The value of `C_(p) - C_(v)` is `1.09R` for a gas sample in state `A` and is `1.00R` in state `B`. Let `T_(A),T_(B)` denote the temperature and `p_(A)` and `p_(B)` denote the pressure of the states `A` and `B` respectively. Then

Let T_a and T_b be the final temperatures of the samples A and B respectively in the previous question.

two samples 1 and 2 are initially kept in the same state. the sample 1 is expanded through an isothermal process where as sample 2 through an adiabatic process up to the same final volume.Let p_(1) and p_(2) be the final pressure of the samples and 2 respectively in the previous question then.

A platinum resistance thermometer is constructed which reads ,0^0 at ice point and 100^0 at steam point. Let t_p denote temperature on this scale and let t denote the temperature on a mercury on a mercury thermometer scale. The resistance of the platinum coil varies with t as R_1 = R_0 (1+alphat + betat^2) . Derive an expression for the resistance as a function of T_p .

Two gases A and B having same pressure P, volume V , and Temperature T are mixed . If mixture has volume and temperature as V ans T respectively. Then pressure of mixture is :

Let overset(to)(OA) = overset(to)(a), vec(OB)= 10vec(a) + 2vec(b) " and " overset(to)(OC)=overset(to)(b) where O,A and C are non-collinear points . Let P denotes the area of the quadrilateral OABC and let q denots the area of the parallelogram with OA and OC as adjacent sides. If p =kq , then k=........

For hydrogen gas C_p - C_v = a and for oxygen gas C_p - C_v = b . The relation between a and b is

Sum of the first p, q and r terms of an A.P. are a, b and c, respectively. Prove that a/p(q-r)+b/q (r-p) +c/r (p-q)=0

If A and B are two events such that P(A)=1/2 , P(B) =7/(12) and P(not A or not B) = 1/4 . State whether A and B are independent?