12: Intermolecular Forces

S1a

1. H-bonding
2. Dipole
3. London
4. Dipole

S1b

1. Ion-Ion
2. London Forces
3. Dipole-Dipole
4. Hydrogen bonding

S1c

1. In \(HF\), there are weak London forces and molecule hydrogen bonding is the strongest force present
2. Because of the polarity in the \(I-Cl\) bond, it contains dipole interactions
3. Since \(HCl\) is not a diatomic molecule, London forces are weak. Hydrogen bonding is weak because it is not an (\(F\),\(O\),\(N\)) atom. However, \(Cl\) is electronegative and hydrogen only a little electronegative, so \(HCl\) has a dipole moment.
4. \(Br_2\) clearly doesn't have a hydrogen bond, neither does it have a dipole moment. Therefore the strongest force is the London force because \(Br_2\) had a larger atomic mass
5. \(CH_4\), not an (\(F\),\(O\),\(N\)) atom therefore it has no H-bond, it has no dipole dipole interactions, plus London forces are weak which is why it has a a very low critical temperature.

S1d

There are typically three main forces affecting liquid and solids: hydrogen bonding, dipole-dipole interactions and London forces.

• \(CHCl_3\): Since N,O or F is not present, there is no hydrogen bonding. It’s a polar molecule, and has a strong dipole-dipole interaction.
• \(F_2\): In the molecule \(F_2\), there are no \(H\) atoms, and thus can have neither dipole moments (dipole-dipole interactions) nor hydrogen bonding. Thus, London forces are the most important.
• \(CO\): Since there is no Hydrogen, there is no hydrogen bonding. \(CO\) has a very small dipole moment, but they do affect the molecule. Overall, London forces are the strongest force.
• \(OH\): Since this molecule is small, London forces are not very strong. Here, hydrogen bonding is the strongest force.
• \(CH_3CH_3\): The only significant force here is London forces because of the molecules lack of a great difference in electronegativity and shape.

S3a

The greater the forces that hold the liquid together (molecular forces) the greater its resistance to flow (viscosity)

1. \(H_2O\)
2. \(CHCl_3\)
3. \(CH_3OH\)
4. \(Ar\)

S3c

The greater the forces that hold the liquid together (molecular forces) the greater its resistance to flow (viscosity)

(d)<(a)<(c)<(b)

S5a

\(C_3H_8O\)

S5b

\(H_2O\): The attraction of the hydrogen bonds keeps water a liquid over a wide temperature range and the energy required to break these multiple hydrogen bonds causes water to stay intact (ie, the bonds don’t break until a high enough temperature is reached for it to vaporize).

S5c

1. \(CH_3OH\) is the liquid. \(C_2H_6\) has more electrons so it has a stronger London force.
2. \(CH_3OH\) also has hydrogen bonding.

S5d

\(NaCl\) is a liquid at room temperature. This is because out of all of the listed elements, it has the strongest intermolecular forces and therefore the highest boiling point.

S5e

The answer here is C, \(C_2H_5OH\). Without knowing the specific properties of this substance, we expect this to be in liquid form because of high potential to form hydrogen bonds (the OH suffix), and so its intermolecular attractions should be much stronger than usually seen in gasses.

S11a

The detergent lowers the surface tension of the water, thereby lowering the energy and allowing water to spread more easily. Detergent is therefore known as a wetting agent.

http://chemwiki.ucdavis.edu/Physical_Chemistry/Physical_Properties_of_Matter/Atomic_and_Molecular_Properties/Intermolecular_Forces/Cohesive_And_Adhesive_Forces/Surface_Tension

S11b

(c) < (a) < (b)

Q11c

Water is a polar molecule meaning that there is unequal sharing of electrons between the hydrogen and oxygen atoms. Oils are made of hydrocarbon chains that are bonded by hydrogen. The elements and structure of oil cause them to become non-polar which means they won’t combine with water.

S11d

Increasing the temperature of the liquid causes the molecules to move faster. And the more energy the more molecules are able to break free at the surface causing the vapor pressure to increase.

S11e

The most important part of the answer is given in the question; hydrocarbons are non-polar. Wood is carbon based, and is non-polar, but is very porous so it does allow water to enter it. Since both the deck and (\(C_9H_{12}\)) are non-polar, they naturally adhere to each other. Water, a polar substance, does not adhere very well to non-polar materials. Once the deck is coated with the non-polar oil, water is naturally repelled.

S11f

Fluorine has high electronegativity and small dimensional size. Also, Fluorine has a strong chemical bond with carbon, creating a stable organic chemical, which has good heat, chemical, and weather resistant properties.

S12a

As the temperature increases, there is additional movement between the molecules forces, leading to easily broken bonds and weak intermolecular forces. Thus, as the temperature increases, the forces controlling surface tension decrease, decreasing the surface tension. Conversely, vapor pressure change is indicated by the Clausius-Clapeyron equation. Usually, vapor pressure is always moving towards its boiling point, or when the vapor pressure is equal to the atmospheric pressure. As you increase the vapor pressure, you reach boiling point faster, which takes less change in heat (or temperature). Thus, as temperature increases, so does the vapor pressure.

S13a

Honey has viscosity because of the strong intermolecular attractions, and lots of internal friction. These properties make the substance thick and sluggish.

S13b

Syrup has a high viscosity. The coldest temperature will produce the thickest liquid because the higher the viscosity, the colder the liquid all due to intermolecular forces.

S14a

Detergent is a wetting agent which lowers the energy required to spread out a water molecule throughout a surface.

S14b

When something “wets” the surface it means that a drop of liquid is spreading into a film of liquid across a surface. This depends on the intermolecular forces and their strengths. “Wetting agents” reduce the surface tension of water so it is able to glide along surfaces more easily.

S19a

At higher altitudes, air pressure is lower and the reduced air pressure lowers the temperature at which water boils in an open container making it easier to evaporate.

S19b

First conver temperature to absolution temperature

• 24.2 °C + 273.15 = 297.35 K
• 69.2 °C + 273.15 = 342.35 K

\[ln \left(\dfrac{89.2}{34.2} \right) = \dfrac{∆H}{ 8.3145} \left[ \dfrac{1}{297.35} – \dfrac{1}{342.35} \right] \]

\[∆H = 18.0\; kJ\]

S20a

Ethyl alcohol feels cool because of heat of evaporation. While the alcohol is evaporating, it absorbs heat from both the skin underneath it and also from the air around it therefore we feel it is cold when we rub it against the skin.

S20b

• Increased temperature: more molecules have sufficient kinetic energy to overcome intermolecular forces
• Increased surface area: there are more liquid molecules at the surface
• Decreased strength of intermolecular forces: the energy needed to overcome intermolecular forces is less, and more molecules have the energy to escape.

http://chemwiki.ucdavis.edu/Physical_Chemistry/Thermodynamics/State_Functions/Enthalpy/Enthalpy_Of_Vaporization

S20c

Because this is the boiling point, the liquid at the top will be becoming vapor while the bottom remains liquid.

S20d

Vapor pressure is lower during evaporation than when the whole liquid is boiling. Because the vapor pressure is not as high when the temperature of the liquid is lower, atmospheric pressure is greater which causes just the top of the liquid to vaporize. When boiling, the temperature of the liquid is higher and its vapor pressure is equal to the atmospheric pressure. This causes vapor to form throughout the liquid and be released.

S21a

Vaporization: liquid to gas

• Pressure= 1.1 atm
• Temperature= 23C+ 273= 300K

\[V=\dfrac{nRT}{P}\]

\[n=\dfrac{27.25\ \frac{kJ}{mol}}{ 2.56\ kJ} =10.64\ mol\ (C_2H_5)_2O\]

\[V= \dfrac{(10.64\ mol) (300\ K) (0.0821\ L\ \frac{atm}{mol\ K})}{1.1\ atm}\]

\[V= 238.2\ L\]

S21b

Given: \(\Delta H_{vap}=40.67\ \frac{kJ}{mol}\) at 100℃

\(100^oC + 273.15 = 373.15\ K\)

\(V= \dfrac{nRT}{P} = 1.25\ kJ\times \frac{(1\ mol)}{(40.67\ kJ)} \times 0.08206\frac{(L\ atm)}{(mol\ K)}\times 373.15 \frac{K}{1\ atm} = 0.941L\ H_2O_{(l)}\)

S21C

\[V=\dfrac{nRT}{P} =\dfrac{1.69kJ\times \frac{1mol}{33kJ}\times 0.08206\frac{L\ atm}{mol\ K}\times 298K}{105.3mmHg\times \frac{1atm}{760mmHg}}=9.04L\ C_6H_{12(l)}\]

S20E

Vaporization occurs when a water molecule gains enough energy to escape from the waters surface.

S21E

\(V=\frac{nRT}{P}\)

\(V= \frac{(1.69 kJ\times \frac{1mol}{42.6\ kJ}) \times(0.08206 \frac{L\ atm}{mol\ K}) (298K)} {(92.4mmHg\times \frac{1\ atm}{760 \ mmHg})}\)

\(V = 7.98L\ CH_3CH_2OH_{(l)}\)

S25B

Heat needed:

\(4.23L\ CH_3OH\times \frac{1000cm^3}{1L}\times \frac{0.798\ g}{1\ cm^3}\times \frac{1mol}{34.042}\times \frac{38kJ}{1\ mol}= 3768\ kJ\)

Amount of \(C_2H_6\) needed:

\(3768\ kJ\times \frac{1\ mol}{1.56\times 10^3\ kJ}= 2.42\ moles\ of\ C_2H_6\)

S12.29

Even though it is unstated in the problem, we are asked about the vapor pressure of water, which is a liquid at two different temperatures and pressures. We know that at water’s BP (100 ºC) pressure is 1 atm. When asked about 2 states and 1 compound of interest, we use Clausius-Clapeyron equation. We also know that enthalpy of vaporization for water is \(40.7\frac{kJ}{mol}\)

• \(T_1=100 + 273.15 = 373.15\ K\)
• \(P_1=1\ atm\)
• \(T_2= 50+ 273.15= 323.15\ K\)
• \(P_2=?\)

$$\ln \left(\dfrac{P_2}{P_1}\right)= \dfrac{ΔH_{vap}}{R} \left( \dfrac{1}{T_1} - \dfrac{1}{T_2} \right)\]

$$ln(\frac{P_2}{1atm})=[\frac{40,700J}{8.3145\frac{J}{mol\ K}}]\times (\frac{1}{373.15} - \frac{1}{323.15})=2.0297$$

$$\ln P_2 - \ln (1\ atm) = 2.0297\]

$$P_2=7.612\ atm\]

S39a

\(T_1 = (61 + 273.2)K = 334.2\ K\)

\(T_2 = (108.7 + 273.2)K = 381.9\ K\)

\(ln(\frac{P1}{P2}) = \frac{\Delta H_{vap}}{R}\times (\frac{1}{T_1} - \frac{1}{T_2})\)

\(\Delta H_{vap}= \frac{[-R\times ln (\frac{P1}{P2})]}{(\frac{1}{T_1} - \frac{1}{T_2})}\)

\(ln(\frac{12.0mmHg}{120 mmHg})=\frac{\Delta H_{vap}}{8.3145\frac{J}{mol\ K}}\times (\frac{1}{381.9}- \frac{1}{334.2})\)

\(\Delta H_{vap}=5.122\times 10^4 \frac{J}{mol}\)

S39b

\(T_1=(63+ 273.2)= 336.2K\)

\(T_2=(115+ 273.2)= 388.2K\)

\(ln(\frac{16}{136})=\frac{\Delta H_{vap}}{8.3145\frac{J}{mol\ K}}\times (\frac{1}{388.2}-\frac{1}{336.2})\)

\(\Delta H_{vap}= 44.7\ \frac{kJ}{mol}\)

S39c

\(25\ mmHg=25\ mmHg\times \frac{1atm}{760\ mmHg} = 0.03289atm\)

\(84\ mmHg=84\ mmHg \times \frac{1atm}{760\ mmHg} = 0.1105atm\)

\(ln(\frac{0.1105}{0.03289})= \frac{\Delta H_{vap}}{8.314 \frac{J}{(K\ mol)}}\times (\frac{1}{311}-\frac{1}{365})\)

\(1.2118= 5.722\times 10^{-5}\Delta H_{vap}\)

\(\Delta H_{vap}=21.2\ \frac{kJ}{mol}\)

S39d

\(T_i=(-92.5+273) K= 180.9K\)

\(T_f=(-42.1+273.2) K= 231.1 K\)

\(ln(\frac{40.0mmHg}{760mmHg}) = \frac{\Delta H_{vap}}{8.3145\frac{J}{mol\ K}}(\frac{1}{231.1K} – \frac{1}{180.9 K})\)

\(-2.944=-1.44\times 10^{-4} \Delta H_{vap}\)

\(\Delta H_{vap}= 2.04\times 10^4 \frac{J}{mol}= 20.4 \frac{kJ}{mol}\)

S39e

• \(T_1=(49℃+273.15\;K)= 322.15\; K\)
• \(T_2=(4.5℃+273.15\;K)= 277.65 \;K\)

\(ln (\frac{2854.66 mmHg}{155.14 mmHg}) = \dfrac{∆H_{vap}}{(8.3145 \frac{J}{mol\ K})} \times (\frac{1}{277.65 K} - \frac{1}{322.15 K})\)

\(2.91=5.98\times 10^{-5}\Delta H_{vap}\)

\(\Delta H_{vap} = 4.866 \times 10^4\ \frac{J}{mol} = 48.66\ \frac{kJ}{mol}\)

S39f

\(ln(\frac{P_2}{P_1})= \frac{\Delta H_{vap}}{R}\times (\frac{1}{T_1}-\frac{1}{T_2})\)

\(\Delta H_{vap}=ln(\frac{10.0mmHg}{80.0mmHg})\times \frac{(8.3145\frac{J}{mol\ K})}{(\frac{1}{56.0+273K}- \frac{1}{25.0+273K})}\)

\(\Delta H_{vap}=54.7\ kJ\)

S41b

\(T_1=(78.37^oC+273.15)= 400.52 K\)

\(ln(\frac{760 mmHg}{335 mmHg})= \frac{38.6\times 10^3 \frac{J}{mol}}{(8.3145\frac{J}{mol\ K})}\times (\frac{1}{T}-\frac{1}{400.52 K})=0.819\)

\(\frac{1}{T}- \frac{1}{400.52 K}= \frac{0.819\times 8.3145 \frac{J}{mol\ K}}{38.6\times 10^3 \frac{J}{mol}}\)

\(\frac{1}{T}-\frac{1}{400.52 K}=1.764\times 10^{-4}\)

\(\frac{1}{T}=\frac{1}{400.52 K}+1.764\times 10^{-4}\)

\(T=374.09\ K\)

S43a

\(ln(\frac{77.5atm}{P_1})=\frac{38\times 10^3 \frac{J}{mol}}{8.314\frac{J}{mol\ }}\times (\frac{1}{378}-\frac{1}{513})\)

\(ln(\frac{77.5}{P_1})=3.1820\)

\(\frac{77.5}{P_1}=24.09\)

\(P_1=3.22atm\)

S43c

\(ln(\frac{P_1}{P_2}) = \frac{\Delta H_{vap}}{R}\times (\frac{1}{T_1} - \frac{1}{T_2})\)

\(ln(\frac{0.28atm}{1.1atm}) =\frac{\Delta H_{vap}}{8.3145\frac{J}{mol\ K}}\times (\frac{1}{353.2}- \frac{1}{313.2})\)

\(\Delta H_{vap}= \frac{R \times ln(\frac{P_1}{P_2})}{(\frac{1}{T_1} - \frac{1}{T_2})}\)

\(\Delta H_{vap} = 31.4\ \frac{kJ}{mol}\)

S43d

\(T_1=(113.5+273.2) K = 386.7 K\)

\(T_2=(380+273.2) K = 653.2 K\)

\(ln(\frac{P_2}{P_1})= \frac{\Delta H_{vap}}{R} \times (\frac{1}{T_1}-\frac{1}{T_2})\)

\(ln(\frac{145.4}{1})=\frac{\Delta H_{vap}}{8.3145\frac{J}{K\ mol}}\times (\frac{1}{386.7K} – \frac{1}{653.2K})\)

\(\Delta H_{vap}= 39.2 \frac{kJ}{mol}\)

\(ln(\frac{1}{P})= \frac{39,200\frac{J}{mol}}{8.3145\frac{J}{mol\ K}}\times (\frac{1}{373.2K} – \frac{1}{386.7K})\)

\(P= 0.44103\ atm\)

S47b

\(Melting\ point\ of\ Al=933.5K\)

\(\Delta H_{fus}\ Al=10.7 \frac{kJ}{mol}\)

\(d=2.7\frac{g}{cm^3}\)

2.37kg of molten aluminum freezes can 64x12x10

1. heat evolved = \( (2.37kg\ Al )(\frac{1000g}{1kg})(\frac{1mol\ Al}{26.98g})(\frac{10.7kJ\ Al}{1mol\ Al})= 939.92\ kJ\)
2. heat absorbed= \( (64\times 12\times 10)(\frac{2.7g}{1cm^3})(\frac{1mol\ Cu}{26.98g})(\frac{10.7kJ\ Al}{1mol\ Al})= 8.2\times 10^{23} kJ\)

S53b

1. \(0.037atm\times (\frac{760mmHg}{1atm})= 28.3mmHg\)
2. \(1atm\times (\frac{760mmHg}{1atm}) = 760mmHg\)
3. \(0.77atm\times (\frac{760mmHg}{1atm}) =588.6mmHg\)

Utilizing the table of Vapor pressure of water at various temperatures in the text book

a) 28.0˚C

b)100.0˚C

c) 93.0˚C

S53c

\(0.360\ g\ of\ H_2O = 0.0199\ mol\)

(a)

40 ˚C, vapor pressure of \(H_2O = 52.8\ mmHg = 0.0694\ atm\)

\(n=\frac{PV}{RT}= \frac{0.0694atm\times 4.20L}{0.0820\frac{L\ atm}{mol\ K} \times 313.2 K}\)

\(n= 0.0113\ mol\)

0.0113 mol of water vapor is less than 0.0199 mol of water there for not all of the water evaporates.

(b)

60 ˚C, vapor pressure of \(H_2O = 122.6\ mmHg = 0.1613\ atm\)

\(n=\frac{PV}{RT}=\frac{0.1613atm\times 4.20L}{0.08206\frac{L\ atm}{mol\ K}\times 333.2K}\)

\(n= 0.0248\ mol\ H_2O\ vapor\)

Since 0.0248 mol > 0.0199 mol,

\(P=\frac{nRT}{V} =\frac{0.0199\ mol\times 0.08206\frac{L\ atm}{mol\ K}\times 333.2K}{4.20L}= 0.130\ atm\)
(c)

80˚C, vapor pressure of \(H_2O = 150.4\ mmHg = 0.198\ atm\)

All water evaporates as seen in part (b) so

\(P=\frac{nRT}{V} =\frac{0.0199\ mol\times 0.08206\frac{L\ atm}{mol\ K}\times 353.2K}{4.20L}= 0.137\ atm\)

S53e

a)

\(0.350g\ H_2O_{(l)}\times \frac{1\ mol\ H_2O}{18.0g H_2O} = 0.0195\ mol\ H_2O\)

\(55.3mmHg\times \frac{1\ atm}{760mmHg} = 0.0728\ atm\)

\(PV=nRT\)

\(n = \frac{(0.0728\ atm)(4.10\ L)}{0.08206 \frac{L\ atm}{mol\ K}\times (313.15 K)}\)

\(n = 0.0116\ mol\ H_2O\)

→ 0.0116 mol < 0.0195 mol

→ P =0.0728 atm

b)

\(149.4mmHg\times \frac{1 atm}{760mmHg} = 0.1966\ atm\)

\(PV=nRT\)

\(n = \frac{(0.1966 atm)(4.10 L)}{0.08206 \frac{L\ atm}{mol\ K}\times (333.15 K)}\)

\(n = 0.0295\ mol\ H_2O\)

→ 0.0295 mol > 0.0195 mol

Thus,

\(P = \frac{nRT}{V} = \frac{0.0195 mol\times 0.08206\frac{L\ atm}{mol\ K} \times 333.15 K}{4.10\ L}\)

\(P = 1.300\ atm\)

c)

\(P = \frac{nRT}{V} = \frac{0.0195 mol\times 0.08206\frac{L\ atm}{mol\ K} \times 363.15 K}{4.10\ L}\)

\(P = 1.417\ atm\)

S53f

0.696 g sample corresponds to 0.0386mol of \(H_2O\).

\(P=\frac{nRT}{V} = \frac{0.0386mol\times 0.08206\frac{L\ atm}{mol\ K}\times 365.2K}{7.8\ L} = 0.148 atm\)

S57B

a)

heat lost by water:

\(Q_w = m\times c\times \Delta T\)

\(Q_w=(120)(4.185\frac{J}{g^oC})(0-22^0C)(\frac{1kK}{1000J})= -11.04kJ\)

\(\Delta H_{condensation} = -\Delta H_{vaporization}\): heat lost= heat loss of condensation and cooling

\(Q_{steam}=(158)(4.185\frac{J}{g^oC})(0-100^0C)(\frac{1kK}{1000J}) + (158)(\frac{1mol}{18.015g})(-40.7\frac{kJ}{1mol})- 356.96= -423kJ\)

\(Total\ energy\ to\ melt\ ice= Q_w+Q_{steam} =-11.04+-423= -434.04kJ\)

\(moles\ of\ ice\ melted= 434.04\times \frac{1}{6.01}=72.22\ mol\)

\(mass\ of\ ice\ melted= (72.22)(\frac{18.015}{1})(\frac{1}{1000})= 1.3 kg\)

\(mass\ unmelted\ ice= 1.73-1.3= 0.43 kg\)

b)

\(heat\ required\ to\ melt\ ice = n \Delta H_{fus}\)

\(heat\ required =(0.43kg)(\frac{1000g}{1kg})(\frac{1mol}{18.015g})(\frac{6.01kJ}{1mol})= 143.45\ kJ\)
\(heat\ per\ 1\ mol\ H_2O= (-4.07\frac{kJ}{1mol})+(18.015)(4.18)(0-100^oC) (\frac{1kJ}{1000J}) = -40.7kj- 7.53kj= -48.2\frac{kJ}{mol}\)

\(mass\ steam\ required =(143.45)(\frac{1}{48.2})(\frac{18.015g}{1mol})= 53.62g\ steam\)

S59a

By exposing graphite to high pressure and a comparatively low temperature, the carbon atoms can bond to form a crystalline solid structure, where each atom is bonded to four others. The covalent bonds become extremely strong and thus make diamond one of the hardest solids.

http://chemwiki.ucdavis.edu/Physical_Chemistry/Physical_Properties_of_Matter/Solids/Network_Covalent_Solids

S59b

Yes. \(-\Delta H_{fus}\) (freezing) is an exothermic reaction, therefore, the freezing water on the plants means that heat is being released. Thus, keeping your sprinklers on will keep the plants warm.

S59c

The reason for this is because it contains the solute carbon dioxide, along with the solvent water. When carbon dioxide is dissolved into water the freezing point gets lowered. When you open the bottle there is a pressure difference between the inside of the can and the outside and the pressure lowers and this leads to carbon dioxide to leave. This then creates the freezing temperature to increase because the carbon dioxide is leaving. The temperature is getting colder so the beer gradually freezes from the top of the beer to the bottom.

S59d

The liquid in the container is superheated, which is when a liquid is heated to a temperature higher than it’s boiling point. The larger the bubbles in the liquid, the lower the surface tension, causing the liquid to expand explosively and boil over.

S61a

\(ln(\frac{1}{0.29}) = \frac{4.18\times 1000}{8.3145}(\frac{1}{194} – \frac{1}{T_{boiling}})\)

\(T_{boiling} = 371\ K = 98.4\ ^oC\)

S61b

If the free energy of the product is less than the free energy of the reactant, then the product is considered stable. Converting diamond to graphite, the free energy is positive meaning diamonds are higher in energy than graphite. Therefore diamond is unstable. Because diamond is unstable, it eventually turns into graphite over millions of years.

S61c

You would expect a diamond to have a higher density when compared to graphite, because unlike graphite that has \(sp^2\) sheets held together by p orbitals, diamonds form \(sp^3\) bonds resulting high in its strength. P bonds does not form strong bonds, which causes these sheets in graphite to be easily broken by sheer force.

S63a

If silicon atoms are substituted for half the carbon atoms in a diamond crystal structure, the resulting structure is that of silicon carbide. Carbon atoms can bond together to produce a solid with properties different than that of diamonds. Like graphite, boron nitride, involves the orbital set \(sp^2 + p\).

S63b

in order, ionic, molecular, covalent network, metallic.

S63c

B and N must have \(sp^2\) hybridization

S67

\(KCl\) because it is the easiest to scratch.

S69a

One arrangement is hexagonal closest packed (HCP) in which the third layer has the same arrangement of spheres as the first layer and covers all the tetrahedral holes. Thus, the stacking for HCP is “ababab” because the structure repeats itself after every two layers. The other arrangement is cubic closest packed (CCP) which is similar to the HCP, since the second layer of spheres is placed on to half of the depressions of the first layer. However, the spheres in the third layer do not line up with those of layer A. Thus, the arrangement of layers is “abcabc”.

S69b

There can be 2 because in one layer has 6 spheres touching one spheres. 2^nd layer is placed on top of 1^st layer by placing spheres in the hole of 1^st. 3^rd layer is placed on top of those two. The closest packing arrangement abab results, when one see a sphere of the bottom first layer. No first layer is visible through the indentation; the closest packing arrangement abcabc results.

S69c

Cubic Close Packed and Hexagonal Closed Packed maximize the density of packing spheres because they are both include sheets of spheres arranged as a triangle at the vertices. In both cases, each sphere has 12 neighbors. Each sphere will have 3 gaps that are empty and decrease the density of the packed spheres. For one gap, surrounded by spheres in an octahedral configuration, the distance to the center of the gap from the center of the sphere is \(\sqrt2\) times the radius of the sphere. For the other two gaps, surrounded by spheres in tetrahedral configurations, the distance to the center of the gap from the center of the sphere is \(\sqrt{\frac{3}{2}}\) times the radius of the sphere. By minimizing the empty space, 74% of the space is filled, thus maximizing the density.

S71a

Crystal structures occur whenever there is a regular pattern of atoms, ions, or molecules. A unit cell is the smallest representation of an entire crystal, and all crystal lattices are built of repeating unit cells. The simple cubic has a coordination number of 6 and contains 1 atom per unit. The body centered cubic (BCC) has a coordination number of 8 and contains 2 atoms per unit cell. The face centered cubic (FCC) has a coordination number of 12 and contains 4 atoms per unit cell. The hexagonal closest packed (HCP) has a coordination number of 12 and contains 2 atoms per unit cell. Lastly, the cubic closest packed (CCP) has a coordination number of 12 and contains 4 atoms per unit cell.

S71b

1. Smallest repeated unit of crystal lattice. Grey squares, open circles, and colored diamonds
2. 1 light colored sq, 2 circles, 1 dark colored diamond

S71c

(a)6 (b)8 (c)12 (d)12

S73a

\(molar\ mass\ of\ Fe = 55.85 \frac{g}{mol}\)

\( \frac{(55.85\frac{g}{mol})}{(6.02\times 10^{23})} = 9.277\times 10^{-23} \frac{g}{unit cell}\)

\(L = \frac{4r}{\sqrt3}\)

(substitute radius (in cm) into equation to get the length of one side)

\(L = \frac{4(1.5\times 10^{-8})}{\sqrt3}\)

\(L = 3.46\times 10^{-8}\)

\(Volume = L^3\)

So, \(Volume = 4.16\times 10^{-23}\ cm^3\)

Now that you have mass and volume, you are able to calculate density using \(D =\frac{M}{V}\)

\(D = \frac{(9.277\times 10^{-23})}{(4.16\times 10^{-23})}\)

\(D = 2.23\frac{g}{cm^3}\)

http://chemwiki.ucdavis.edu/Physical_Chemistry/Physical_Properties_of_Matter/Solids/Virtual%3a_Crystal_Structure/Unit_Cells/Body_Centered_Cubic

S73b

\(S=\frac{4(98meters)}{3^{\frac{1}{2}}}\)

\(S=226.3213055\ meters\)

\(D=\frac{M}{V}\)

\(D= \frac{55.845g}{(226.3213055\ m)^3}\)

\(D= 4.8\times 10^{-6} \frac{g}{m^3}\)

S73c

\(V = (\frac{4r}{\sqrt3})^3\)

\(V= (\frac{4\times 150\ pm \times \frac{100cm}{10^{12}\ pm}}{ {\sqrt3}})^3 = 4.157\times 10^{-23}\ cm^3\)

\(M=(\frac{2W\ atoms}{1unit cell})(\frac{1mol\ W}{6.022\times 10^{23}\ W\ atoms})(\frac{183.85g\ W}{1mol\ W})\)

\(M=6.106\times 10^{-22}\)

\(Density=\frac{Mass}{Volume}\)

\(D= \frac{6.106\times 10^{-22}}{4.157\times 10^{-23}\ cm^3} =14.69\frac{g}{cm^3}\)

S73d

\(M = (\frac{1\ atom}{unit\ cell}) (\frac{209g}{mol}) (\frac{mol}{6.022\times 10^{23} atoms}) = 3.47\times 10^{-22}\ g\)

\(135pm (\frac{1m}{10^{12}pm}) (\frac{100cm}{1m}) = 1.35\times 10^{-8}cm\)

\(V=L^3 = (2r)^3= (2\times 1.35\times 10^{-8} cm)^3 = 1.97\times 10^{-23} cm^3\)

\(D = \frac{M}{V} = \frac{3.47\times 10^{-22}\ g}{1.97\times 10^{-23} cm^3} = 17.6 \frac{g}{cm^3}\)

S73e

In order to calculate the density, calculate the volume of Iron. We know that the length of one side of this structure is equal to \(\frac{4r}{\sqrt3}\)

So, \(\frac{4(124)}{\sqrt3}= 286.3657 pm\).

Before calculating the volume, convert 286.3657 pm into cm.

\(286.3657\times \frac{(1 m)}{10^{12} pm}\times \frac{(100 cm)}{(1 m)}= 2.863657\times 10^{-8}\)

\(Volume= (2.863657\times 10^{-8})^3= 2.348351\times 10^{-23}\)

Now, calculate the mass in grams of Iron per unit cell. Since BCC packing structure implies to atoms per unit cell, this can be done be calculating the mass of one iron atom and multiplying by 2.

\(\frac{Mass\ of\ iron}{unit\ cell}= 2\times \frac{(1\ mol\ Fe)}{(6.022X10^{23})}\times \frac{(55.845 g)}{(1\ mol\ Fe)}=9.2735\times 10^{-23}\)

Finally, to find the density of iron, just divide the mass per unit cell by volume per unit cell.

\(Density= \frac{9.2735\times 10^{-23}}{2.348351\times 10^{-23}}= 3.9489 \frac{g}{cm^3}\)

S75a

a) length of a body-centered cubic unit cell = \(\frac{4r}{\sqrt3}\)

distance between neighbors = length of unit cell = \(395 pm = 3.95\times 10^{-10}\ m\)

\(3.95\times 10^{-10} = \frac{4r}{\sqrt3}\)

\(r = 1.71\times 10^{-10}\ m = 1.71\times 10^{-8}\ cm\)

b) \(M\ of\ unit\ cell = (22.99\frac{g}{mol})(\frac{1\ mol}{6.022\times 10^{23}\ atoms})(\frac{2\ atoms}{unit\ cell})\)

\(= 7.64\times 10^{-23}\frac{g}{unit\ cell}\)

\(V\ unit\ cell = \frac{64r^3}{3^{3/2}} = \frac{64(1.71\times 10^{-8}\ cm)^3}{3^{3/2}} = 6.16\times 10^{-23}\ cm^3\)
\(D = \frac{M}{V}= \frac{7.64\times 10^{-23}}{6.16\times 10^{-23}} = 1.24\frac{g}{cm^3}\)

c) \(n\times L = 2\times d\times sin(x)\)

\((0.23)(3.43\times 10^{-9}) = 2(3.95\times 10^{-10} m)sin(x)\)

\(x = 1.52 radians\)

S75b

1. Diameter of Po=400 pm
2. \(Unit\ cell=(400pm)^3=6.4\times 10^7 pm^3=6.4\times 10^{-23} cm^3\ per\ unit\ cell\) \[\rho=\dfrac{M}{V}=\dfrac{3.47 \times 10^{-22}\;g}{6.4 \times 10^{-23}\; cm^3}=5.42\; g/cm^3\]
3. \(n=1\), \(d=400pm\) and \(wavelength=180.0pm\)

\(sin(\Theta)=\frac{n\times gamma}{2d}=\frac{(1)(1.8\times 10^{-10})}{2(400\times 10^{-12})}=0.225\)

\(\Theta=13^o\)

S75c

\(\pi=\lambda\)

a)

\(V\ per unit\ cell= L^3=(4.09\ Å)^3= 68.418\ Å = 6.84\times 10^{-7}\ cm^3\)

\(M\ per unit\ cell= \frac{(107.868 g)}{(1\ mol)}\times \frac{(1\ mol)}{(6.022\times 10^{23}\ atoms})= 1.791\times 10^{-22} \frac{g}{atom} \times 2=3.582\times 10^{-22}\frac{g}{unit cell}\)

\(Density= \frac{3.582\times 10^{-22}}{6.84\times 10^{-7}}= 5.5285\times 10^{-16}\frac{g}{cm^3}\)

b)

\(n= 1\), \(d=4.09\), \(\pi=1.5\times 10^{-10}\)

\(sin\Theta = \frac{1.5\times 10^{-10}}{2(4.09\times 10^{-10}\ Å)}\)

\(\Theta= 10.566^o\)

S75d

\(L=r\sqrt8\)

\(L= 144\sqrt8\)

\(L= 407\ pm\)

\(V=(407)^3 = 6.7\times 10^7\ pm^3\)

\(6.7\times 10^7\ pm^3 \times (\frac{1m}{1\times 10^{12}pm})^3\times (\frac{100cm}{1m})^3 = 6.7\times 10^{-23} cm^3\)

\(Mass\ of\ the\ unit\ cell\ (uc) = (\frac{4\ atoms}{uc})(\frac{196.67g}{mol})(\frac{mol}{6.022\times 10^{23}}) = 1.31\times 10^{-21}\ g\)

\(D = \frac{M}{V} = \frac{(1.31\times 10^{-21}g)}{(6.7\times 10^{-23}cm^3)}= 19.4\frac{g}{cm^3}\)

\(n\lambda= d(sin 20°)\)

\((1)(5 nm) = d(sin 20°)\)

\(d = 0.068 nm= 68 pm\)

S79a

We expect from the radius ratio inequalities that the \(Cs^+\) ion will occupy a cubic hole in a simple cubic lattice of \(Cl^-\) ions. This unit cell is in accord with one to one ratio of \(Cs^+\) to \(Cl^-\) ions since there is one \(Cs^+\) in the center of the unit cell and \(8\times (\frac{1}{8})\ Cl^-\)ions at the corners.

S79b

\(TiO_2\): 8 \(Ti^{4+}\) ions on the corners, shared among 8 unit cells, 1 \(Ti^{4+}\) corner ion per unit cell, There is 1 in the center contained within the unit cell. There is also 2 \(O^{2-}\) on the faces, shared between two unit cells, 2 face atoms per unit cells. 2 \(O^{2-}\) ions within the unit cell. It totals to 4 \(O^{2-}\) ions per unit cell. The ratio of Ti and O is 2\(Ti\) per 4\(O^{2-}: Ti_2O_4\).

S79c

• \(MgCl_2\): In each of the eight corners there are \(Mg^{2+}\) ions, which are shared among eight unit cells, for a total of one \((8\times \frac{1}{8})\) ion per unit cell. There are also six \(Mg^{2+}\) ions on each face of the unit cell, for a total of three \((6\times \frac{1}{2})\) ions per unit cell. This altogether gives a total on 4 \(Mg^{2+}\) per unit cell. There are eight \(Cl^-\) ions contained within the unit cell. This gives a ratio of 4 \(Mg^{2+}\) ions to 8 \(Cl^-\) ions, or \(MgCl_2\).
• \(MnO_2\): In each of the eight corners there are \(Mn^{2+}\) ions, which are shared among eight unit cells, for a total of one \((8\times \frac{1}{8})\) ion per unit cell. There is also one \(Mn^{2+}\) ion in the center of the unit cell. Therefore, there are a grand total of two \(Mn^{2+}\) ions per unit cell. There are four \(O^{2-}\) ions on four faces of the unit cell, each of which is shared between two unit cells, for a total of two \((4\times \frac{1}{2})\) atoms per unit cell. There are an additional two \(O^{2-}\) ions completely contained within the unit cell. This gives a grand total of four \(Mn^{2+}\) ions per unit cell. Thus, the ratio is two \(Mn^{2+}\) ions to four \(O^{2-}\) ions, or \(MnO_2\).

S81a

a) In a face-centered cubic unit cell, there are six anions around each cation, and six cations surrounding each anion. Therefore, the coordination number of \(Li^+\) and \(F^-\) is 6.

b) There is a fluoride ion at each of the eight quarters, in the unit cell; each of which is shared with the eight surrounding unit cells. There is also one fluoride ion on each of the six faces; each is shared between two unit cells. Thus, the total number of fluoride ions

\(= (8\times \frac{1}{8})+(6\times \frac{1}{2})=3\ F^-\ ions\)

There are twelve edges on the unit cell, each of which has a lithium ion on it, and each of these is shared between four unit cells. There is also a lithium ion completely contained within the unit cell. Thus, the total number of lithium ions

\(= (12\times \frac{1}{4}) + 1 = 4\ Li^+\ ions\)

Thus, there are four formula units per unit cell of \(LiF\).

c) Along the edge of the unit cell, combined, there is one \(Li^+\) and one \(F^-\) ion. Therefore the length of the unit cell is \(2\times Li^+\ radius+2\times F^-\ radius=(2\times 59)+(2\times 133)=384pm\)

Since the unit cell is a cube, the volume of the unit cell is the length cubed,

\((384\ pm)^3 = 5.66\times 10^7\ pm\)

d) \(5.66\times 10^7pm \times (\frac{1m}{10^12pm})^3 × (\frac{100 cm}{1m})^3= 5.66\times 10^{-23}\ cm^3\)

\(D=\frac{M}{V}= \frac{4\ LiF\ f.u.}{5.66\times 10^{-23}\ cm^3}\times \frac{1\ mol\ LiF}{6.022\times 10^{23}\ f.u.}\times \frac{25.94g\ LiF}{1\ mol\ LiF}=3.04\frac{g}{cm^3}\)

S81b

1. The length of the edge is equal to the radius of 1 \(O\), plus the diameter of \(Mg\), the radius of another 0 edge length\(=2\times O radius+2 mg radius-2\times 140pm+2\times 72 pm=424 pm\) \(V=(424\ pm)^3= 7.62 \times 10^7\ pm^3\times (\frac{1m}{10^{12}\ pm})^3 \times (\frac{100\ cm}{1\ m})^3=7.62 \times 10^{-23}\ cm^3\)
2. \(\rho = \frac{m}{V}=\frac{4MgO\ formula\ unit}{7.62\times 10^{-23}\ cm^3}\times \frac{1mol\ MgO}{6.022\times 10^{23}\ formula\ units}\times \frac{40.3g\ MgO}{1mol\ MgO}=3.51\frac{g}{cm^3}\)
3. \(Mg\) is 6 and \(O\) is 6
4. \(Total\ Oxide\ ion=8\ corners\times \frac{1\ oxide\ ion}{8\ unit\ cell}+6\ faces \times \frac{1\ oxide\ ion}{2\ unit\ cells}= 4\ O\ ions\)

\(Total\ Mg\ ions=12\ adjoining\ cell\times \frac{1\ magnesiumion}{4\ unit\ cells}+central\ Mg\ ion=4\ Mg\ ions\)

S81c

\(BCC = 2\frac{atoms}{unit\ cells}\)

\(m = (\frac{2\ atoms}{unit\ cells})(183.8\frac{g}{mol})(\frac{1\ mol}{6.022\times 10^{23}\ atoms}) = 6.104\times 10^{-22}\ g\)

\(V= L^3 = (\frac{4r}{3^0.5})^3 = (\frac{(4)(140.8\times 10^{-10}cm)}{(3^0.5)})^3 = 3.43\times 10^{-23}\ cm^3\)

\(r = 140.8pm = 140.8\times 10^{-12}m = 140.8\times 10^{-10}\ cm\)

\(d = \frac{m}{V} = \frac{6.104\times 10^{-22}\ g}{3.43\times 10^{-23}\ cm^3} = 17.8 \frac{g}{cm^3}\)

S83a

\(Length = (rCl^-) + (rNa^+) + (rNa^+) + (rCl^-)= 2(rNa^+) + 2(rCl^-) = (2\times 99) +(2\times 181) = 560pm\)

S83b

1. Radius ratio= \(\frac{99pm}{181pm}= 0.547\) = Cations occupy octahedral holes of an fcc array of anions.
2. Radius ratio= \(\frac{72pm}{184pm}= 0.3913\) = cations occupy tetrahedral holes of an fcc array of anions.
3. Radius ratio= \(\frac{59pm}{133pm}= 0.44361\) = cations occupy octahedral holes of an fcc array of anions.

S83c

1. \(RbI\) has a \(Rb\) radius =149pm and \(I\) radius = 220pm therefore is face centered cubic.
2. \(CsCI\) has a \(Cs\) radius = 77pm and \(Cl\) radius = 220pm therefore is body centered cubic.
3. \(MgO\) has a \(Mg\) radius = 72pm and \(O\) radius = 140pm therefore is face centered cubic.
4. \(AgCl\) has an \(Ag\) radius = 115pm and \(Cl\) radius = 181pm therefore is face centered cubic.

S83d

1. \(\frac{rLi}{rO2}=\frac{59pm}{128pm}=0.461\) cations are in the octahedral holes of a face centered cubic
2. \(\frac{rCa}{rO}=\frac{100pm}{140pm}=0.714\) cations are in octahedral holes of a face centered cubic
3. \(\frac{rCu}{rCl}=\frac{96pm}{181pm}=0.53\) cations are in octahedral holes of a face centered cubic

S85a

The lattice energy of a compound is found indirectly by using Hess’s Law to cancel out ions and ultimately calculating the desired enthalpy. Step 1: \(\Delta H\) of sublimation of initial solid. Step 2: Dissociation of \(0.5mol\) of 2^nd gas. Step 3: Ionization of \(1mol\) of 1^st gas (previously solid) to proton-donated ion. Step 4: convert \(1mol\) of 2^nd gas to its proton-gained ion. Step 5: Allow the 1^st gas and 2^nd gas to form one mole of newly formed solid.

http://chemwiki.ucdavis.edu/Inorganic_Chemistry/Lattices

S85b

Those lattice energies vary approximately with cation size. More exothermic lattice energy will produce in smaller cation. \(LiCl_{(s)}\) is the most exothermic and \(CsCl_{(s)}\) is the least.

S85c

\(Rxn1 + 2Rxn2 – 2Rxn3\)

\(\Delta H^o_{rxn} = -622.2 kJ + (2\times -285.8 kJ) + (2\times 187.8 kJ) = -818.2 kJ\)

S85d

When the anion is kept constant, one can compare the lattice energy by investigating the size of the cation. The smaller the cation, the more energy is capable of being released, causing a more exothermic lattice energy. Therefore, it is evident that \(MgS_{(s)}\) has the most exothermic lattice energy of the series, and \(BaS_{(s)}\) has the most endothermic lattice energy of the series.

S87a

A smaller cation will produce a more exothermic lattice energy.

S87b

\(\Delta H^o_{rxn}=(2\times -258.8)+(1\times -293.5)+(-1\times -890.4)=25.3kJ\)

S87c

\(Mg^+_{(g)} \rightarrow Mg^{2+}_{(g)}+e^-\) \(I_2=1500\frac{kJ}{mol}\)

\(2Mg^{2+}_{(g)}\rightarrow 2Cl^-_{(g)}+2MgCl_{2(s)}\) \(LE=-2526\frac{kJ}{mol}\)

\(Mg_{(s)} \rightarrow Mg_{(g)}\) \(\Delta H_{sub}=146\frac{kJ}{mol}\)

\(Mg_{(s)} \rightarrow Mg^+_{(g)}+e^-\) \(I_1=750\frac{kJ}{mol}\)

\(Cl_{2(g)} \rightarrow 2Cl_{(g)}\) \(DE=(2\times 122)\ \frac{kJ}{mol}\)

\(2Cl_{(g)}+2e^- \rightarrow 2Cl^-_{(g)}\) \(2\times EA=2(-349)\ \frac{kJ}{mol}\)

\(\Delta H_f=\Delta H_{sub}+I_1+I_2+DE+(2\times EA)+LE=146+750+1500+244-698-2526-645\)

The example of 12-12, \(\Delta H_f\) for \(MgCl\) is \(19\frac{kJ}{mol}\). \(MgCl_2\) is much more stable than \(MgCl\), since it has more energy release when it form \(MgCl_{2\ (s)}\) is more stable than \(MgCl_{(s)}\).

S89a

Under these conditions snow does not melt but sublimes. The solid has a vapor pressure of ice at 0°C is 4.58 mmHg. If the air is not already saturated with water vapor, the ice will sublime.

S89b

The candle has cotton thread surrounded by paraffin which is a heavy chain hydrocarbon and hence initially in the solid phase. When the cotton thread is lighted, the tip starts to burn and the heat melts the paraffin into a liquid phase. The liquid of hydrocarbons enter into the fibers of the cotton thread. The hydrogen carbons end up vaporing and finally burn out giving out carbon dioxide and water vapor.

$$C_nH_{2n(l)} + O_{2(g)} \rightarrow nCO_{2(g)} + H_2O_{(g)}\]

S89c

When wood is burned, oxygen from the air reacts with various hydrocarbons in the wood, forming carbon dioxide, steam and some other chemicals. The overall process is exothermic and involves no liquid stage.

S89d

When the ice reaches \(0^oC\) it phase changes from solid ice to liquid water. As the water continues to boil, the liquid water will transform into vapor gas once \(100^oC\) is reached. At \(0^oC\) this is enthalpy of condensation and at \(100^oC\) this is called enthalpy of vaporization.

S92a

Heat required to raise the temperature of ice

=\((13.0g)\times \frac{(2.09\ J)}{(g°C)}\times (0--10)°C=271.7\ J\)

Heat required to convert ice to liquid water

=\((13.0g)\times \frac{334\ J}{g}= 4342\ J\)

Heat required to raise the temperature of water

=\((13.0g)\times \frac{4.18\ J}{g°C}\times (100- -0)°C=5434\ J\)

Heat required to convert water to steam

=\((13.0g)\times \frac{2257J}{g°C}= 29341\ J\)

Heat required to raise the temperature of water

=\((13.0g)\times \frac{(2.09\ J)}{(g°C)}\times (105- -100)°C=135.85\ J\)

Sum together all the heats

=\(271.7J+4342J+5434J+29341J+135.85J=39524.55J\)

S92b

Specific heat : \(Mercury_{(s)}= 0.121\frac{J}{g°C}\)

\(Melting (mp= 38.87°C) = 2.33\ \Delta H^o\ \frac{kJ}{mol}\)
\(Mercury_{(l)} = 0.140\frac{J}{g°C}\)

\(Vaporization = 61.3 \Delta H°\ \frac{kJ}{mol}\)

\(q=mCp\Delta T = (15.0g) (0.121\frac{J}{g°C})(-38.87-(50))= 20.2\ J\)

\(q = n\Delta H_{fus} = (15.0 g) (\frac{mol}{200.59g}) (2330\frac{J}{mol}) = 174\ J\)

\(q=mCp\Delta T = (15.0 g) (0.140\frac{J}{g°C}) (25- (-38.87)) = 134\ J\)

\(q = n\Delta H_{vap} = (15.0 g) (\frac{mol}{200.59g}) (61300\frac{J}{mol}) = 4580\ J\)

\(q\ total = 20.2 + 174 + 134+ 4580 = 4910\ J\)

S92c

\(q= mC\Delta T\) \(q = n\Delta H\)

\(q_1 = (4.2 g)(19.4\frac{J}{g°C})(-34.0 + 54.3°C) = 1654\ J\)

\(moles = (4.2g\ Cl_2)(\frac{1\ mol}{70.9\ g}) = 0.0592\ mol\ Cl_2\)

\(q_2= (0.592 mol)(4.90\frac{kJ}{mol}) = 0.290\ kJ = 290\ J\)

\(q_3 = (4.2 g)(14.7\frac{J}{g°C})(20 + 34.0°C) = 3334\ J\)

\(q_{total} = 1654 + 290 + 3334 = 5278\ J\)

S92d

\(Mol\ Hg_{(s)}=\frac{Mass}{atomic\ mass}=\frac{24.0g}{200.59\frac{g}{mol}}=0.120mol\)

\(Heat\ required,\ q_l=mol\times molar\ specific\ heat \times temp\ differ=0.12mol\times 24.3\frac{J.}{mol\ K}\times (-38.7+50^oC)=32.85J\)

\(Heat\ of\ formation= 61.32\frac{kJ}{mol}\)

\(\Delta H_{sub}=\Delta H_{fus}+\Delta H_{vap}=2.33+61.32=3.65kJ\)

\(Heat\ required, q_2=mol\times \Delta H_{sub}=0.12\times 63.65\frac{kJ}{mol} \times \frac{10^3J}{1kJ}=7638\ J\)

\(Heat\ required, q_3=mass\times specific\ heat\times temp\ diff=24.0g\times 0.104\frac{J}{g^oC} \times (33+38.7^oC)=178.96J\)

\(Total\ heat\ required=q_1+q_2+q_3=32.85+7638+178.96=7849.81J\)

S94a

\(Mass\ of\ C_2H_5OH\ when\ there\ is\ 2.5g\ of\ Instant\ Car\ Kooler=\frac{10}{100}\times 2.5g=0.25g\)

\(Heat\ absorbed\ by\ 0.25g\ ethanol=0.25g\times \frac{1mol}{46.07g}\times 42.6\frac{kJ}{mol}\times \frac{10^3J}{1kJ}=231.17J\)

\(Average\ volume\ of\ a\ car=100ft^3\times (\frac{12in}{1ft})^3\times (\frac{2.54cm}{1in})^3=2.83\times 10^6\ cm^3\)

\(Approximate\ density\ of\ air\ at\ this\ temperature=1.067\frac{kg}{m^3}\times \frac{10^3g}{1kg}\times (\frac{1m}{10^2cm})^3=0.00107\frac{g}{cm^3}\)

\(Approximate\ mass\ of\ air\ in\ a\ car=D\times V= 0.00107\frac{g}{cm^3}times (2.83\times 10^6cm^3)=3028.1g\)

\(Mol\ of\ air=\frac{M}{average\ molar\ mass}=\frac{3028.1g}{28.97\frac{g}{mol}}=104.52\ mol\)

\(Heat\ capacity\ of\ air=36\frac{J}{mol\ K}\)

\(Heat=mol\ of\ air\times specific\ heat\ capacity\times temp\ difference\)

\(231.17J=104.52mol\times 36\frac{J}{mol\ K}\times (75-T_f^oC)\)

\(T_f=74.73^oC\)

S94b

\(q=mCp\Delta T= (50.0 g) (4.184 \frac{J}{g\ °C}) (100 – 25) = 15690\ J\)

\(q = n\Delta H_{vap}= (50.0 g) (\frac{mol}{18.02\ g}) (44\times 10^3 \frac{J}{mol}) = 122086.57\ J\)

\(q=mCp\Delta T= (50.0 g) (2.08\frac{J}{g\ °C}) (110 – 100) = 1040\ J\)

\(q\ total = 15690 + 122086.57 + 104 J= 1.39\times 10^5\ J\)

S94c

Past the critical point, no phase boundaries exist.

S110a

Only the center atoms belong entirely to the bcc unit cell. Only \(\frac{1}{8}^{th}\) of each corner atoms on the cell belongs entirely to the unit cell. So the 8 corner atoms only equal 1 atom. By that, the total number of atoms is then only 2. \([1 + (8\times (\frac{1}{8}))]\)

http://chemwiki.ucdavis.edu/Physical_Chemistry/Physical_Properties_of_Matter/Solids/Virtual%3a_Crystal_Structure/Unit_Cells/Body_Centered_Cubic

S110b

\(1\ mol\ Mg = 6.022\times 10^{23}\ atoms = 24.32\frac{g}{mol}\ Mg\)

\(m= 1\ atom\ Mg\ atoms \times \frac{24.32g\ Mg}{6.022\times 10^{23}\ Mg\ atoms} = 4.04\times 10^{-23}\ g\ Mg\)

\(V= L^3= (409 pm\times \frac{10^3}{10^9})^3 cm^3= 6.84\times 10^{-11}\)

\(Density\ of\ Mg=\frac{mass}{volume} = \frac{4.04\times 10^{-23}\ g\ Mg}{6.84\times 10^{-11}\ cm^3}\)

\( = 5.9\times 10^{-13}\frac{g}{cm^3}\)

S110c

\(\rho = \dfrac{m}{V}\)

\(m = (2 \frac{atoms}{unit cell}) (\frac{1\ mol}{6.02\times 10^{23}\ atoms})(50.94 \frac{g}{mol})\)

\(V = L^3 = (4r\sqrt3)^3\)

\(6.11\frac{g}{cm^3} = (1.61918\times 10^{-22}\ g)(12.32r^3)\)

\(r = 131\ pm\)

S110d

\(Radius=128pm\)

\(Diagonal\ of\ the\ face=4r=4(128)=512pm\)

\((512pm)^2=L^2+1^2\)

\(L=362 pm\)

\(ratio\ volume\ to\ unit\ cell\ volume=\frac{Vol\ sphere}{Vol\ unit\ cell}=\frac{4\times (\frac{4}{3})\pi(128pm)^3}{(362pm)^3}=0.7410\)

\(Ratio=1-0.7410=0.2589\)

\(Percent\ FCC=25.89\%\)