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Publications Citing Natural Hazards Data
List of peer-reviewed publications that cite using Natural Hazards data.
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| Title | Year Sort ascending | Author | Topic | Dataset |
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| Public Health Data Applications Using the CDC Tracking Network: | Amos, H. M., Skaff, N. K., Schollaert Uz, S., Policelli, F. S., Slayback, D., Macorps, E., Jo, M. J., Patel, K., Keller, C. A., Abue, P., Buchard, V., Werner, A. K. | Aerosols, Aerosol Extinction, Aerosol Optical Depth/Thickness, Angstrom Exponent, Aerosol Particle Properties, Carbonaceous Aerosols, Dust/Ash/Smoke, Organic Particles, Sulfate Particles, Sulfur Oxides, Sulfur Compounds, Sulfate, Sulfur Dioxide, Sulfur Oxides, Particulate Matter, Dimethyl Sulfide, Black Carbon, Sea Salt, PARTICULATE MATTER (PM 2.5), PARTICULATE MATTER (PM 1.0), PARTICULATE MATTER (PM 10), Geopotential Height, Altitude, Surface Temperature, Upper Air Temperature, Dew Point Temperature, Air Temperature, Cloud Top Temperature, Atmospheric Winds, Surface Winds, U/V Wind Components, Upper Level Winds, U/V Wind Components, Vertical Wind Velocity/Speed, Atmospheric Pressure, Sea Level Pressure, Cloud Top Pressure, Sea Level Pressure, Surface Pressure, Specific Humidity, Total Precipitable Water, Cloud Liquid Water/Ice, Atmospheric Water Vapor, Atmospheric Ozone, Oxygen Compounds, Boundary Layer Winds, Skin Temperature, Floods, Floods |
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| Protected areas are effective on curbing fires in the Amazon | Pessoa, Ana Carolina M., Morello R.S., Thiago F., Silva-Junior, Celso H.L., Doblas, Juan, Carvalho, Nathalia S., Aragao, Luiz E.O.C., Anderson, Liana O. | Fire Ecology, Biomass Burning, Wildfires, Fire Occurrence, Burned Area | ||
| Measuring Understory Fire Effects from Space: Canopy Change in Response | East, Alyson, Hansen, Andrew, Armenteras, Dolors, Jantz, Patrick, Roberts, David W. | Fire Ecology, Biomass Burning, Wildfires, Fire Occurrence, Burned Area, Lidar, Forest Composition/Vegetation Structure, Digital Elevation/Terrain Model (DEM), Canopy Characteristics | ||
| Sources of Formaldehyde in US Oil and Gas Production Regions | Dix, Barbara, Li, Meng, Roosenbrand, Esther, Francoeur, Colby, Brown, Steven S., Gilman, Jessica B., Hanisco, Thomas F., Keutsch, Frank, Koss, Abigail, Lerner, Brian M., Peischl, Jeff, Roberts, James M., Ryerson, Thomas B., St. Clair, Jason M., Veres, Patrick R., Warneke, Carsten, Wild, Robert J., Wolfe, Glenn M., Yuan, Bin, Veefkind, J. Pepijn, Levelt, Pieternel F., McDonald, Brian C., de Gouw, Joost | Gas Flaring, Heat, Methane | ||
| Simulating dynamic fire regime and vegetation change in a warming | Williams, Neil G., Lucash, Melissa S., Ouellette, Marc R., Brussel, Thomas, Gustafson, Eric J., Weiss, Shelby A., Sturtevant, Brian R., Schepaschenko, Dmitry G., Shvidenko, Anatoly Z. | Fire Dynamics, Normalized Difference Vegetation Index (NDVI), Albedo, Forests, Burned Area, Crown | ||
| Simulating spatio-temporal dynamics of surface PM2. 5 emitted from Alaskan wildfires | Chen, Dong, Billmire, Michael, Loughner, Christopher P., Bredder, Allison, French, Nancy H.F., Kim, Hyun Cheol, Loboda, Tatiana V. | Fire Occurrence, Fire Dynamics, Burned Area, PARTICULATE MATTER (PM 2.5), Emissions | ||
| Recent massive expansion of wildfire and its impact on active layer over pan-Arctic permafrost | Zhu, Xingru, Xu, Xiyan, Jia, Gensuo | Burned Area, Vegetation Species, Forests, Fire Occurrence, Soil Classification, Tree Rings, Soil Depth, Carbon, Vegetation Cover, Forest Fire Science, Soil Moisture/Water Content, Biomass, Emissions, Dominant Species, Biomass Burning, Surface Temperature, Precipitation Amount, Fire Dynamics, Topographic Effects | ||
| Regional ecological forecasting across scales: A manifesto for a | Slingsby, Jasper A., Wilson, Adam M., Maitner, Brian, Moncrieff, Glenn R. | Fire Ecology, Biomass Burning, Wildfires, Fire Occurrence, Burned Area, Vegetation Index, Normalized Difference Vegetation Index (NDVI), Enhanced Vegetation Index (EVI) | ||
| Remotely Sensed Agriculture Drought Indices for Assessing the Impact on | Khlif, Manel, Escorihuela, Maria Jose, Chahbi Bellakanji, Aicha, Paolini, Giovanni, Lili Chabaane, Zohra | Vegetation Index, Normalized Difference Vegetation Index (NDVI), Enhanced Vegetation Index (EVI), Fire Ecology, Biomass Burning, Wildfires, Fire Occurrence, Burned Area, Land Surface Temperature, Emissivity |
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| Reply to: Detecting long-term Arctic surface water changes | Webb, Elizabeth E., Liljedahl, Anna K., Loranty, Michael M., Witharana, Chandi, Lichstein, Jeremy W. | Fire Ecology, Biomass Burning, Wildfires, Fire Occurrence, Burned Area | ||
| The Drought Regime in Southern Africa: A Systematic Review | Chivangulula, Fernando Maliti, Amraoui, Malik, Pereira, Mario Gonzalez | Photosynthetically Active Radiation, Leaf Area Index (LAI), Leaf Characteristics, Fraction Of Absorbed Photosynthetically Active Radiation (fapar), Evapotranspiration, Latent Heat Flux, Land Use/Land Cover Classification, Fire Ecology, Biomass Burning, Wildfires, Fire Occurrence, Burned Area, Canopy Characteristics, Evergreen Vegetation, Crown, Deciduous Vegetation, Vegetation Cover, Surface Thermal Properties, Land Surface Temperature, THERMAL ANOMALIES, Photosynthesis, Primary Production, Emissivity, Reflectance |
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| The power of eDNA sampling to investigate the impact of Australian mega-fires on platypus occupancy | McColl-Gausden, Emily F., Griffiths, Josh, Collins, Luke, Weeks, Andrew R., Tingley, Reid | Fire Ecology, Biomass Burning, Wildfires, Fire Occurrence, Burned Area | ||
| The carbon transfer from plant to soil is more efficient in less productive ecosystems | Fan, Xianlei, Bai, Edith, Zhang, Jing, Wang, Xuhui, Yuan, Wenping, Piao, Shilong | Litter Characteristics, Droughts, Land Use/Land Cover, Biomass, Forests, Carbon | ||
| The savannization of tropical forests in mainland Southeast Asia since 2000 | Wang, Mengjie, Guo, Qinfeng, Chen, Anping | Fire Ecology, Biomass Burning, Wildfires, Fire Occurrence, Burned Area, Canopy Characteristics, Evergreen Vegetation, Crown, Deciduous Vegetation, Leaf Characteristics, Vegetation Cover, Land Use/Land Cover Classification |
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| Stakeholder perceptions of wildfire management strategies as nature-based solutions in two Iberian biosphere reserves | Lecina-Diaz, Judit, Campos, Joao, Pais, Silvana, Carvalho-Santos, Claudia, Azevedo, Joao, Fernandes, Paulo, Goncalves, Joao, Aquilue, Nuria, Roces-Diaz, Jose V., Agrelo de la Torre, Maria, Brotons, Lluis, Chas-Amil, Maria-Luisa, Lomba, Angela, Duane, Andrea, Moreira, Francisco, Touza, Julia, Hermoso, Virgilio, Sil, Angelo, Vicente, Joana, Honrado, Joao, Regos, Adrian | Burned Area, Fire Dynamics, Fire Occurrence | ||
| Summer Compound Drought-Heat Extremes Amplify Fire-Weather Risk and Burned Area beyond Historical Thresholds in Chongqing Region, Subtropical China | Gutierrez Rodriguez, Lucas, He, Yingpeng, Sun, Mengqi, Yao, Yinan, de Dios, Victor Resco | Fire Ecology, Biomass Burning, Wildfires, Fire Occurrence, Burned Area | ||
| Spatio-temporal variability of fire occurrence and recurrence in the | Silva, Amanda Cavalcante da, Juvanhol, Ronie Silva, Miranda, Jonathan da Rocha | Fire Ecology, Biomass Burning, Wildfires, Fire Occurrence, Burned Area | ||
| Using Landsat time series and bi-temporal GEDI to compare spectral and structural vegetation responses after fire | Huettermann, Sven, Jones, Simon, Soto-Berelov, Mariela, Hislop, Samuel | Fire Ecology, Biomass Burning, Wildfires, Fire Occurrence, Burned Area, Plant Phenology, Canopy Characteristics, Vegetation Cover, Lidar, Topography, Vegetation Height | ||
| Using machine learning algorithms to predict groundwater levels in Indonesian tropical peatlands | Hikouei, Iman Salehi, Eshleman, Keith N., Saharjo, Bambang Hero, Graham, Laura L.B., Applegate, Grahame, Cochrane, Mark A. | Wetlands, Forests, Burned Area, Fire Ecology | ||
| Urbanization decreases species richness, and increases abundance in dry climates whereas decreases in wet climates: A global meta-analysis | Szabo, Borbala, Koranyi, David, Galle, Robert, Lovei, Gabor L., Bakonyi, Gabor, Batary, Peter | Land Surface Temperature, Natural Hazards, Infrastructure, Sustainability, Land Use/Land Cover | ||
| Vegetation Fires and Entropy Variations in Myanmar | Vadrevu, Krishna Prasad, Salikineedi, Pranith, Eaturu, Aditya, Biswas, Sumalika | Fire Ecology, Biomass Burning, Wildfires, Fire Occurrence, Burned Area | ||
| Water-energy-vegetation nexus explain global geographical variation in surface urban heat island intensity | Liao, Jiayuan, Dai, Yongjiu, An, Le, Hang, Jian, Shi, Yurong, Zeng, Liyue | Land Surface Temperature, Natural Hazards, Infrastructure, Sustainability, Land Use/Land Cover | ||
| Underground trees inhabit varied environmental extremes across the Afrotropics | Courtenay, Anya P, Moonlight, Peter W, Toby Pennington, R, Lehmann, Caroline E R | Fire Ecology, Biomass Burning, Wildfires, Fire Occurrence, Burned Area | ||
| Unrecorded Tundra Fires of the Arctic Slope, Alaska USA | Miller, Eric A., Jones, Benjamin M., Baughman, Carson A., Jandt, Randi R., Jenkins, Jennifer L., Yokel, David A. | Fire Occurrence, Fire Dynamics, Burned Area, Vegetation Species, Land Use Classes, Terrain Elevation | ||
| Tree size diversity is the major driver of aboveground carbon storage in dryland agroforestry parklands | Noulekoun, Florent, Mensah, Sylvanus, Kim, HyungSub, Jo, Heejae, Gouwakinnou, Gerard N., Houehanou, Thierry D., Mensah, Michael, Naab, Jesse, Son, Yowhan, Khamzina, Asia | Fire Ecology, Biomass Burning, Wildfires, Fire Occurrence, Burned Area |