Supercomputer simulations predict how E. coli adapts to environmental stresses.
Toolkit lets scientists detect extreme weather in climate simulations far faster than before.
High-performance computing reveals the relationship between DNA and phosphorous uptake.
Tiny cages can trap and release inert argon gas atoms, allowing their further study and providing a new way to capture rare gases.
For the first time, scientists modeled the spontaneous bifurcation of turbulence to high-confinement mode, solving a 35-year-old mystery.
Calculations of a subatomic particle called the sigma provide insight into the communication between subatomic particles deep inside the heart of matter.
Water table depth and groundwater flow are vital to understanding the amount of water that plants transmit to the atmosphere.
Researchers simulate the design of new quantum bits for easier engineering of quantum computers.
Research uncovers the errors that prevent modeled precipitation variations from matching real-world results.
New approach could benefit applications as diverse as propeller and printers.
First atomically thin, halide perovskite sheets could be an alternative to graphene for future electronics.
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