«Warmer, wetter climate could mean stronger, more intense storms: High - resolution climate simulations suggest that extreme convective systems will increase in
frequency under a warmer climate scenario.»
Her results suggest that extreme thunderstorms, or what atmospheric scientists call convective systems, will increase in frequency
under a warmer climate scenario.
The model simulations including this additional feedback still showed a similar percentage increase of hurricane intensity
under warm climate conditions as the original model without ocean coupling.
This discovery will help improve the prediction of future ice outflow from Antarctica the future fate of the ice
sheet under a warming climate is clearly tied dynamically to changes of the floating ice shelves.
But Cohen and his colleagues found the increases in outbreaks were driven instead by storm relative helicity, which has not been projected to
increase under a warming climate.
These predictions are limited by a poor understanding of the recent changes observed in the Antarctic and Greenland ice sheets, and a lack of knowledge about the variability of ice sheet
behaviour under a warming climate.
It is of interest to scientists because it is changing rapidly; it is thinning, accelerating and receding3, all of which contribute directly to sea level, and its
future under a warming climate is uncertain.
Possible future changes in cyclonic storms in the Bay of Bengal,
India under warmer climate The aim of this paper is to study the model's simulated frequency, track, intensity and location of cyclonic storms (CSs) and severe cyclonic storms (SCSs) in the Bay of Bengal (BoB), India.
The US CLIVAR Hurricane Working Group was formed to improve understanding of interannual variability and trends in the tropical cyclone activity from the beginning of the 20th century to the present and quantify changes in the characteristics of tropical
cyclones under a warming climate.
This severe, widespread bleaching and mortality will undoubtedly have long - term consequences for reef ecosystems and suggests a troubled future for tropical marine
ecosystems under a warming climate.
We conclude that runnel ponds represent a source of methane from potentially older C, and that they contain methanogenic communities able to use diverse sources of carbon, increasing the risk of augmented methane
release under a warmer climate.
«The intention here is to save some of the last remaining bull trout populations and create new ones that will
survive under a warming climate,» says Clint Muhlfeld, a research ecologist with the U.S. Geological Survey.
This isotope signal needs careful calibration and Louise Sime and colleagues make the point that
under warm climate conditions such as the Eemian the calibration developed for cold climate conditions might be different — in fact isotopes during warm periods might be less sensitive to temperature, and so applying the cold - climate calibration might underestimate actual temperatures.
Her results suggest that extreme thunderstorms, or what atmospheric scientists call convective systems, will increase in
frequency under a warmer climate scenario.
This means that,
under a warming climate, Beijing is likely to see more haze events, and when they do occur, they'll last longer.
The methanogenic community included genera capable of both AM and HM, indicating that methanogens could potentially use different carbon substrates and thus acclimate to changing conditions, for example vegetation cover or hydrology,
under a warmer climate.