Yes, temperature and kinetic energy are always equal except when going through a phase change, during which temperature stays the same, potential energy increases, and bonds are made/broken.
In the case of gas, kinetic energy is equal to temperature unless condensing or depositing.
Solid, liquid, real gas, and ideal gas.
The two are in direct proportion.
kelvin
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Other things being equal, it is directly proportional to the temperature. It is also directly proportional to the amount of gas.Other things being equal, it is directly proportional to the temperature. It is also directly proportional to the amount of gas.Other things being equal, it is directly proportional to the temperature. It is also directly proportional to the amount of gas.Other things being equal, it is directly proportional to the temperature. It is also directly proportional to the amount of gas.
Density is inversely proportional to volume. If the same amount of stuff takes up a larger volume, it will have a lower density. 1 kg of air is slightly below one cubic meter, but 1 kg of water is about the size of your milk carton. As the temperature of an object increases, it's volume increases. This means that temperature is directly proportional to volume. Since temperature is directly proportional to volume, and volume is inversely proportional to density, thus density is inversely proportional to temperature. In the physical sense, you can visualize temperature as the energy (spacing) between particles and density as how much particles you can put in a box. As temperature goes up, the spacing of particles increase. Therefore, you cant put so much particles into the same sized box.
The following variables are directly proportional: Temperature and Pressure Temperature and Volume These variables are inversely proportional: Pressure and Volume
Directly proportional. As temperature goes up, so does resistance (hence supercomputers being cooled to such low temperatures).
Density is directly proportional to the specific heat.
Directly proportional, at pressure and temperature constant.
The temperature of a substance increases as the mean random kinetic energy of its particles increases. This is because temperature of an object is directly proportional to the kinetic energy of its particles. Thus when the particles move faster as a whole, such as when the object is put near a flame, the object heats up.
The temperature of a substance increases as the mean random kinetic energy of its particles increases. This is because temperature of an object is directly proportional to the kinetic energy of its particles. Thus when the particles move faster as a whole, such as when the object is put near a flame, the object heats up.
Other things being equal, it is directly proportional to the temperature. It is also directly proportional to the amount of gas.Other things being equal, it is directly proportional to the temperature. It is also directly proportional to the amount of gas.Other things being equal, it is directly proportional to the temperature. It is also directly proportional to the amount of gas.Other things being equal, it is directly proportional to the temperature. It is also directly proportional to the amount of gas.
This is the thermodinamic scale (Kelvin scale).
Temperature is only sometimes directly proportional to frequency. Temperature however is not always directly proportional to frequency in all cases.
Density is inversely proportional to volume. If the same amount of stuff takes up a larger volume, it will have a lower density. 1 kg of air is slightly below one cubic meter, but 1 kg of water is about the size of your milk carton. As the temperature of an object increases, it's volume increases. This means that temperature is directly proportional to volume. Since temperature is directly proportional to volume, and volume is inversely proportional to density, thus density is inversely proportional to temperature. In the physical sense, you can visualize temperature as the energy (spacing) between particles and density as how much particles you can put in a box. As temperature goes up, the spacing of particles increase. Therefore, you cant put so much particles into the same sized box.
Directly proportional-- If average KE increases, temperature increases, and vice versa.
it is directly proportional.
The following variables are directly proportional: Temperature and Pressure Temperature and Volume These variables are inversely proportional: Pressure and Volume
Directly proportional. As temperature goes up, so does resistance (hence supercomputers being cooled to such low temperatures).
rate of corossion is directly proportional to temperature