Forwarded from Phys.Org
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➖@Phys_Org➖
Atomic motion captured in 4-D for the first time
Everyday transitions from one state of matter to another—such as freezing, melting or evaporation—start with a process called "nucleation," in which tiny clusters of atoms or molecules (called "nuclei") begin to coalesce. Nucleation plays a critical role in circumstances as diverse as the formation of clouds and the onset of neurodegenerative disease.
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➖@Phys_Org➖
➖@Phys_Org➖
Atomic motion captured in 4-D for the first time
Everyday transitions from one state of matter to another—such as freezing, melting or evaporation—start with a process called "nucleation," in which tiny clusters of atoms or molecules (called "nuclei") begin to coalesce. Nucleation plays a critical role in circumstances as diverse as the formation of clouds and the onset of neurodegenerative disease.
Powered by Physics and Affiliates®
➖@Phys_Org➖
phys.org
Atomic motion captured in 4-D for the first time
Everyday transitions from one state of matter to another—such as freezing, melting or evaporation—start with a process called "nucleation," in which tiny clusters of atoms or molecules (called "nuclei") ...
Forwarded from Phys.Org
#NanoTechNEWS
➖@Phys_Org➖
A new way to make droplets bounce away
In many situations, engineers want to minimize the contact of droplets of water or other liquids with surfaces they fall onto. Whether the goal is keeping ice from building up on an airplane wing or a wind turbine blade, or preventing heat loss from a surface during rainfall, or preventing salt buildup on surfaces exposed to ocean spray, making droplets bounce away as fast as possible and minimizing the amount of contact with the surface can be key to keeping systems functioning properly.
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➖@Phys_Org➖
➖@Phys_Org➖
A new way to make droplets bounce away
In many situations, engineers want to minimize the contact of droplets of water or other liquids with surfaces they fall onto. Whether the goal is keeping ice from building up on an airplane wing or a wind turbine blade, or preventing heat loss from a surface during rainfall, or preventing salt buildup on surfaces exposed to ocean spray, making droplets bounce away as fast as possible and minimizing the amount of contact with the surface can be key to keeping systems functioning properly.
Powered by Physics and Affiliates®
➖@Phys_Org➖
phys.org
A new way to make droplets bounce away
In many situations, engineers want to minimize the contact of droplets of water or other liquids with surfaces they fall onto. Whether the goal is keeping ice from building up on an airplane wing or a ...
Forwarded from Phys.Org
#NanoTechNEWS
➖@Phys_Org➖
Physicists OK commercial graphene for T-wave detection
Russian researchers from the Moscow Institute of Physics and Technology (MIPT) and Valiev Institute of Physics and Technology have demonstrated resonant absorption of terahertz radiation in commercially available graphene. This is an important step toward designing efficient terahertz detectors to enable faster internet and a safe replacement for X-ray body scans. The research findings were published in Physical Review Applied.
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➖@Phys_Org➖
➖@Phys_Org➖
Physicists OK commercial graphene for T-wave detection
Russian researchers from the Moscow Institute of Physics and Technology (MIPT) and Valiev Institute of Physics and Technology have demonstrated resonant absorption of terahertz radiation in commercially available graphene. This is an important step toward designing efficient terahertz detectors to enable faster internet and a safe replacement for X-ray body scans. The research findings were published in Physical Review Applied.
Powered by Physics and Affiliates®
➖@Phys_Org➖
phys.org
Physicists OK commercial graphene for T-wave detection
Russian researchers from the Moscow Institute of Physics and Technology (MIPT) and Valiev Institute of Physics and Technology have demonstrated resonant absorption of terahertz radiation in commercially ...
Forwarded from Phys.Org
#NanoTechNEWS
➖@Phys_Org➖
New technique lets researchers make thousands of nanowires, capable of recording intracellular signals, at the same time
Machines are getting cozy with our cells. Embeddable sensors record how and when neurons fire; electrodes spark heart cells to beat or brain cells to fire; neuron-like devices could even encourage faster regrowth after implantation in the brain.
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➖@Phys_Org➖
➖@Phys_Org➖
New technique lets researchers make thousands of nanowires, capable of recording intracellular signals, at the same time
Machines are getting cozy with our cells. Embeddable sensors record how and when neurons fire; electrodes spark heart cells to beat or brain cells to fire; neuron-like devices could even encourage faster regrowth after implantation in the brain.
Powered by Physics and Affiliates®
➖@Phys_Org➖
phys.org
New technique lets researchers make thousands of nanowires, capable of recording intracellular signals, at the same time
Machines are getting cozy with our cells. Embeddable sensors record how and when neurons fire; electrodes spark heart cells to beat or brain cells to fire; neuron-like devices could even encourage faster ...
#NanoTechNEWS
#Magnetism
➖@Phytimes➖
New shortcut enables faster creation of spin pattern in magnet
Physicists have discovered a much faster approach to create a pattern of spins in a magnet. This shortcut opens a new chapter in topology research. This discovery also offers an additional method to achieve more efficient magnetic data storage. The research will be published on 5 October in Nature Materials.
➖@Phytimes➖
#Magnetism
➖@Phytimes➖
New shortcut enables faster creation of spin pattern in magnet
Physicists have discovered a much faster approach to create a pattern of spins in a magnet. This shortcut opens a new chapter in topology research. This discovery also offers an additional method to achieve more efficient magnetic data storage. The research will be published on 5 October in Nature Materials.
➖@Phytimes➖
phys.org
New shortcut enables faster creation of spin pattern in magnet
Physicists have discovered a much faster approach to create a pattern of spins in a magnet. This shortcut opens a new chapter in topology research. This discovery also offers an additional method to achieve ...