thermal equilibrium

One sense is that of thermal equilibrium within a system for itself.

This is not true, as the law only applies in thermal equilibrium.

After a certain point you cannot bond and during this time your thermal equilibrium is reached.

But, as Albert might have said, thermal equilibrium was maintained.

While the transfer of energy as heat continues, the system is not in thermal equilibrium.

This is expected since the air and surface waters approach thermal equilibrium.

Thermal equilibrium must also take place unless the sample temperature is measured.

The Earth's atmosphere is then far from thermal equilibrium.

These bodies are said to be in thermal equilibrium.

Thus, on a very practical basis, there is no way to keep the two gas samples from thermal equilibrium.

If two systems are in thermal equilibrium their temperatures are the same.

At that point the net flow of energy is zero, and the systems are said to be in thermal equilibrium.

The temperature T arises from the fact that the system is in thermal equilibrium with its environment.

The heat bath remains in thermal equilibrium at temperature T no matter what the system does.

Calorimeters assume the sample is in thermal equilibrium or nearly so.

Hence the number of atoms in these two states will be approximately equal at thermal equilibrium.

The ratio of the different conformational states is determined by thermal equilibrium.

More generally, it can be applied to any classical system in thermal equilibrium, no matter how complicated.

A black body in thermal equilibrium has two notable properties:

Canonical ensemble: describes a system in thermal equilibrium with its environment.

A system is said to be in thermal equilibrium when it experiences no net change of its observable state over time.

Thermal equilibrium between two bodies entails that they have equal temperatures.

The substances and states of the two heat reservoirs should be chosen so that they are not in thermal equilibrium with one another.

Such a system is not in thermal equilibrium, and as such requires special conditions to occur.

If a container was in thermal equilibrium with that, it would be too cold to allow most chemical reactions to happen.