Use the combined gas law --- it shows that for those conditions the temp must remain 100K (In an isotropic process.) How about in an adiabatic process? I can't seem to find an equation that solves an adiabatic process without information unknown in the scenario.
It depends on it's original temperature and how much it was heated.
Doubling the distance reduces the force of gravity to one quarter its original.
An experimental gas law is the Charles Law. The formula used is original volume/original temperature= new volume/new temperature. The law describes expansion of gases with heat.
Assuming the wire follows Ohm's Law, the resistance of a wire is directly proportional to its length therefore doubling the length will double the resistance of the wire. However when the length of the wire is doubled, its cross-sectional area is halved. ( I'm assuming the volume of the wire remains constant and of course that the wire is a cylinder.) As resistance is inversely proportional to the cross-sectional area, halving the area leads to doubling the resistance. The combined effect of doubling the length and halving the cross-sectional area is that the original resistance of the wire has been quadrupled.
The original source for diamonds is carbon. They are formed by reaction of the high temperature and pressure in the Earth's mantle on minerals containing carbon.
Doubled # = original# * 2^(times it doubles)
Compressing a voice signal sample into segments prior to quantization and expanding it it its original size once transmitted Compressing larger signals more than smaller signals
Compressing a voice signal sample into segments prior to quantization and expanding it it its original size once transmitted Compressing larger signals more than smaller signals
The number obtained by doubling a prime number: -- is an even number -- is a composite number -- has exactly four factors: 1, 2, the original prime number if different from 2, the new number
Denote the original area by A, denote the new area by A', denote the original circumference by C, and denote the new circumference by C'. C=2*pi*r so C'=2C=2*pi*(2r). So doubling the circumference corresponds to doubling the radius. A=pi*r2. A'/A=pi*(2r)2/[pi*r2]=4. So doubling the radius quadruples the area.
It depends on it's original temperature and how much it was heated.
Assuming the wire follows Ohm's Law, the resistance of a wire is directly proportional to its length therefore doubling the length will double the resistance of the wire. However when the length of the wire is doubled, its cross-sectional area is halved. ( I'm assuming the volume of the wire remains constant and of course that the wire is a cylinder.) As resistance is inversely proportional to the cross-sectional area, halving the area leads to doubling the resistance. The combined effect of doubling the length and halving the cross-sectional area is that the original resistance of the wire has been quadrupled.
Yes of Course it will!
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Doubling the distance reduces the force of gravity to one quarter its original.
Doubling the length of the sides of a square results in the area being quadrupled (four times the original area).
An experimental gas law is the Charles Law. The formula used is original volume/original temperature= new volume/new temperature. The law describes expansion of gases with heat.