And in the long term, human emissions would have to drop to ZERO in order to stabilize concentrations, because the deep ocean will
eventually reach equilibrium with the surface layers.
Moreover, labor costs should
eventually reach an equilibrium across the globe, since people and their needs are the same across the globe.
Not exact matches
The resulting rough edges dampen the power of the waves, reducing their effect on newly exposed, weaker rock until
eventually the process
reaches equilibrium.
I think all closeted men and women
eventually reach this breaking of the
equilibrium, and that's when we finally say it out loud.
Eventually a new
equilibrium is
reached: the warming trend stops — energy in and energy out balance.
In fact, a gas with a DALR is a fairly special case of the many «
equilibria» one can
reach in the specific limit of hydrodynamic relaxation (only) to a state of hydrostatic balance neglecting the much slower thermal relaxation that
eventually makes the gas isothermal.
From gbaikie:
Eventually it will
reach thermal
equilibrium, correct?
It will
eventually reach thermal
equilibrium again by oth law, isentropic now with 4 bodies.
Eventually it will
reach thermal
equilibrium, correct?
Eventually the skin layer
reaches a new
equilibrium where energy in = energy out.
However, planets will
eventually reach new
equilibrium states where the heat - loss balances the energy input.
You based this on the following definition of the 2nd law: «'' When two isolated systems in separate but nearby regions of space, each in thermodynamic
equilibrium in itslef, but not in
equilibrium with each other t first, are at some time allowed to interact, breaking the isolation that separates the two systems, and they exchange matter or energy, they will
eventually reach a mutual thermodynamic
equilibrium.»
«When two isolated systems in separate but nearby regions of space, each in thermodynamic
equilibrium in itself, but not in
equilibrium with each other at first, are at some time allowed to interact, breaking the isolation that separates the two systems, and they exchange matter or energy, they will
eventually reach a mutual thermodynamic
equilibrium.»
But the crucial conclusion from the 2nd law, is that as a result they «will
eventually reach a mutual
equilibrium.»
You based this on the following definition of the 2nd law: ««When two isolated systems in separate but nearby regions of space, each in thermodynamic
equilibrium in itself, but not in
equilibrium with each other at first, are at some time allowed to interact, breaking the isolation that separates the two systems, and they exchange matter or energy, they will
eventually reach a mutual thermodynamic
equilibrium.»