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Campbell JB, Wynne RH. Introduction to Remote Sensing [Internet]. New York: Guilford Press; 2011. Available from: https://ebookcentral-proquest-com.ezproxy01.rhul.ac.uk/lib/rhul/detail.action?docID=843851
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Campbell JB, Wynne RH. Introduction to Remote Sensing [Internet]. 5th ed. New York: Guilford Press; 2011. Available from: https://ebookcentral.proquest.com/lib/rhul/detail.action?docID=843851
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Jensen JR. Remote Sensing of the Environment: An Earth Resource Perspective. Second edition. Vol. Always learning. Harlow: Pearson Education Limited; 2014.
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Jensen JR. Remote Sensing of the Environment: An Earth Resource Perspective [Internet]. Second edition. Vol. Pearson Custom Library. Harlow, Essex, England: Pearson Education Limited; 2014. Available from: https://www-dawsonera-com.ezproxy01.rhul.ac.uk/abstract/9781292034935
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Campbell JB, Wynne RH. Electromagnetic Radiation. In: Introduction to Remote Sensing [Internet]. New York: Guilford Press; 2011. Available from: https://ebookcentral.proquest.com/lib/rhul/reader.action?docID=843851&ppg=64
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Observing The Biosphere From Space [720p] | YouTube [Internet]. Available from: https://www.youtube.com/watch?v=Hn_ffF_KvIU
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NASA | Earth Observing Landsat 5 Turns 25 Years Old | YouTube [Internet]. Available from: https://www.youtube.com/watch?v=ArLvDtsewn0
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Campbell JB, Wynne RH. Plant Sciences. In: Introduction to Remote Sensing [Internet]. New York: Guilford Press; 2011. Available from: https://ebookcentral.proquest.com/lib/rhul/reader.action?docID=843851&ppg=498
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Jonathan A. Foley, Ruth DeFries, Gregory P. Asner, Carol Barford, Gordon Bonan, Stephen R. Carpenter, F. Stuart Chapin, Michael T. Coe, Gretchen C. Daily, Holly K. Gibbs, Joseph H. Helkowski, Tracey Holloway, Erica A. Howard, Christopher J. Kucharik, Chad Monfreda, Jonathan A. Patz, I. Colin Prentice, Navin Ramankutty and Peter K. Snyder. Global Consequences of Land Use. Science [Internet]. 2005;309(5734):570–4. Available from: http://www.jstor.org/stable/3842335?seq=1#page_scan_tab_contents
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Hansen MC, Loveland TR. A Review of Large Area Monitoring of Land Cover Change Using Landsat Data. Remote Sensing of Environment. 2012;122:66–74.
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Hansen MC, Potapov PV, Moore R, Hancher M, Turubanova SA, Tyukavina A, et al. High-Resolution Global Maps of 21st-Century Forest Cover Change. Science. 2013 Nov 15;342(6160):850–3.
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McKinna LIW. Three Decades of Ocean-Color Remote-Sensing Trichodesmium Spp. in the World’s Oceans: A Review. Progress in Oceanography. 2015;131:177–99.
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Baccini A, Goetz SJ, Walker WS, Laporte NT, Sun M, Sulla-Menashe D, et al. Estimated Carbon Dioxide Emissions From Tropical Deforestation Improved by Carbon-Density Maps. Nature Climate Change. 2012;2(3):182–5.
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Ruth S. DeFries, Richard A. Houghton, Matthew C. Hansen, Christopher B. Field, David Skole and John Townshend. Carbon Emissions from Tropical Deforestation and Regrowth Based on Satellite Observations for the 1980s and 1990s. Proceedings of the National Academy of Sciences of the United States of America [Internet]. 2002;99(22):14256–61. Available from: http://www.jstor.org/stable/3073573
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Hansen MC, Roy DP, Lindquist E, Adusei B, Justice CO, Altstatt A. A Method for Integrating MODIS And Landsat Data for Systematic Monitoring of Forest Cover and Change in the Congo Basin. Remote Sensing of Environment. 2008;112(5):2495–513.
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Kratzer S, Therese Harvey E, Philipson P. The Use of Ocean Color Remote Sensing in Integrated Coastal Zone Management—a Case Study From Himmerfjärden, Sweden. Marine Policy. 2014;43:29–39.
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Ramankutty N, Evan AT, Monfreda C, Foley JA. Farming the Planet: 1. Geographic Distribution of Global Agricultural Lands in the Year 2000. Global Biogeochemical Cycles. 2008;22(1).
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Sterling S, Ducharne A. Comprehensive Data Set of Global Land Cover Change for Land Surface Model Applications. Global Biogeochemical Cycles. 2008;22(3):n/a-n/a.
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Gao J, Liu Y. Applications of Remote Sensing, GIS and GPS in Glaciology: A Review. Progress in Physical Geography. 2001;25(4):520–40.
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Linde J, Grab S. The Changing Trajectory of Snow Mapping. Progress in Physical Geography. 2011;35(2):139–60.
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On the Accuracy of Glacier Outlines Derived From Remote-Sensing Data. Annals of Glaciology [Internet]. 2013;54(63):171–82. Available from: http://www.zora.uzh.ch/83965/
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Paul F, Bolch T. The Glaciers Climate Change Initiative: Methods for Creating Glacier Area, Elevation Change and Velocity Products. Remote Sensing of Environment. 2015;162:408–26.
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Quincey DJ, Lucas RM, Richardson SD, Glasser NF, Hambrey MJ, Reynolds JM. Optical Remote Sensing Techniques in High-Mountain Environments: Application to Glacial Hazards. Progress in Physical Geography. 2005;29(4):475–505.
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Challenges and Recommendations in Mapping of Glacier Parameters From Space: Results of the 2008 Global Land Ice Measurements From Space (GLIMS) Workshop, Boulder, Colorado, USA. Annals of Glaciology [Internet]. 2009;50(53):53–69. Available from: http://www.zora.uzh.ch/29212/
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Andreassen LM, Paul F, Kääb A, Hausberg JE. Landsat-Derived Glacier Inventory for Jotunheimen, Norway, and Deduced Glacier Changes Since the 1930s. The Cryosphere. 2008;2(2):131–45.
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Bolch T, Menounos B, Wheate R. Landsat-Based Inventory of Glaciers in Western Canada, 1985–2005. Remote Sensing of Environment. 2010;114(1):127–37.
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De Angelis H, Rau F, Skvarca P. Snow Zonation on Hielo Patagónico Sur, Southern Patagonia, Derived From Landsat 5 Tm Data. Global and Planetary Change. 2007;59(1–4):149–58.
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McMillan M, Shepherd A, Sundal A, Briggs K, Muir A, Ridout A, et al. Increased Ice Losses From Antarctica Detected by CryoSat-2. Geophysical Research Letters. 2014;41(11):3899–905.
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Raup B, Kääb A, Khalsa SJS, Beedle M, Helm C. Remote Sensing and GIS Technology in the Global Land Ice Measurements from Space (GLIMS) Project. Computers & Geosciences. 2007;33(1):104–25.
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Rignot E, Bamber JL, van den Broeke MR, Davis C, Li Y, van de Berg WJ, et al. Recent Antarctic Ice Mass Loss From Radar Interferometry and Regional Climate Modelling. Nature Geoscience. 2008;1(2):106–10.
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Campbell JB, Wynne RH, MyiLibrary. Hydrospheric Sciences. In: Introduction to Remote Sensing [Internet]. New York: Guilford Press; 2011. Available from: https://ebookcentral.proquest.com/lib/rhul/reader.action?docID=843851&ppg=582
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Fingas M, Brown C. Review of Oil Spill Remote Sensing. Marine Pollution Bulletin. 2014;83(1):9–23.
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Gawarkiewicz GG, Todd RE, Plueddemann AJ, Andres M, Manning JP. Direct Interaction Between the Gulf Stream and the Shelfbreak South of New England. Scientific Reports. 2012;2.
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Karim F, Dutta D, Marvanek S, Petheram C, Ticehurst C, Lerat J, et al. Assessing the Impacts of Climate Change and Dams on Floodplain Inundation and Wetland Connectivity in the Wet–dry Tropics of Northern Australia. Journal of Hydrology. 2015;522:80–94.
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Klemas V, Yan XH. Subsurface and Deeper Ocean Remote Sensing From Satellites: An Overview and New Results. Progress in Oceanography. 2014;122:1–9.
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Kozlov I, Dailidienė I, Korosov A, Klemas V, Mingėlaitė T. MODIS-Based Sea Surface Temperature of the Baltic Sea Curonian Lagoon. Journal of Marine Systems. 2014;129:157–65.
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Mouw CB, Greb S, Aurin D, DiGiacomo PM, Lee Z, Twardowski M, et al. Aquatic Color Radiometry Remote Sensing of Coastal and Inland Waters: Challenges and Recommendations for Future Satellite Missions. Remote Sensing of Environment. 2015;160:15–30.
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Ogilvie A, Belaud G, Delenne C, Bailly JS, Bader JC, Oleksiak A, et al. Decadal Monitoring of the Niger Inner Delta Flood Dynamics Using MODIS Optical Data. Journal of Hydrology. 2015;523:368–83.
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Palmer SCJ, Kutser T, Hunter PD. Remote Sensing of Inland Waters: Challenges, Progress and Future Directions. Remote Sensing of Environment. 2015;157:1–8.
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Reinart A, Reinhold M. Mapping Surface Temperature in Large Lakes With MODIS Data. Remote Sensing of Environment. 2008;112(2):603–11.
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Campbell JB, Wynne RH. Introduction to Remote Sensing [Internet]. 5th ed. New York: Guilford Press; 2011. Available from: https://ebookcentral.proquest.com/lib/rhul/detail.action?docID=843851
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Campbell JB, Wynne RH. Introduction to Remote Sensing [Internet]. New York: Guilford Press; 2011. Available from: https://ebookcentral.proquest.com/lib/rhul/detail.action?docID=843851
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Direct Acquisition of Data: Airborne Laser Scanning [Internet]. Available from: http://geomorphology.org.uk/sites/default/files/geom_tech_chapters/2.1.4_LiDAR.pdf
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Crapoulet A, Héquette A, Marin D, Levoy F, Bretel P. Variations in the Response of the Dune Coast of Northern France to Major Storms as a Function of Available Beach Sediment Volume. Earth Surface Processes and Landforms. 2017;42(11):1603–22.
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Goodwin NR, Armston JD, Muir J, Stiller I. Monitoring Gully Change: A Comparison of Airborne and Terrestrial Laser Scanning Using a Case Study From Aratula, Queensland. Geomorphology. 2017;282:195–208.
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Mäkinen J, Kajuutti K, Palmu JP, Ojala A, Ahokangas E. Triangular-Shaped Landforms Reveal Subglacial Drainage Routes in Sw Finland. Quaternary Science Reviews. 2017;164:37–53.
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Nelson A, Dubé K. Channel Response to an Extreme Flood and Sediment Pulse in a Mixed Bedrock and Gravel-Bed River. Earth Surface Processes and Landforms. 2016;41(2):178–95.
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Obu J, Lantuit H, Grosse G, Günther F, Sachs T, Helm V, et al. Coastal Erosion and Mass Wasting Along the Canadian Beaufort Sea Based on Annual Airborne LiDAR Elevation Data. Geomorphology. 2017;293:331–46.
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Robb C, Willis I, Arnold N, Guðmundsson S. A Semi-Automated Method for Mapping Glacial Geomorphology Tested at Breiðamerkurjökull, Iceland. Remote Sensing of Environment. 2015;163:80–90.
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Abalharth M, Hassan MA, Klinkenberg B, Leung V, McCleary R. Using LiDAR to Characterize Logjams in Lowland Rivers. Geomorphology. 2015;246:531–41.
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Breckenridge A. The Tintah-Campbell Gap and Implications for Glacial Lake Agassiz Drainage During the Younger Dryas Cold Interval. Quaternary Science Reviews. 2015;117:124–34.
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Bull JM, Miller H, Gravley DM, Costello D, Hikuroa DCH, Dix JK. Assessing Debris Flows Using LIDAR Differencing: 18 May 2005 Matata Event, New Zealand. Geomorphology. 2010;124(1–2):75–84.
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Croke J, Todd P, Thompson C, Watson F, Denham R, Khanal G. The Use of Multi Temporal LiDAR to Assess Basin-Scale Erosion and Deposition Following the Catastrophic January 2011 Lockyer Flood, SE Queensland, Australia. Geomorphology. 2013;184:111–26.
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De Rose RC, Basher LR. Measurement of River Bank and Cliff Erosion From Sequential LIDAR and Historical Aerial Photography. Geomorphology. 2011;126(1–2):132–47.
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Dowlinga TPF. Morphometry and Core Type of Streamlined Bedforms in Southern Sweden From High Resolution LiDAR. Morphometry and Core Type of Streamlined Bedforms in Southern Sweden From High Resolution LiDAR [Internet]. 236:54–63. Available from: http://www.sciencedirect.com/science/article/pii/S0169555X15001014
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Lin Z, Kaneda H, Mukoyama S, Asada N, Chiba T. Detection of Subtle Tectonic–geomorphic Features in Densely Forested Mountains by Very High-Resolution Airborne LiDAR Survey. Geomorphology. 2013;182:104–15.
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Benjamin H. Mackey, Joshua J. Roering and Michael P. Lamb. Proceedings of the National Academy of Sciences of the United States of America. 2011;108(47):18905–9. Available from: http://www.jstor.org/stable/23058621
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Pedersen A, Kocurek G, Mohrig D, Smith V. Dune Deformation in a Multi-Directional Wind Regime: White Sands Dune Field, New Mexico. Earth Surface Processes and Landforms. 2015;40(7):925–41.
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Reddya AD, Hawbakerb TJ, Wursterc F, Zhua Z, Wardd S, Newcombd D, et al. Quantifying Soil Carbon Loss and Uncertainty From a Peatland Wildfire Using Multi-Temporal LiDAR. Quantifying soil carbon loss and uncertainty from a peatland wildfire using multi-temporal LiDAR [Internet]. 170:306–16. Available from: http://www.sciencedirect.com/science/article/pii/S0034425715301401
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Richter A, Faust D, Maas HG. Dune Cliff Erosion and Beach Width Change at the Northern and Southern Spits of Sylt Detected With Multi-Temporal Lidar. CATENA. 2013 Apr;103:103–11.
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