landsat-8 Data using the NOAA JPSS Enterprise Algorithm,
RS(11), No. 2, 2019, pp. xx-yy.
DOI Link 1902
BibRef

Jin, M.J.[Mei-Jun], Li, J.M.[Jun-Ming], Wang, C.L.[Cai-Li], Shang, R.L.[Rui-Lan],
A Practical Split-Window Algorithm for Retrieving Land Surface Temperature from Landsat-8 Data and a Case Study of an Urban Area in China,
RS(7), No. 4, 2015, pp. 4371-4390.
DOI Link 1505
BibRef

Wang, F.[Fei], Qin, Z.H.[Zhi-Hao], Song, C.Y.[Cai-Ying], Tu, L.L.[Li-Li], Karnieli, A.[Arnon], Zhao, S.[Shuhe],
An Improved Mono-Window Algorithm for Land Surface Temperature Retrieval from Landsat 8 Thermal Infrared Sensor Data,
RS(7), No. 4, 2015, pp. 4268-4289.
DOI Link 1505
BibRef

Wang, S.H.[Song-Han], He, L.H.[Long-Hua], Hu, W.S.[Wu-Sheng],
A Temperature and Emissivity Separation Algorithm for Landsat-8 Thermal Infrared Sensor Data,
RS(7), No. 8, 2015, pp. 9904.
DOI Link 1509
BibRef

Emami, H., Safari, A., Mojaradi, B.,
Fusion Methods for Land Surface Emissivity and Temperature Retrieval of the Landsat Data Continuity Mission Data,
GeoRS(54), No. 7, July 2016, pp. 3842-3855.
IEEE DOI 1606
Earth BibRef

Ndossi, M.I.[Milton Isaya], Avdan, U.[Ugur],
Application of Open Source Coding Technologies in the Production of Land Surface Temperature (LST) Maps from Landsat: A PyQGIS Plugin,
RS(8), No. 5, 2016, pp. 413.
DOI Link 1606
BibRef

Mechri, R.[Rihab], Ottlé, C.[Catherine], Pannekoucke, O.[Olivier], Kallel, A.[Abdelaziz], Maignan, F.[Fabienne], Courault, D.[Dominique], Trigo, I.F.[Isabel F.],
Downscaling Meteosat Land Surface Temperature over a Heterogeneous Landscape Using a Data Assimilation Approach,
RS(8), No. 7, 2016, pp. 586.
DOI Link 1608
BibRef

Tardy, B.[Benjamin], Rivalland, V.[Vincent], Huc, M.[Mireille], Hagolle, O.[Olivier], Marcq, S.[Sebastien], Boulet, G.[Gilles],
A Software Tool for Atmospheric Correction and Surface Temperature Estimation of Landsat Infrared Thermal Data,
RS(8), No. 9, 2016, pp. 696.
DOI Link 1610
BibRef

Simó, G.[Gemma], García-Santos, V.[Vicente], Jiménez, M.A.[Maria A.], Martínez-Villagrasa, D.[Daniel], Picos, R.[Rodrigo], Caselles, V.[Vicente], Cuxart, J.[Joan],
Landsat and Local Land Surface Temperatures in a Heterogeneous Terrain Compared to MODIS Values,
RS(8), No. 10, 2016, pp. 849.
DOI Link 1609
BibRef

Rosas, J.[Jorge], Houborg, R.[Rasmus], McCabe, M.F.[Matthew F.],
Sensitivity of Landsat 8 Surface Temperature Estimates to Atmospheric Profile Data: A Study Using MODTRAN in Dryland Irrigated Systems,
RS(9), No. 10, 2017, pp. xx-yy.
DOI Link 1711
BibRef

Ling, F.[Feng], Foody, G.M.[Giles M.], Du, H.[Hao], Ban, X.[Xuan], Li, X.D.[Xiao-Dong], Zhang, Y.H.[Yi-Hang], Du, Y.[Yun],
Monitoring Thermal Pollution in Rivers Downstream of Dams with Landsat ETM+ Thermal Infrared Images,
RS(9), No. 11, 2017, pp. xx-yy.
DOI Link 1712
BibRef

Parastatidis, D.[David], Mitraka, Z.[Zina], Chrysoulakis, N.[Nektrarios], Abrams, M.[Michael],
Online Global Land Surface Temperature Estimation from Landsat,
RS(9), No. 12, 2017, pp. xx-yy.
DOI Link 1802
BibRef

Cristóbal, J.[Jordi], Jiménez-Muñoz, J.C.[Juan C.], Prakash, A.[Anupma], Mattar, C.[Cristian], Skokovic, D.[Dražen], Sobrino, J.A.[José A.],
An Improved Single-Channel Method to Retrieve Land Surface Temperature from the Landsat-8 Thermal Band,
RS(10), No. 3, 2018, pp. xx-yy.
DOI Link 1804
BibRef

García-Santos, V.[Vicente], Cuxart, J.[Joan], Martínez-Villagrasa, D.[Daniel], Jiménez, M.A.[Maria Antònia], Simó, G.[Gemma],
Comparison of Three Methods for Estimating Land Surface Temperature from Landsat 8-TIRS Sensor Data,
RS(10), No. 9, 2018, pp. xx-yy.
DOI Link 1810
BibRef

Nill, L.[Leon], Ullmann, T.[Tobias], Kneisel, C.[Christof], Sobiech-Wolf, J.[Jennifer], Baumhauer, R.[Roland],
Assessing Spatiotemporal Variations of Landsat Land Surface Temperature and Multispectral Indices in the Arctic Mackenzie Delta Region between 1985 and 2018,
RS(11), No. 19, 2019, pp. xx-yy.
DOI Link 1910
BibRef

Gerace, A.[Aaron], Kleynhans, T.[Tania], Eon, R.[Rehman], Montanaro, M.[Matthew],
Towards an Operational, Split Window-Derived Surface Temperature Product for the Thermal Infrared Sensors Onboard Landsat 8 and 9,
RS(12), No. 2, 2020, pp. xx-yy.
DOI Link 2001
BibRef

Sekertekin, A.[Aliihsan], Bonafoni, S.[Stefania],
Land Surface Temperature Retrieval from Landsat 5, 7, and 8 over Rural Areas: Assessment of Different Retrieval Algorithms and Emissivity Models and Toolbox Implementation,
RS(12), No. 2, 2020, pp. xx-yy.
DOI Link 2001
BibRef

Miller, J.[Jonathan], Gerace, A.[Aaron], Eon, R.[Rehman], Montanaro, M.[Matthew], Kremens, R.[Robert], Wehle, J.[Jarrett],
Low-Cost Radiometer for Landsat Land Surface Temperature Validation,
RS(12), No. 3, 2020, pp. xx-yy.
DOI Link 2002
BibRef

Zhang, X., Jiao, Z., Dong, Y., He, T., Ding, A., Yin, S., Zhang, H., Cui, L., Chang, Y., Guo, J., Xie, R.,
Development of the Direct-Estimation Albedo Algorithm for Snow-Free Landsat TM Albedo Retrievals Using Field Flux Measurements,
GeoRS(58), No. 3, March 2020, pp. 1550-1567.
IEEE DOI 2003
Remote sensing, MODIS, Earth, Artificial satellites, Table lookup, Land surface, Sensors, Accuracy assessment, two-step correction strategy BibRef

Guo, J.X.[Jin-Xin], Ren, H.Z.[Hua-Zhong], Zheng, Y.T.[Yi-Tong], Lu, S.Z.[Shang-Zong], Dong, J.J.[Jia-Ji],
Evaluation of Land Surface Temperature Retrieval from Landsat 8/TIRS Images before and after Stray Light Correction Using the SURFRAD Dataset,
RS(12), No. 6, 2020, pp. xx-yy.
DOI Link 2003
BibRef

Ermida, S.L.[Sofia L.], Soares, P.[Patrícia], Mantas, V.[Vasco], Göttsche, F.M.[Frank-M.], Trigo, I.F.[Isabel F.],
Google Earth Engine Open-Source Code for Land Surface Temperature Estimation from the Landsat Series,
RS(12), No. 9, 2020, pp. xx-yy.
DOI Link 2005
BibRef

Vanhellemont, Q.[Quinten],
Combined land surface emissivity and temperature estimation from Landsat 8 OLI and TIRS,
PandRS(166), 2020, pp. 390-402.
Elsevier DOI 2007
Emissivity, Surface temperature, Atmospheric correction, Thermal infrared, Landsat 8, TIRS, OLI, Neural network BibRef

Sekertekin, A.[Aliihsan], Bonafoni, S.[Stefania],
Sensitivity Analysis and Validation of Daytime and Nighttime Land Surface Temperature Retrievals from Landsat 8 Using Different Algorithms and Emissivity Models,
RS(12), No. 17, 2020, pp. xx-yy.
DOI Link 2009
BibRef

Chen, M.[Maosi], Sun, Z.B.[Zhi-Bin], Newell, B.H.[Benjamin H.], Corr, C.A.[Chelsea A.], Gao, W.[Wei],
Missing Pixel Reconstruction on Landsat 8 Analysis Ready Data Land Surface Temperature Image Patches Using Source-Augmented Partial Convolution,
RS(12), No. 19, 2020, pp. xx-yy.
DOI Link 2010
BibRef

Dang, T.[Thanhtung], Yue, P.[Peng], Bachofer, F.[Felix], Wang, M.[Michael], Zhang, M.D.[Ming-Da],
Monitoring Land Surface Temperature Change with Landsat Images during Dry Seasons in Bac Binh, Vietnam,
RS(12), No. 24, 2020, pp. xx-yy.
DOI Link 2012
BibRef

Niclòs, R.[Raquel], Puchades, J.[Jesús], Coll, C.[César], Barberà, M.J.[María J.], Pérez-Planells, L.[Lluís], Valiente, J.A.[José A.], Sánchez, J.M.[Juan M.],
Evaluation of Landsat-8 TIRS data recalibrations and land surface temperature split-window algorithms over a homogeneous crop area with different phenological land covers,
PandRS(174), 2021, pp. 237-253.
Elsevier DOI 2103
Landsat-8 TIRS, Calibration, LST algorithms, Validation, In-situ measurements, Thermal-infrared BibRef

García, D.H.[David Hidalgo], Díaz, J.A.[Julián Arco],
Spatial and Multi-Temporal Analysis of Land Surface Temperature through Landsat 8 Images: Comparison of Algorithms in a Highly Polluted City (Granada),
RS(13), No. 5, 2021, pp. xx-yy.
DOI Link 2103
BibRef

Yang, Y.C.[Yi-Chen], Lee, X.[Xuhui],
A Scale-Separating Framework for Fusing Satellite Land Surface Temperature Products,
RS(14), No. 4, 2022, pp. xx-yy.
DOI Link 2202
BibRef

Galve, J.M.[Joan M.], Sánchez, J.M.[Juan M.], García-Santos, V.[Vicente], González-Piqueras, J.[José], Calera, A.[Alfonso], Villodre, J.[Julio],
Assessment of Land Surface Temperature Estimates from Landsat 8-TIRS in A High-Contrast Semiarid Agroecosystem. Algorithms Intercomparison,
RS(14), No. 8, 2022, pp. xx-yy.
DOI Link 2205
BibRef

Aliabad, F.A.[Fahime Arabi], Shojaei, S.[Saeed], Mortaz, M.[Morad], Ferreira, C.S.S.[Carla Sofia Santos], Kalantari, Z.[Zahra],
Use of Landsat 8 and UAV Images to Assess Changes in Temperature and Evapotranspiration by Economic Trees following Foliar Spraying with Light-Reflecting Compounds,
RS(14), No. 23, 2022, pp. xx-yy.
DOI Link 2212
BibRef

Eon, R.[Rehman], Gerace, A.[Aaron], Falcon, L.[Lucy], Poole, E.[Ethan], Kleynhans, T.[Tania], Raqueño, N.[Nina], Bauch, T.[Timothy],
Validation of Landsat-9 and Landsat-8 Surface Temperature and Reflectance during the Underfly Event,
RS(15), No. 13, 2023, pp. 3370.
DOI Link 2307
BibRef

Song, L.J.[Li-Juan], Wu, Y.F.[Yi-Fan], Gong, J.X.[Jia-Xing], Fan, P.[Pei], Zheng, X.[Xiaopo], Zhao, X.[Xi],
Improvement of Ice Surface Temperature Retrieval by Integrating Landsat 8/TIRS and Operation IceBridge Observations,
RS(15), No. 18, 2023, pp. 4577.
DOI Link 2310
BibRef

Quan, J.L.[Jin-Ling], Guan, Y.J.[Yong-Juan], Zhan, W.F.[Wen-Feng], Ma, T.[Ting], Wang, D.D.[Dan-Dan], Guo, Z.[Zheng],
Generating 60-100 m, hourly, all-weather land surface temperatures based on the Landsat, ECOSTRESS, and reanalysis temperature combination (LERC),
PandRS(205), 2023, pp. 115-134.
Elsevier DOI 2311
Land surface temperature, All-weather reconstruction, Annual temperature cycle, Diurnal dynamics, Fine resolution BibRef

Bektas Balcik, F., Ergene, E.M.,
Determining The Impacts Of Land Cover/use Categories On Land Surface Temperature Using Landsat8-oli,
ISPRS16(B8: 251-256).
DOI Link 1610
BibRef

Orhan, O., Yakar, M.,
Investigating Land Surface Temperature Changes Using Landsat Data in Konya, Turkey,
ISPRS16(B8: 285-289).
DOI Link 1610
BibRef

Cook, M.J., Schott, J.R.,
The Atmospheric Compensation Component of a Landsat Land Surface Temperature (LST) Product: Assessment of Errors Expected for a North American Test Product,
LandImaging14(73-79).
DOI Link 1411
BibRef

Chapter on Remote Sensing General Issue, Land Use, Land Cover continues in
Land Surface Temperature using MODIS .