To solve this problem it is necessary to apply the concepts related to temperature stagnation and adiabatic pressure in a system.
The stagnation temperature can be defined as
[tex]T_0 = T+\frac{V^2}{2c_p}[/tex]
Where
T = Static temperature
V = Velocity of Fluid
[tex]c_p =[/tex] Specific Heat
Re-arrange to find the static temperature we have that
[tex]T = T_0 - \frac{V^2}{2c_p}[/tex]
[tex]T = 673.15-(\frac{528}{2*1.005})(\frac{1}{1000})[/tex]
[tex]T = 672.88K[/tex]
Now the pressure of helium by using the Adiabatic pressure temperature is
[tex]P = P_0 (\frac{T}{T_0})^{k/(k-1)}[/tex]
Where,
[tex]P_0[/tex]= Stagnation pressure of the fluid
k = Specific heat ratio
Replacing we have that
[tex]P = 0.4 (\frac{672.88}{673.15})^{1.4/(1.4-1)}[/tex]
[tex]P = 0.399Mpa[/tex]
Therefore the static temperature of air at given conditions is 72.88K and the static pressure is 0.399Mpa
Note: I took the exactly temperature of 400 ° C the equivalent of 673.15K. The approach given in the 600K statement could be inaccurate.
