Chemistry, Third edition

ANSWERS TO EXERCISES AND REVISION QUESTIONS

(c) Two fluorine atoms accept electrons:

2F(g)2e–2F–(g) H^ — 4 (2339)678 kJ mol–^1

Substituting into equation (A),

H^ — 5  1121  148  2200  158  678

2949 kJ mol–^1

or,H^ —LH^ — 5 2949 kJ mol–^1.

13O

Average(5311075)/2803 kJ mol–^1.

13P

(i)The standard enthalpy change for the process

CH 4 (g)CH 3 (g)H(g) will approximately equal H^ —C–H.

Therefore the enthalpy change for the reverse

process:

CH 3 (g)H(g)CH 4 (g)

will be H^ —C–H, i.e. 412 kJ mol–^1.

(ii)Comparing the bond lengths with the bond enthalpy

data in Table 13.4, the trend supports the proposition

that long bonds are weak bonds (or, conversely, that

short bonds are strong bonds).

(iii)Double and triple bonds are stronger than single

bonds. The general order of bond strength is triple bonds

double bonds single bonds.

13Q

(i)CH 2 CH 2 (g)Cl 2 (g)CH 2 Cl–CH 2 Cl(g)

To completely break up the molecules on the left-hand

side of this equation we need to dissociate: one CC

bond, four C–H bonds and one Cl–Cl bond. From

Table 13.4,

energy absorbed  612 4(412) 242 2502 kJ mol–^1

i.e. the energy change due to bond destruction is

2502 kJ.

To form the reactant molecules, we need to make four

C–H bonds, two C–Cl bonds and one C–C bond. From

Table 13.4,

energy given out 4(412)2(338) 348 2672 kJ

mol–^1

i.e. the energy change due to bond formation  2672

kJ. Therefore, the net change in energy is

H^ —f(298 K)  2502  2672 170 kJ mol–^1

(ii)Bond energies can be used directly only if all the

reactants and products are gases. If some reactants or

products are not gases then the enthalpy change for the

phase change (solid gas or liquid gas) must be

allowed for.

We start by working out the enthalpy change for the

reaction in which all the reactants and products are

gaseous:

2H 2 O(g)2H 2 (g)O 2 (g) (A)

We now apply the average bond energies in Table 13.4

for the heat absorbed in breaking bonds in reactant

molecules, this involves breaking four O–H bonds:

4  463 1852 kJ mol–^1

From Table 13.4 the heat released when bonds in

product molecules are assembled, which involves

making two H–H bonds and one OO bond is

(2 436) 497 1369 kJ mol–^1

The overall change in enthalpy is therefore

H^ —A 1852  1369 483 kJ mol–^1

However, we want the enthalpy change for the reaction

2H 2 O(l)2H 2 (g)O 2 (g) (B)

and we are given

H 2 O(l)H 2 O(g) H^ —f44 kJ mol–^1

or

2H 2 O(l)2H 2 O(g) H—^ f88 kJ mol–^1

H 2 O(g) possesses a higher enthalpy than H 2 O(l): this

means that the enthalpy change for reaction (B) will be

larger than that of reaction (A) by 88 kJ. (If you can’t see

this, draw an energy diagram for the processes involved):

H—^ B(298 K)  483  88 571 kJ mol–^1

Revision questions

13.1Following are false: (i),(ii),(iv)(2 mol SO 3 (g)

made) and (vi).

13.2 (i)See text.

(ii)Combustion of methyl benzene:

C 7 H 8 (l)9O 2 (g)7CO 2 (g)4H 2 O(l)

H—c^ [4H—^ f(H 2 O(l)) 7 H^ —f(CO 2 (g))][H^ —f(C 7 H 8 (l))

 9 H^ —f(O 2 (g))]

From Table 13.2:

[(285.83 4)(393.51 7)][12.00]

 (3897.89)(12.0)3909.9 kJ per mole of

methyl benzene

(iii)1 mol of methyl benzene has a molar mass of

approximately 92 g mol–^1.

Heat given out in the complete combustion of 1 g of

methyl benzene is 3909.9/92 42 kJ g–^1.

1 cm^3 of methyl benzene has a mass of 0.86 g.

The heat given out in the complete combustion of

1 cm^3 of methyl benzene is approximately

42 0.8636 kJ cm–^3.

13.3 (i)H^ —f[Hf—^ (P(s) (red))] [H^ —f(P(s) (white))]

 18  0 18 kJ mol–^1

i.e. red phosphorus is the more energetically stable form

of phosphorus.

(ii)

H—^ f[Hf^ —(H 2 O(l))H^ —f(CH 3 CO 2 C 2 H 5 (l))]

[H—f^ (C 2 H 5 OH(l))H—f^ (CH 3 CO 2 H)(l)]

(285.83481)(277.69485)

(766.83)(762.69)

 4 kJ mol–^1

(iii)

H—f^ [3H^ —f(N 2 (g)) 9 H^ —f(H 2 O(g))

 5 H^ —f(Al 2 O 3 (s)) 6 H^ —f(HCl(g))]

[6H^ —f(NH 4 ClO 4 (s)) 10 H^ —f(Al(s))]

TheH^ —fof elements in their reference states is zero.

H—^ f(NH 4 ClO 4 (s)) is obtained from Table 13.2.

H—^ f[(241.82 9)(1675.7 5)

(92.31 6)][295.31 6]

[2176.388378.5553.86][1771.86]



9337 kJ mol–^1

(Notice that the effect of producing a highly exothermic

compound (Al 2 O 3 (s)), is to make the overall reaction

highly exothermic.)

13.4Ignoring the heat capacity of the calorimeter and of

the reactants and products,

q mmixtureCmixtureT

q 100  4.18 0.411.7 102 J

...H1.7 102 J

Neither reactant is in excess. The number of moles of

Ag+(aq) (which equals the number of moles of Cl–(aq)) is

(^0500) 0.0502.5 10 – 3
1000
The enthalpy change when 1 mol of either reactant is
consumed is
H^1
2.5 10 –^3  1.7^10
2
H 6.8 104  68 kJ mol–1
13.5HCOOH(l)^1 ⁄ 2 O 2 (g)CO 2 (g)H 2 O(l)
H—^ c277.2 kJ mol–^1
H—^ c[H^ —f(COO(g))H—^ f(H 2 O(l))]
[H—^ f(HCOOH(l))^1 ⁄ 2 H^ —f(O 2 (g))]
whereH—f^ (HCOOH(l)) is the only unknown,
H—^ f(CO 2 (g))393.51 kJ mol–^1 andH^ —f(H 2 O(l))
285.83 kJ mol–^1 (from Table 13.2) and H—^ f(O 2 (g))
0. Substitution and rearrangement gives:
H—^ f(HCOOH(l)(393.51285.83)(277.2)
402.1 kJ mol–^1
13.6 (i)C 6 H 12 O 6 (s)6O 2 (g)6CO 2 (g)6H 2 O(l)
(ii)M(C 6 H 12 O 6 )180 g mol–^1. The complete
combustion of 180 g of glucose releases 2816 kJ of
energy. The complete combustion of 10 g of glucose
would release (10/180) 2816 160 kJ (2 significant
figures). If the combustion of glucose within the body
were only 40% efficient, only 64 kJ of energy would be
available for work for every 10 g of glucose consumed.
13.7 (i)The third standard ionization energy of
aluminium is the standard enthalpy change for the
process
Al^2 +(g)Al^3 +(g)e–
H—^ ion(3)2751 kJ mol–^1
(ii)The equation
Al(s)Al^3 +(g)3e– (A)
is the sum of the equations:
Al(s)Al(g) (B)
Al(g)Al+(g)e– (C)
Al+(g)Al^2 +(g)e– (D)
Al^2 +(g)Al^3 +(g)3e– (E)
The enthalpy change for reaction (A) is the sum of the
enthalpy changes for reactions (B)–(E) (If you are unsure
about this, sketch an energy diagram):
H—A^ H—B^ H^ —CH^ —DH^ —E
 326  584  1823  2751 5484 kJ mol–^1
13.8
(a) Ca(s) Ca(g) H—^1
(b) Ca(g) Ca+(g)e– H—^ 2A
(c) Ca+(g)Ca^2 +(g)e– H—^ 2B
(d) O 2 (g)O(g)O(g) H—^3
(e) O(g) 2e–O^2 – (g) H—^4
(f) Ca^2 +,O–(s)Ca^2 +(g)O^2 – (g) H—^ L
The formation of calcium oxide,
Ca(s)^1 ⁄ 2 O 2 (g)Ca^2 +,O–(s) H—^ f
may also be split up into steps, as for NaCl. We follow
the pattern for NaCl in the text, with
H—^2 H2A—^ H^ —2B. Therefore,
H—^ fH^ — 1 H^ — 2 ^1 ⁄ 2 H—^3 H— 4 (H^ —L)
Notice that only half of H^ — 3 is required because only
one atom of O is required to combine with one atom
of Ca.
H—^ f 193  1740 248.5 703  3513
629 kJ mol–^1
13.9
2F 2 (g)S(g)SF 4 (g) H—^ f994 kJ mol–^1
In breaking bonds in the reactant molecules, we break
two F–F bonds:
heat absorbed  2  158 316 kJ
The heat released when bonds in product molecules are
assembled involves making four S–F bonds, each of
bond enthalpy x. The total enthalpy change is 4x (which
is negative because heat is given out when bonds are
formed). Therefore, the overall change in enthalpy is
 994  4 x 316
which gives
xH—^ S–F(994316)/4
x328 kJ per mole of S–F bonds.
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