LibCat » Книги » Приключения » unrecognised » Global Drought and Flood

Global Drought and Flood

Здесь есть возможность читать онлайн «Global Drought and Flood» — ознакомительный отрывок электронной книги совершенно бесплатно, а после прочтения отрывка купить полную версию. В некоторых случаях можно слушать аудио, скачать через торрент в формате fb2 и присутствует краткое содержание. Жанр: unrecognised, на английском языке. Описание произведения, (предисловие) а так же отзывы посетителей доступны на портале библиотеки ЛибКат.

Читать книгу

Название:
Global Drought and Flood
Автор:
Неизвестный Автор
Жанр:
unrecognised / на английском языке
Год:
неизвестен
ISBN:
нет данных
Рейтинг книги:
5 / 5. Голосов: 1
Избранное:

Добавить в избранное
Отзывы:
Написать комментарий
Ваша оценка:
- 100
- 1
- 2
- 3
- 4
- 5

Global Drought and Flood: краткое содержание, описание и аннотация

Предлагаем к чтению аннотацию, описание, краткое содержание или предисловие (зависит от того, что написал сам автор книги «Global Drought and Flood»). Если вы не нашли необходимую информацию о книге — напишите в комментариях, мы постараемся отыскать её.

Recent advances in the modeling and remote sensing of droughts and floods Droughts and floods are causing increasing damage worldwide, often with devastating short- and long-term impacts on human society. Forecasting when they will occur, monitoring them as they develop, and learning from the past to improve disaster management is vital.
Global Drought and Flood: Observation, Modeling, and Prediction Volume highlights include:
Remote sensing approaches for mapping droughts and floods Physical and statistical models for monitoring and forecasting hydrologic hazards Features of various drought and flood systems and products Use by governments, humanitarian, and development stakeholders in recent disaster cases Improving the collaboration between hazard information provision and end users The American Geophysical Union promotes discovery in Earth and space science for the benefit of humanity. Its publications disseminate scientific knowledge and provide resources for researchers, students, and professionals.

Global Drought and Flood — читать онлайн ознакомительный отрывок

Ниже представлен текст книги, разбитый по страницам. Система сохранения места последней прочитанной страницы, позволяет с удобством читать онлайн бесплатно книгу «Global Drought and Flood», без необходимости каждый раз заново искать на чём Вы остановились. Поставьте закладку, и сможете в любой момент перейти на страницу, на которой закончили чтение.

Тёмная тема

Шрифт:

↓

↑

Сбросить

Интервал:

↓

↑

Закладка:

Сделать

146 Oguntunde, P.G., Abiodun, B.J., & Lischeid, G. (2011). Rainfall trends in Nigeria, 1901–2000. Journal of Hydrology, 411(3–4), 207–218. https://doi.org/10.1016/j.jhydrol.2011.09.037

147 Olagunju, T.E. (2015). Drought, desertification and the Nigerian environment: A review. Journal of Ecology and the Natural Environment, 7(7), 196–209.

148 Otkin, J.A., Anderson, M.C., Hain, C., Svoboda, M., Johnson, D., Mueller, R., et al. (2016). Assessing the evolution of soil moisture and vegetation conditions during the 2012 United States flash drought. Agricultural and Forest Meteorology, 218, 230–242.

149 Owe, M., deJeu, R., Walker, J., & Zukor, D.J. (2001). A methodology for surface soil moisture and vegetation optical depth retrieval using the microwave polarization difference index. IEEE Transactions on Geoscience and Remote Sensing, 39(8), 1643–1654.

150 Paneque, P. (2015). Drought management strategies in Spain. Water, 7(12), 6689–6701. https://doi.org/10.3390/w7126655

151 Park, S., Im, J., Park, S., & Rhee, J. (2017). Drought monitoring using high resolution soil moisture through multi‐sensor satellite data fusion over the Korean peninsula. Agricultural and Forest Meteorology, 237–238, 257–269. https://doi.org/10.1016/j.agrformet.2017.02.022

152 Pinzon, J.E., & Tucker, C.J. (2014). A non‐stationary 1981–2012 AVHRR NDVI3g time series. Remote Sensing, 6(8), 6929–6960.

153 Poumadere, M., Mays, C., Le Mer, S., & Blong, R. (2005). The 2003 heat wave in France: dangerous climate change here and now. Risk Analysis: An International Journal, 25(6), 1483–1494.

154 Raei, E., Nikoo, M.R., AghaKouchak, A., Mazdiyasni, O., & Sadegh, M., (2018). GHWR, a multi‐method global heatwave and warm‐spell record and toolbox. Nature Scientific Data, 5, 180206.

155 Rajsekhar, D., Singh, V. P., & Mishra, A. K. (2015). Multivariate drought index: An information theory based approach for integrated drought assessment. Journal of Hydrology, 526, 164–182. https://doi.org/10.1016/j.jhydrol.2014.11.031

156 Ramírez‐Beltrán, N. D., Salazar, C. M., Castro Sánchez, J. M., & González, J. E. (2019) A satellite algorithm for estimating relative humidity, based on GOES and MODIS satellite data. International Journal of Remote Sensing, 21, 1–23. https://doi.org/10.1080/01431161.2019.1629715

157 Rhee, J., Im, J., & Carbone, G.J. (2010b). Monitoring agricultural drought for arid and humid regions using multi‐sensor remote sensing data. Remote Sensing of Environment, 114(12), 2875–2887. https://doi.org/10.1016/j.rse.2010.07.005

158 Rind, D., Goldberg, R., Hansen, J., Rosenzweig, C., & Ruedy, R. (1990). Potential evapotranspiration and the likelihood of future drought. Journal of Geophysical Research: Atmospheres, 95(D7), 9983–10004.

159 Rodell, M., & Famiglietti, J.S. (2002). The potential for satellite‐based monitoring of groundwater storage changes using GRACE: the High Plains aquifer, Central US. Journal of Hydrology, 263(1–4), 245–256.

160 Rott, H., Yueh, S.H., Cline, D.W., Duguay, C., Essery, R., Haas, C., et al. (2010). Cold regions hydrology high‐resolution observatory for snow and cold land processes. Proceedings of the IEEE, 98(5), 752–765.

161 Rouse Jr, J., Haas, R.H., Schell, J.A., & Deering, D.W. (1974). Monitoring vegetation systems in the Great Plains with ERTS. Third Earth Resources Technology Satellite‐1 Symposium, Vol. I: Technical Presentations (NASA SP‐351, compiled and edited by S.C. Freden, E.P. Mercanti, M.A. Becker). Washington, DC: NASA

162 Ryu, J.H., Sohrabi, M., & Acharya, A. (2014). Toward mapping gridded drought indices to evaluate local drought in a rapidly changing global environment. Water Resources Management, 28(11), 3859–3869.

163 Sadegh, M., Love, C., Farahmand, A., Mehran, A., Tourian, M.J., & AghaKouchak, A. (2017). Multi‐sensor remote sensing of drought from space. In V. Lakshmi (Ed.), Remote Sensing of Hydrological Extremes (pp. 219–247). Springer.

164 Sadegh, M., Ragno, E., & AghaKouchak, A. (2017). Multivariate copula analysis toolbox (MvCAT): Describing dependence and underlying uncertainty using a Bayesian framework. Water Resources Research, 53(6), 5166–5183. https://doi.org/10.1002/2016WR020242

165 Sadegh, M., Moftakhari, H., Gupta, H.V, Ragno, E., Mazdiyasni, O., Sanders, B., et al. (2018). Multi‐hazard scenarios for analysis of compound extreme events. Geophysical Research Letters, 45(11), 5470–5480.

166 Sadri, S., Wood, E.F., & Pan, M. (2018). Developing a drought‐monitoring index for the contiguous US using SMAP. Hydrology and Earth System Sciences, 22(12), 6611–6626.

167 Sánchez, N., González‐Zamora, Á., Piles, M., & Martínez‐Fernández, J. (2016). A new Soil Moisture Agricultural Drought Index (SMADI) integrating MODIS and SMOS products: a case of study over the Iberian Peninsula. Remote Sensing, 8(4), 287.

168 Santi, E., Paloscia, S., Pettinato, S., Brocca, L., Ciabatta, L., & Entekhabi, D. (2018). Integration of microwave data from SMAP and AMSR2 for soil moisture monitoring in Italy. Remote Sensing of Environment, 212, 21–30.

169 Santos, J.F., Pulido‐Calvo, I., & Portela, M.M. (2010). Spatial and temporal variability of droughts in Portugal. Water Resources Research, 46(3). https://doi.org/10.1029/2009WR008071

170 Sapiano, M.R.P., & Arkin, P.A. (2009). An intercomparison and validation of high‐resolution satellite precipitation estimates with 3‐hourly gauge data. Journal of Hydrometeorology, 10(1), 149–166.

171 Save, H., Bettadpur, S., & Tapley, B. D. (2012). Reducing errors in the GRACE gravity solutions using regularization. Journal of Geodesy, 86(9), 695–711.

172 Scaini, A., Sánchez, N., Vicente‐Serrano, S. M., & Martínez‐Fernández, J. (2015). SMOS‐derived soil moisture anomalies and drought indices: A comparative analysis using in situ measurements. Hydrological Processes, 29(3), 373–383. https://doi.org/10.1002/hyp.10150

173 Scanlon, B.R., Longuevergne, L., & Long, D. (2012). Ground referencing GRACE satellite estimates of groundwater storage changes in the California Central Valley, USA. Water Resources Research, 48(4). https://doi.org/10.1029/2011WR011312

174 Seager, R., & Hoerling, M. (2014). Atmosphere and ocean origins of North American droughts. Journal of Climate, 27(12), 4581–4606.

175 Senay, G. B. (2008). Modeling landscape evapotranspiration by integrating land surface phenology and a water balance algorithm. Algorithms, 1(2), 52–68.

176 Shafer, B.A., & Dezman, L.E. (1982). Development of a Surface Water Supply Index (SWSI) to assess the severity of drought conditions in snow pack runoff areas. Western Snow Conference (pp. 164–175). Reno, NV: Colorado State University.

177 Sheffield, J., Goteti, G., Wen, F., & Wood, E.F. (2004). A simulated soil moisture based drought analysis for the United States. Journal of Geophysical Research: Atmospheres, 109(D24). https://doi.org/10.1029/2004JD005182

178 Sherwood, S.C., Ingram, W., Tsushima, Y., Satoh, M., Roberts, M., Vidale, P.L., & O’Gorman, P.A. (2010). Relative humidity changes in a warmer climate. Journal of Geophysical Research: Atmospheres, 115(D9). https://doi.org/10.1029/2009JD012585

179 Shiferaw, B., Tesfaye, K., Kassie, M., Abate, T., Prasanna, B. M., & Menkir, A. (2014). Managing vulnerability to drought and enhancing livelihood resilience in sub‐Saharan Africa: Technological, institutional and policy options. Weather and Climate Extremes, 3, 67–79.

180 Shojaeezadeh, S.A., Nikoo, M.R., McNamara, J.P., AghaKouchak, A., & Sadegh, M. (2018). Stochastic modeling of suspended sediment load in alluvial rivers. Advances in Water Resources, 119, 188–196.

181 Shojaeezadeh, S.A., Nikoo, M.R., Mirchi, A., Mallakpour, I., AghaKouchak, A., & Sadegh, M. (2019). Probabilistic hazard assessment of contaminated sediment in rivers. Science of The Total Environment, 703, 134875.