I recommend taking a climate science class. Understandable though, I don’t think I really got into the details of how the CC equation is useful until graduate school.
Long range ensembles look brutal for the entire lower-48. This is the pattern I’ve been worried about for this summer.
Even if the PNW escapes the first round in mid/late June, I suspect the death ridge will only expand further in July.
@the_convergence_zone The radiative forcing per doubling of CO^2 concentration is roughly 3.6W/m^2 before feedbacks. How much of that is actually thermalized depends on a gargantuan slew of factors that would require hundreds of pages to adequately explain. And even then it would be lacking.
Alas, long story short, future changes in precipitation worldwide will hinge on the spatiotemporal evolution of circulation/heat flows, clouds/albedo, etc. These variables (and numerous others) play outsized roles in regulating the planetary energy budget over space and time.
The Clausius Clapeyron equation (dP/dT = L/TΔV) quantifies the relationship between pressure and temperature of a parcel substance during a phase change (IE: evaporation, condensation, freezing, sublimation, etc). It can be useful in solving for theta-e, moist adiabatic LR, etc, depending on what constants and/or inputs you have.
But it’s irrelevant to what we’re talking about because it contains no spatiotemporal variables. You’re trying to sound smart by invoking thermodynamic equations that you clearly do not understand.