Just to back up the correct ideal(or perfect) gas equation that is Pv=RT, with v = specific volume (1/density).
This subject can be attacked from a different perspective...
It can be seen with the basic conservation of energy equation (applied to a diffuser) and some basic assumptions (one-dimensional flow, negligible heat transer, negligible changes in potential energy, and non-flow Work, as well as steady state flow conditions)
The equation simplifies to...
mfr-in * (h1 + Vin^2/2) = mfr-out * (h2 + Vout^2/2)
with mfr = mass flow rate, and with the steady state assumption, these terms cancel because mfr-in=mfr-out,
then the equation becomes...
h1 + Vin^2/2 = h2 + Vout^2/2
now, h = enthalpy, which is defined as h = u + Pv
with ..
u = internal energy
P= PRESSURE (what we're looking at
v= specific volume
now looking at our equation... h1 + Vin^2/2 = h2 + Vout^2/2
with Vout decreasing significantly at the exit of the diffuser, this drop in magnitude has to be made up by h2 = u + Pv, this correction is mainly due to a RISE in pressure, as "Guest" mentioned before.
Now, this is a somewhat simplified look, but this is how fluids is generally taught at the basic level, to understand the basic charactersistics of a diffuser. I know this stuff didn't add much to the aerodynamic discussion, but i thought a different look at the subject apart from the perfect gas equation might interest some of you. If you have some questions on some of the terms or things i've said, let me know.
If you see a big mistake, let me know (i'm supposed to know this stuff, being an engineering student, lol)
