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How can one type of crystal adopt so many beautiful forms? Some of the world’s greatest scientific minds have puzzled over this question.
Geophysicists have a love-hate relationship with “the Ice Age.”
Analyses and numerical simulations were conducted on three recent nor’easters which formed on the East Coast of the United States to explore the effects of warmer-than-normal sea-surface temperatures.PDF Download
Two tropical cyclones were simulated with the NCAR WRF model to determine if warm sea-surface temperatures would cause them to intensify into hypercanes and follow similar storm tracks as the originPDF Download
A hypercyclone was simulated over the Arabian Sea to test enhanced precipitation over the Middle East and explain evidence for greater vegetation in the past.PDF Download
Because of the enormous explanatory and predictive success of the plate tectonics model, we feel that at least some portion of plate tectonics theory should be incorporated into the creation model.PDF Download
Based on the likely four-fold increase in precipitation rate and doubling of the frequency of storms following the Genesis Flood, glaciers over a kilometer thick would have developed in a few hundredPDF Download
Precipitation from two cold, winter orographic storms in Yosemite National Park and the Sierra Nevada was simulated with the NCAR mesoscale weather model called WRF.PDF Download
Based on the likely increase in precipitation rate and frequency of storms following the Genesis Flood, glaciers thousands of feet thick would have developed in a few hundred years.PDF Download
Oxygen isotopes in ice cores extracted from polar regions exhibit a decreasing trend in the ratio of the heavy to light isotopes from the beginning of the Ice Age to its end.
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