`{:(,2(s),+,3B(g),rarr,4C(g)),(t=0,10mol,,10mol,,):}`
Find final moles of `A,B` and `C` .

{:(,2A(s),+,3B(g),rarr,4C(g)),(t=0,10mol,,10mol,,):} Find final moles of A,B and C .

{:(,2A(s),+,3B(g),rarr,4C(g)),(t=0,10mol,,10mol,,):} Find final moles of A,B and C .

For the reaction 2A(g)+3B(l)rarrC(g)+4D(l),DeltaH=300"cal//mol" Calculate DeltaU (in calories) of reaction when 3 moles of A (g) react with 4 moles of B (l) at 27^(@)C. (R=2"cal//mol"-K)

{:(A^(-) (g) rarr A^(2+)(g),,DeltaH = 1100KJ//mol),(A(g)rarrA^(2+)(g),,DeltaH = 1200 KJ//mol):} Electron gain enthalpy of A is P xx 10^(2) KJ//mol . What is the value of P ?

{:(A^(-) (g) rarr A^(2+)(g),,DeltaH = 1100KJ//mol),(A(g)rarrA^(2+)(g),,DeltaH = 1200 KJ//mol):} Electron gain enthalpy of A is P xx 10^(2) KJ//mol . What is the value of P ?

Calculate Delta G (in joule) for the reaction 2A(g) to B(g)+C(g) when mixture contains 1 mole of A, 2 moles of B and 1 mole of C at total pressure of 10 atm and 300 K. [Given : G_(m)^(@),A(g)=40 "kJ mol"^(-1) , G_(m)^(@),B(g)=60 "kJ mol"^(-1) , G_(m)^(@),C(g)=20 "kJ mol"^(-1) , R=8.3 JK^(-1)mol^(-1) and "In " 2=0.7 ]

For 2A(g) B(g) +3C(g) , Pressure of A at t = 0 is 500 mm, then total pressure of A, B & C at t = 10 min is( in mm)

What mass of oxygen gas is required to burn completely 2.5 mol of method? underset(underset("reactant")("one"))("Moles of ")rarr underset(underset("reactant")("another"))("Mass of") Stragetgy : Use the balanced equation {:(CH_(4), + 2O_(2), rarr CO_(2), + 2H_(2) O),(1mol, 2mol,1 mol,2mol),(16.0 g,2(32.0)g,44.0g,2(18.0g)):} to find the relationship among moles and grams of reactants : underset(CH_(4))("Mole of ")rarr underset(O_(2))("Moles of")rarr underset(O_(2))("grams of")

The enthalpy change for the following process are listed below : (a) Cl_(2(g)) rarr 2Cl_((g)), DeltaH=242.3kJ mol^(-1) (b) I_(2(g))rarr 2I_((g)), DeltaH=151.0kJ mol^(-1) (c) ICl_((g)) rarr I_((g))+Cl_((g)), DeltaH=211.3kJ mol^(-1) (d) I_(2(s)) rarr I_(2(g)), DeltaH=62.76kJ mol^(-1) If standard state of iodine and chloride are I_(2(s)) and Cl_(2(g)) , the standard enthalpy of formation for ICl_((g)) is :