A source contains two phosphorous radio nuclides `""_(15)^(32)P (T_(1//2) = 14.3d)` and `""_(15)^(33)P(T_(1//2) = 25.3d)`. Initially, 10% of the decays come from `""_(15)^(33)P`. How long one must wait until 90% do so?

IF ""^(15)P_(r-1):""^(16)P_(r-2) = 3 : 4 then r=

n^(th) term of an A.P. is a_(n) . If a_(1)+a_(2)+a_(3) = 102 and a_(1) = 15 , then find a_(10) .

The element with the electronic configuration 1s^(2) 2s^(2) 2p^(6) 3s^(2) 3p^(6) 3d^(10) 4s^(1) is

A gaseous system changes from state A(P_(1), V_(1), T_(1)) " to " B(P_(2), V_(2), T_(2)), B " to " C(P_(3), V_(3), T_(3)) and finally from C to A. The whole process may be called

For 2NH_3(g) underset(Delta)overset(Pt)(to) products follows zero order kinetics. If t_(1//2) at p = 4 atm is 25 sec, t_(1//2) at p = 16 atm will be (in sec)

Density of gas is inversely proportional to absolute temperature and directly proportional to pressure rArr d prop P/T rArr (dT)/P = constant rArr (d_(1)T_(1))/P_(1) =(d_(2)T_(2))/P_(2) Density at a particular temperature and pressure can be calculated bousing ideal gas equation PV = nRT rArr PV = ("mass")/("molar mass (M)") x RT P xx M =("mass")/("volume") xx RT rArr P xx M = d xx RT d=(PM)/(RT) The density of gas is 3.8 g L^(-1) at STP. The density at 27°C and 700 mm Hg pressure will be

if the equation (3x ) ^(2) +(27 xx 3 ^(1//p) - 15 ) x+4=0 has equal roots then p=

H_(2)O_(2(aq)) decomposes to H_(2)O_((l))and O_(2(g)) in a first reaction w.r.t. H_(2)O_(2). The rate constant is k=1.06 xx10^(-3) "min" ^(-1). How long it will take 15% of the sample of defcompose ?