When the temperature is increased, the resistivity of a material typically also increases. This is because at higher temperatures, the thermal vibrations of the atoms in the material increase, leading to more collisions with free electrons, which in turn increase resistance.
If the temperature of a gas increases, its particles will gain more kinetic energy and move faster. This will cause the gas to expand and exert more pressure on its surroundings.
If the volume is constant, an increase in temperature will result in an increase in pressure, according to the ideal gas law (PV = nRT). This is because the molecules will have higher kinetic energy and will collide with the container walls more frequently and with greater force.
Diffusion happens faster at higher temperatures because increased thermal energy causes particles to move more rapidly. As temperature rises, the kinetic energy of the molecules increases, leading to more frequent and forceful collisions between them. This heightened activity facilitates the mixing of substances, allowing them to spread more quickly throughout a medium. Consequently, the overall rate of diffusion accelerates with rising temperature.
If the average movement of particles in a sweater increases, this typically indicates that the sweater's temperature is rising. Increased particle movement corresponds to higher thermal energy, which translates to a higher temperature. Consequently, as the particles vibrate and move more rapidly, the overall temperature of the sweater will increase.
It increases as the temperature increases.
When the temperature is increased, the resistivity of a material typically also increases. This is because at higher temperatures, the thermal vibrations of the atoms in the material increase, leading to more collisions with free electrons, which in turn increase resistance.
It increases.
the forest evaporates
Many reactions are of the form:dCA/dt = kCAdCA/dt is the change in concentration of A with timek is the reaction rate constantCA is the concentration of AThe rate constant often exhibits an Arrhenius relationship, so:k=Ae^(-Ea/RT)A is a pre-exponential term (constant)Ea is the activation energy of the reaction (constant)R is the universal gas constant (constant)T is the temperature of the reactionTherefore, as T increases, the value of the exponential term increases. This means that k will increase as T increases, and therefore dCA/dt will increases as T increases.Hope that helps!
If a gas,their moving speed increases,number of collisions increase
As kinetic energy, and therefore temperature increases, the number of effective collisions which result in sufficient activation energy also increases, which is why reactions happen at a faster rate at higher temperatures.
As kinetic energy increases, the particles in an object move faster and with greater speed. This results in increased motion and collisions among the particles, causing them to vibrate or rotate more vigorously. Ultimately, this leads to an overall increase in the temperature and internal energy of the object.
It will increase
When the temperature increases, the mercury in a thermometer expands and rises up the column because the volume of the liquid increases with temperature. This expansion is linear and is used to indicate the rise in temperature on the thermometer scale.
As Earth's depth increases, both temperature and pressure increase. The increase in temperature is primarily due to the Earth's internal heat and geothermal energy. Pressure increases with depth due to the weight of the overlying rock and materials compressing the layers beneath.
When air is compressed temperature increases because of the collission and vibration of molecules