#1)# What is the change in internal energy of combustion in #"kJ/mol"# for a bomb calorimeter whose heat capacity is #"3024 J/"^@ "C"# that has raised in temperature by #1.2910^@ "C"# due to the combustion of #"0.1575 g Mg"#? Also help with one more?
#2)# If the change in enthalpy of reaction for #"2NO"(g) + "O"_2(g) -> 2"NO"_2(g)# is #-"114.6 kJ"# , then what amount of heat is produced when #"23.000 kg"# of #"NO"_2(g)# is generated?
1 Answer
I would have asked this in two separate questions...
#DeltaE = q + w#
#= q - cancel(PDeltaV)#
so the heat flow is equal to the change in internal energy in this scenario. You were given not the specific heat capacity, but the heat capacity... note the units are
The amount of internal energy released from the bomb out to the water is:
#DeltaE = q = "3024 J/"cancel(""^@ "C") cdot (1.2910cancel(""^@ "C"))#
#= "3904 J" = "3.904 kJ"#
But the question wants you to report it in
Thus, the internal energy released from the magnesium is:
#color(blue)(DeltaE_C) = |-"3.904 kJ"/(0.1575 cancel"g Mg" xx "1 mol Mg"/(24.305 cancel"g Mg"))|#
#=# #color(blue)("602.5 kJ/mol")#
and the VALUE of
#2"NO"(g) + "O"_2(g) -> 2"NO"_2(g)#
#DeltaH_(rxn) = -"114.6 kJ/"color(red)("2 mols NO"_2(g))# .
That then acts as a conversion factor. The heat PRODUCED asked for is the magnitude, not a negative value. So,
#color(blue)(DeltaH_(rxn)) = 2.30 xx 10^4 cancel("g NO"_2) xx cancel("1 mol NO"_2)/(46.0055 cancel("g NO"_2)) xx "+114.6 kJ"/(2 cancel("mol NO"_2))#
#= color(blue)(2.86 xx 10^4 "kJ")#
