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Yes, the more mass the object has, the more temperature the object will have. Think of it like a fat person, when he sweats, he sweats more than a thin person.
Thermal energy depends on mass, temperature and specific heat capacity of the material. Larger means, is that in mass? If so then thermal energy would be more in larger compared to that smaller at the same temperature provided both are made up of the same material.
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.
Water has a greater specific heat capacity.
The mass has quite a big influence on the kinetic energy, cause its a factor in the formula: 1/2mv2
Yes, the more mass the object has, the more temperature the object will have. Think of it like a fat person, when he sweats, he sweats more than a thin person.
more = greater
Where in the world did that idea come from ? Compare an iceberg the size of California and a cup of coffee.
Thermal energy depends on mass, temperature and specific heat capacity of the material. Larger means, is that in mass? If so then thermal energy would be more in larger compared to that smaller at the same temperature provided both are made up of the same material.
Basically, the amount of hydrogen (mass). The more mass a star has, the greater the pressure in the core. The greater the pressures in the core, the higher the temperature, the higher the temperature, the hotter the star will be, the hotter the star, the blighter the envelope will be.
more = greater
If a star has more mass, there will be more gravitational attraction. The star's material will get closer together, and the star will have more temperature and more pressure.
Cooler material (magma) shrinks and becomes more dense. Gravity acts on this denser material more strongly because of its greater unit mass (density = Mass/volume). Lighter material rises as the heavier material displaces it below. This produces a the apparent bouyant force.
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.
Water has a greater specific heat capacity.
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.
Heat is transferred based on the temperature of a mass (relative to the cooler mass it is transferring heat to) and the heat capacity of the mass. The total heat capacity is a product of the mass and the specific heat, i.e. Heat capacity = mass x specific heat. The hotter the mass, the more heat it can transfer. The greater the mass, the more heat it can transfer per degree of temperature drop. 100 kg of boiling water could be expected to be able to transfer 100 times the amount of heat of just 1 kg of boiling water for a drop of 1 °C.