Agricultural Management Options for Climate Variability and Change: Microirrigation by Lincoln Zotarelli, Clyde Fraisse, Daniel Dourte

“…HS1203/HS1203: Agricultural Management Options for Climate Variability and Change: Microirrigation (ufl.edu) …”
Get full text

Agricultural Management Options for Climate Variability and Change: AgroClimate by Clyde Fraisse

Get full text

Agricultural Management Options for Climate Variability and Change: Conservation Tillage by Kip Balkcom, Leah Duzy, Daniel Dourte, Clyde Fraisse

“…This 4-page fact sheet focuses on the use of conservation tillage in crop production systems as a strategy to minimize the risks associated with climate variability and change and to improve resource-use efficiency. …”
Get full text

Using Seasonal Climate Variability Forecasts: Crop Yield Risk by Clyde W. Fraisse, Joel O. Paz, Charles M. Brown

Get full text

Agricultural Management Options for Climate Variability and Change: AgroClimate by Clyde Fraisse

Get full text

Agricultural Management Options for Climate Variability and Change: Variable-Rate Irrigation by Calvin Perry, Clyde Fraisse, Daniel Dourte

Get full text

Agricultural Management Options for Climate Variability and Change: Sod-Based Rotation by David Wright, Jim Marois, Clyde Fraisse, Daniel Dourte

Get full text

Using Seasonal Climate Variability Forecasts to Plan Forest Plantation Establishment by Norman Breuer, Matthew Langholtz, David Zierden, Clyde Fraisse

Get full text

Agricultural Management Options for Climate Variability and Change: Sod-Based Rotation by David Wright, Jim Marois, Clyde Fraisse, Daniel Dourte

Get full text

Changes in the relationship between climate variables and vegetation carbon uptake in East Asia by Min-Seok Shin, Sang-Wook Yeh, Hak-Jun Lee, Chang-Eui Park

“…To understand the carbon cycle in East Asia in the context of rising CO2, we analyzed a land carbon cycle dataset (TRENDY) from 1982 to 2020, examining the relationship between vegetation carbon uptake and two climate variables (i.e. precipitation and surface temperature) during the vegetation growing season (March to September). …”
Get full text

Natural Climate Variability Can Influence Cyanobacteria Blooms in Florida Lakes and Reservoirs by Karl E. Havens, Mark V. Hoyer, Edward J. Phlips

“…SGEF-234/SG142: Natural Climate Variability Can Influence Cyanobacteria Blooms in Florida Lakes and Reservoirs (ufl.edu) …”
Get full text

Agricultural Management Options for Climate Variability and Change: High-Residue Cover Crops by Joel Love, Jed Dillard, Kirk Brock, Daniel Dourte, Clyde Fraisse

Get full text

Using Seasonal Climate Variability Forecasts: Risk Management for Tomato Production in South Florida by Norman Breuer, Phyllis Gilreath, Gene McAvoy, David Letson, Clyde Fraisse

“…The third part discusses economic and risk management implications of seasonal climate variability for tomato producers and extensionists looking at a broader context in South Florida. …”
Get full text

The Moderating Influence of Spring Climate on the Rio Grande Headwaters: A Paleo Perspective by C. A. Woodhouse, W. L. Tintor

Subjects: “…climate variability…”
Get full text

Agricultural Management Options for Climate Variability and Change: Sensor-Based, Variable-Rate Nitrogen Management by Wesley Porter, Ahmad Khalilian, Daniel Dourte, Clyde Fraisse

Get full text

Minimal Arctic Sea Ice Loss in the Last 20 Years, Consistent With Internal Climate Variability by M. R. England, L. M. Polvani, J. Screen, A. C. Chan

Subjects: Get full text

Variabilité spatio-temporelle des séquences sèches en France depuis 1950 by Florian Raymond, Albin Ullmann

Subjects: Get full text

Height‐Latitude Patterns of Interannual Climate Variability in the Upper Mesosphere and Lower Thermosphere During Spring and Autumn Months by Liang Zhang, Zhongfang Liu, Brian Tinsley

Get full text

Climaterna: A decade of daily data on births, deaths, pollution and climate variables for all municipalities in BrazilREDU by Cristiano Torezzan, Camila Ferreira Soares, Breno Bernard Nicolau de França, Priscila Pereira Coltri, Everton Emanuel Campos de Lima, Alexandre Cândido Xavier, Jaqueline Nichi, Charles M'poca Charles, Negli René Gallardo-Alvarado, Sergio Floquet, Gabriel Moreira Motta, Matheus Alves de Andrade, Mateus Samuel Risso, Malcolm dos Reis Alves Pereira, Guilherme Almussa Leite Torres, Kevin Hyslop, Dimitri de Oliveira Silva, Oluwafunmilola Deborah Awe, Caio Simplicio Arantes, Valter Lacerda de Andrade Júnior, Rodolfo de Carvalho Pacagnella

Get full text

Spatiotemporal Change in Climate Variables and Resources of Wind， Solar Radiation and Precipitation in Qinghai Province from 1961 to 2021 by Meixia DUAN, Miaoni GAO, Han JIANG, Runhong XU, buda SU, Tong JIANG

“…In order to evaluate the potential of wind， solar radiation and precipitation in guaranteeing the development of clean energy comprehensively， this study analyzed the temporal and spatial changes in climate variables and resources of wind speed， solar radiation and precipitation in Qinghai Province throughout the year and four seasons from 1961 to 2021 based on the observation data of daily 10-meter-height wind speed， sunshine duration and precipitation at 51 meteorological stations.The results are as follows： （1） The annual average wind speed， solar radiation and precipitation in Qinghai Province are 2.67 m·s-1， 6084.2 MJ·m-2， and 299.7 mm， respectively.Wind speed tends to be higher in the western regions and lower in the east， which exceeds 3 m/s and reaches the standard for wind energy resource development in western Qinghai.The annual solar radiation in the entire Province exceeds 5040 MJ·m-2， and reaches the "very rich" level according to China Solar energy GB Standards.The solar radiation of Qaidam Basin is at its highest abundance level， which is ideal for solar energy resource development.Precipitation generally decreases from southeast to northwest.The resources of wind， solar radiation， and precipitation in Qinghai Province exhibits seasonal complementarity， characterized by a pattern of “strong winds， good sunlight， and less water in spring， whereas weak winds， good sunlight， and abundant water in summer”.（2） Under climate change， the annual average wind speed and total solar radiation in Qinghai Province show a significant decrease at rates of 0.16 m·s-1·10a-1and 29.04 MJ·m-2·（10a）-1， respectively.The western and central parts of Haixi are most affected by these changes， but the wind speed and solar radiation still remain within the acceptable range for wind energy and photovoltaic resource development.Meanwhile， precipitation increases significantly at a rate of 8.85 mm·（10a）-1， with the largest increase observed in western Yushu， eastern Haixi and northern Guoluo.The most significant decrease in wind speed is observed in spring， while summer solar radiation decreases at the fastest rate but with a substantial increase in precipitation.The changes in solar radiation and precipitation could be ascribed to the increased cloud cover in this region.（3） The changes in the areas where wind speed and solar radiation meet suitable development standards in Qinghai Province are not significant with reduced variabilities， which could ensure the stable development of clean energy.Wind energy resources in western Qinghai （such as Tanggula Mountains）， solar energy resources in the Qaidam Basin， and water energy resources in the three major river basins of the Yangtze River， Yellow River， and Lancang River have great potential for development.Overall， the results provide a theoretical foundation for the development of a balanced clean energy system encompassing wind， solar and hydropower.This contributes to achieving national "dual carbon" goals and enhancing the high-quality development of Qinghai Province.…”
Get full text