False, the two are totally unrelated. Temperature is related to the average energy of the particles.False, the two are totally unrelated. Temperature is related to the average energy of the particles.False, the two are totally unrelated. Temperature is related to the average energy of the particles.False, the two are totally unrelated. Temperature is related to the average energy of the particles.
anything that is real takes up space and has mass. that is how and object is related to mass
NO We can think of temperature as mass with a speed. No mass no temperature, no speed, no temperature. Therefore, if mass went to absolute zero, it would have no speed and could not oscillate (emit energy) in the first place. So most agree that no mass can go to absolute rest in the first place.
No, a body's inertia is related to its mass and movement. Weight is related to a body's mass in a gravity field without movement.
Mass is measured with a balance and temperature with a thermometer. cw: Mass (gravitational): Usually you measure the force of its attraction to Earth. Mass(kinetic): Usually you measure the acceleration from a given force. Temperature can also be measured by its radiation spectrum (e.g., a star).
Density = mass/volume so it is related to mass and volume. And Volume is related to temperature and pressure, so it is related to those as well.
For a given volume and pressure, the mass of the air contained in that volume (density) will decrease as the temperature increases.
Celsius and degree measure temperature. Celsius, mass, and kelvin are metric measurements. Celsius and Kelvin are metric and temperature measurements. Celsius and Kelvin are the related terms.
False, the two are totally unrelated. Temperature is related to the average energy of the particles.False, the two are totally unrelated. Temperature is related to the average energy of the particles.False, the two are totally unrelated. Temperature is related to the average energy of the particles.False, the two are totally unrelated. Temperature is related to the average energy of the particles.
This is the formula for finding calories: calories= (Tf-Ti)mass Or, in words, you subtract the final temperature (the temperature of the fused waters) by its initial temperature (the hot/ cold water's original temperature). You then multiply this answer by the mass of the water before you mix them together. Your hot and cold water should both have the same mass, but not the same temperature.
No. Stars vary in lots of aspects, including:* Diameter * Mass * Color (and the related surface temperature) * Chemical composition * Density (related to mass and diameter) * Brightness
Mass does not change with temperature
The color of a star is mainly related to the star's surface temperature. This is only remotely related to the star's mass; for example, high-mass stars can either be very hot (blue) or not-so-hot (red), depending on the phase in the star's life.
Hi, heat transferred = mass x specific heat capacity x rise/fall in temperature If heat is lost then fall in temperature If heat is gained then rise in temperature. More the transfer then greater the difference in temperature.
Hi, heat transferred = mass x specific heat capacity x rise/fall in temperature If heat is lost then fall in temperature If heat is gained then rise in temperature. More the transfer then greater the difference in temperature.
Hi, heat transferred = mass x specific heat capacity x rise/fall in temperature If heat is lost then fall in temperature If heat is gained then rise in temperature. More the transfer then greater the difference in temperature.
Temperature has no effect on molar mass