[" The bond energies of "C=C" and "],[C-C" at "298K" are "590" and "],[331kJmol^(-1)" ,respectively.The "],[" enthalpy of polymerization per mole of "],[" ethylene is "]

The bond energies of C=C and C-C at 298 K are 590 and 331 kJ mol^(-1) , respectively. The enthalpy of polymerisation per mole of ethaylene is

The bond energies of C=C and C-C at 298 K are 590 and 331 kJ mol^(-1) , respectively. The enthalpy of polymerisation per mole of ethaylene is

The polymerisation of ethylene to linear polyethylene is represented by the reaction nCH_(2)=CH_(2)rarr(-CH_(2)-CH_(2)-)_(n) When n has a large integral value. Given theat the average enthalpies of bond dissociation for C=C and C-C at 298K are +590 and +331kJ mol^(-1) respectively, calculate the enthalpy of polymerisation per mole of ethylene at 298K .

The polymerisation of ethylene to linear polyethylene is represented by the reaction nCH_(2)=CH_(2)rarr(-CH_(2)-CH_(2)-)_(n) When n has a large integral value. Given theat the average enthalpies of bond dissociation for C=C and C-C at 298K are +590 and +331kJ mol^(-1) respectively, calculate the enthalpy of polymerisation per mole of ethylene at 298K .

The polymerisation of propene to linear polypropene is represented by the reaction where n has intergral value, the average enthalpies of bond dissociation for (C =C) and (C -C) at 298K are +509 and +331 kJ mol^(-1) , respectively. the enthalpy of polymerisation is -360 kJ . Find the value of n .

The polymerisation of propene to linear polypropene is represented by the reaction where n has intergral value, the average enthalpies of bond dissociation for (C =C) and (C -C) at 298K are +509 and +331 kJ mol^(-1) , respectively. the enthalpy of polymerisation is -360 kJ . Find the value of n .