Chemistry 116 Fall 2024 Lecture 17 PDF

Summary

This document is Lecture 17 from a Chemistry 116 course for Fall 2024. It focuses on thermochemistry, specifically calorimetry. A periodic table is also included.

Full Transcript

10/7/24

Chemistry 116
Fall 2024
Lecture 17

Focus Area 4A : Thermochemistry
Calorimetry

100 µm

Glaucophane
Na(Na,K,Ca)
Paulingite
2(Mg,Fe) (Al,Si)
3Al23Si 2O242:17 H2O
8O22(OH) Half Dome, Yosemite

1

Seven elements exist at diatomic molecules at standard conditions
1 18
IA VIIIA
1A 8A
1 Periodic Table of the Elements 2
H
Hydrogen
2
IIA
13
IIIA
14
IVA
15
VA
16
VIA
17
VIIA
He
Helium
1.008 2A 3A 4A 5A 6A 7A 4.003
3 4 5 6 7 8 9 10
Li
Lithium
Be
Beryllium
B
Boron
C
Carbon
N
Nitrogen
O
Oxygen
F
Fluorine
Ne
Neon
6.941 9.012 10.811 12.011 14.007 15.999 18.998 20.180
11 12 13 14 15 16 17 18
Na
Sodium
Mg
Magnesium
3
IIIB
4
IVB
5
VB
6
VIB
7
VIIB
8 9
VIII
10 11
IB
12
IIB
Al
Aluminum
Si
Silicon
P
Phosphorus
S
Sulfur
Cl
Chlorine
Ar
Argon
22.990 24.305 3B 4B 5B 6B 7B 8 1B 2B 26.982 28.086 30.974 32.066 35.453 39.948
19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36
K
Potassium
Ca
Calcium
Sc
Scandium
Ti
Titanium
V
Vanadium
Cr
Chromium
Mn
Manganese
FeIron
Co
Cobalt
Ni
Nickel
Cu
Copper
Zn Zinc
Ga
Gallium
Ge
Germanium
As
Arsenic
Se
Selenium
Br
Bromine
Kr
Krypton
39.098 40.078 44.956 47.867 50.942 51.996 54.938 55.845 58.933 58.693 63.546 65.38 69.723 72.631 74.922 78.971 79.904 83.798
37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54
Rb
Rubidium
Sr
Strontium
Y
Yttrium
Zr
Zirconium
Nb
Niobium
Mo
Molybdenum
Tc
Technetium
Ru
Ruthenium
Rh
Rhodium
Pd
Palladium
Ag
Silver
Cd
Cadmium
In
Indium
SnTin
Sb
Antimony
Te
Tellurium
I
Iodine
Xe
Xenon
85.468 87.62 88.906 91.224 92.906 95.95 98.907 101.07 102.906 106.42 107.868 112.414 114.818 118.711 121.760 127.6 126.904 131.294
55 56 57-71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86
Cs
Cesium
Ba
Barium
Hf
Hafnium
Ta
Tantalum
W
Tungsten
Re
Rhenium
Os
Osmium
Ir
Iridium
Pt
Platinum
Au
Gold
Hg
Mercury
Tl
Thallium
Pb
Lead
Bi
Bismuth
Po
Polonium
At
Astatine
Rn
Radon
132.905 137.328 178.49 180.948 183.84 186.207 190.23 192.217 195.085 196.967 200.592 204.383 207.2 208.980 [208.982] 209.987 222.018
87 88 89-103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118
Fr
Francium
Ra
Radium
Rf
Rutherfordium
Db
Dubnium
Sg
Seaborgium
Bh
Bohrium
Hs
Hassium
Mt Ds Rg
Meitnerium Darmstadtium Roentgenium Copernicium
Cn Uut
Ununtrium
Fl
Flerovium
Uup Lv Uus Uuo
Ununpentium Livermorium Ununseptium Ununoctium
223.020 226.025 unknown unknown unknown unknown

57 58 59 60 61 62 63 64 65 66 67 68 69 70 71
Lanthanide
Series La
Lanthanum
Ce
Cerium
Pr Nd
Praseodymium Neodymium
Pm Sm
Promethium Samarium
Eu
Europium
Gd
Gadolinium
Tb
Terbium
Dy
Dysprosium
Ho
Holmium
Er
Erbium
Tm
Thulium
Yb
Ytterbium
Lu
Lutetium
138.905 140.116 140.908 144.243 144.913 150.36 151.964 157.25 158.925 162.500 164.930 167.259 168.934 173.055 174.967
89 90 91 92 93 94 95 96 97 98 99 100 101 102 103
Actinide
Series Ac
Actinium
Th
Thorium
Pa
Protactinium
U
Uranium
Np
Neptunium
Pu
Plutonium
Am Cm
Americium Curium
Bk
Berkelium
Cf
Californium
Es
Einsteinium
Fm
Fermium
Md
Mendelevium
No
Nobelium
Lr
Lawrencium
227.028 232.038 231.036 238.029 237.048 244.064 243.061 247.070 247.070 251.080 257.095 258.1 259.101

© 2014 Todd Helmenstine
sciencenotes.org

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The specific heat is an intensive property

When the heat capacity is divided by the mass, we get an intensive property:

18,140 J Substance Symbol (state) Specific Heat (J/g °C)
cFe = = 0.45 J/ g oC helium He(g) 5.193
(800 g)(50 oC)
water H2O(l) 4.184
ethanol C2H6O(l) 2.376
90,700 J ice H2O(s) 2.093 (at −10 °C)
cFe = = 0.45 J/ g oC water vapor H2O(g) 1.864
(4000 g)(50 oC)
nitrogen N2(g) 1.040
air 1.007
oxygen O2(g) 0.918
q aluminum Al(s) 0.897
c = carbon dioxide CO2(g) 0.853
(m)(DT) argon Ar(g) 0.522
iron Fe(s) 0.449
copper Cu(s) 0.385
q = m c DT lead Pb(s) 0.130
gold Au(s) 0.129
J o silicon Si(s) 0.712
== g C
g oC
Why do gases and liquids have much higher specific heats than metals?

3

Example Problems

1. If a beaker containing 800.0 g of water is heated from 21 oC to 85 oC, what quantity of heat has been added to the
water?
q = m c DT

= (800.0 g) (4.184 J / g oC) (85 oC – 21 oC)

= 214,220 J
= 210,000 J = 210 kJ

2. Suppose a piece of an unknown metal with a mass of 217 g absorbs 1430 J of heat, and its temperature
rises from 24.5 oC to 39.1 oC. What is the specific heat of the metal?
q
c =
(m)(DT)

1430 J
= = 0.451 J / g oC
(217 g)(39.1 oC – 24.5 oC)

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Calorimetry is a technique for the experimental measurement of heat changes

heat released == q is “negative” heat absorbed == q is “positive”

5

A simple calorimeter can be highly effective!

A 248 g piece of an unknown metal is heated to 314.0 oC and is dropped into a calorimeter
containing 390 g of water, in which the water is initially at 22.6 oC. The final temperature
is 38.7 oC. What is the specific heat of the metal?
qlost = – qgained
qlost, metal = – qgained, water

m c DT (metal) = – [m c DT (water)]

(248 g) (c) (38.7 oC – 314.0 oC) = – [(390 g) (4.184 J/g oC) (38.7 oC – 22.6 oC)]

– [(390 g) (4.184 J/g oC) (16.1 oC)]
c =
(248 g) (– 275.3 oC)

c = 0.39 J / g oC

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Measurement of heat changes in chemical reactions

Example : Heat of neutralization
Experiment: 50.0 mL of 1.00 M HCl(aq) reacts with 50.0 mL of 1.00 M NaOH(aq). If the initial
temperature of both solutions is 22.0 oC, and the final temperature is 28.9 oC, what is the heat of
neutralization of HCl(aq) in J/mole? Assume that the specific heat of the solution is equivalent to the
specific heat of water. The density of the solution is 0.9987 g / mL.

HCl(aq) + NaOH(aq) H2O(l) + NaCl(aq)

q = m c DT 0.9987 g solution
100.0 mL solution x
o o
= (99.87 g solution) (4.184 J / g C) (6.9 C) 1 mL solution

= 2883 J = 2900 J = 99.87 g solution

moles HCl = 50.0 mL 10 –3 L 1.00 mole HCl
x x = 0.0500 mole HCl
1 mL 1L
2900 J Temperature of surroundings increased, so
qsolution = = 58,000 J/mole = 58 kJ/mole
0.0500 mole HCl reaction is exothermic, and q = - 58 kJ

7

Heat of combution can be measured in a “bomb” calorimeter

qrxn = – (qwater + qbomb)

= – [ (m c DT)water + (C DT)bomb]

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Example Problem

Suppose that 0.963 g of liquid benzene (C6H6) undergoes combustion in a bomb calorimeter with C = 784 J/oC, and
925 mL of water. The temperature of the calorimeter and water increases by 8.39 oC as a result of the reaction.
What is the heat of combusion of benzene in kJ/mole?

C6H6(l) + O2(g) CO2(g) + H2O(l)

C6H6(l) + O2(g) 6 CO2(g) + 3 H2O(l)

C6H6(l) + 15/2 O2(g) 6 CO2(g) + 3 H2O(l)

2 C6H6(l) + 15 O2(g) 12 CO2(g) + 6 H2O(l)

qrxn = – (qwater + qbomb)

= – [ (m c DT)water + (C DT)bomb]

= – [(925 g) (4.184 J / g oC) (8.39 oC) + (784 J/oC) (8.39 oC)]

= – (32,500 J + 6,580 J) = – (32,500 + 6,600 J) = –39,100 J = – 39.1 kJ

9

Benzene combustion, continued.

0.963 g C6H6 1 mole C6H6
x = 0.0123 mole C6H6
78.12 g C6H6

– 39.1 kJ
= – 3180 kJ / mole !!!
0.0123 mole C6H6

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 10/9/24

Chemistry 116
Fall 2024
Lecture 18

Focus Area 4A : Thermochemistry
Calorimetry
The Enthalpy Function
Thermochemical Equations
Standard Enthalpy of Formation

Orthoclase

KAlSi3O8 Calcite, CaCO3

1

The halogens span three states of matter at standard conditions

vaporization

Fluorine
Bromine

sublimation

Chlorine
Iodine

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Heat of combustion can be measured in a “bomb” calorimeter

q lost = – q gained
qrxn = – (qwater + qbomb)

= – [ (m c DT)water + (C DT)bomb]

3

Example Problem

Suppose that 0.963 g of liquid benzene (C6H6) undergoes combustion in a bomb calorimeter with C = 784 J/oC, and
925 mL of water. The temperature of the calorimeter and water increases by 8.39 oC as a result of the reaction.
What is the heat of combusion of benzene in kJ/mole?

C6H6(l) + O2(g) CO2(g) + H2O(l)

C6H6(l) + O2(g) 6 CO2(g) + 3 H2O(l)

C6H6(l) + 15/2 O2(g) 6 CO2(g) + 3 H2O(l)

2 C6H6(l) + 15 O2(g) 12 CO2(g) + 6 H2O(l)

q lost = – q gained
qrxn = – (qwater + qbomb)

= – [ (m c DT)water + (C DT)bomb]

= – [(925 g) (4.184 J / g oC) (8.39 oC) + (784 J/oC) (8.39 oC)]

= – (32,500 J + 6,580 J) = – (32,500 + 6,580 ) J = –39,100 J = – 39.1 kJ

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Benzene combustion, continued.

0.963 g C6H6 1 mole C6H6
x = 0.0123 mole C6H6
78.12 g C6H6

– 39.1 kJ
= – 3180 kJ / mole !!!
0.0123 mole C6H6

5

The conservation of energy is stated by the First Law of Thermodynamics

DE = q + w == The change in INTERNAL ENERGY of a chemical system is the sum of the
work done and the heat exchanged.

Some conventions : Heat added TO the system == “positive” q

Heat removed FROM the system == “negative” q

Work done ON the system == ”positive” w

Work done BY the system == “negative” w

DE

Key Point : The internal energy E is a STATE FUNCTION –
the path of the change in internal energy does not matter !!

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The Enthalpy is a state function describing "heat content"

H = E + PV For chemical reactions at
constant pressure, DP = 0,
DH = DE + D(PV) = DE + PDV + VDP so VDP = 0 !

PDV == “Pressure – volume work”

Compression : change in volume is negative (DV < 0) If the work done
is positive when the
work done on the system (w is positive) volume change is negative,
then w = – PDV
So, w = – PDV

For systems at constant pressure DH = DE + PDV

= q + w – w Because PDV = – w

= q First Law of Thermodynamics:
DE = q + w
The heat of reaction at constant pressure is equal to the enthalpy change ! = q – PDV

7

Thermochemical equations relate enthalpy changes to chemical reactions

H2(g) + ½ O2(g) H2O(l) DH = – 285.8 kJ (exothermic)

H2(g) + ½ O2(g) H2O(g) DH = – 241.8 kJ (exothermic)

The physical state of the reactants and products will affect the value of the enthalpy change !!

C(s) + 2H2(g) + ½ O2(g) CH3OH(l) DH = – 239.2 kJ

2 C(s) + 4H2(g) + O2(g) 2 CH3OH(l) DH = – 478.4 kJ

Enthalpy of reaction is an extensive property !

Standard enthalpy of formation == enthalpy of reaction for the formation of ONE MOLE
of a substance from the elements in their STANDARD STATES

H2(g) + ½ O2(g) H2O(l) DH f o = – 285.8 kJ (exothermic)

A special type of notation for a specific type of enthalpy change !

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 10/12/24

Chemistry 116
Fall 2024
Lecture 19

Focus Area 4A : Thermochemistry
Calculation of Enthalpy of Reaction

Orthoclase Almandine Garnet
Fe2Al3(SiO4)3

Eclogite
KAlSi3O8 Calcite, CaCO3

1

The Enthalpy is a state function describing "heat content"

H = E + PV For chemical reactions at
constant pressure, DP = 0,
DH = DE + D(PV) = DE + PDV + VDP so VDP = 0 !

PDV == “Pressure – volume work”

Compression : change in volume is negative (DV < 0) If the work done
is positive when the
work done on the system (w is positive) volume change is negative,
then w = – PDV
So, w = – PDV

For systems at constant pressure DH = DE + PDV

= q + w – w Because PDV = – w

= q First Law of Thermodynamics:
DE = q + w
The heat of reaction at constant pressure is equal to the enthalpy change ! = q – PDV

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 10/12/24

Thermochemical equations relate enthalpy changes to chemical reactions

H2(g) + ½ O2(g) H2O(l) DH = – 285.8 kJ (exothermic)

H2(g) + ½ O2(g) H2O(g) DH = – 241.8 kJ (exothermic)

The physical state of the reactants and products will affect the value of the enthalpy change !!

C(s) + 2H2(g) + ½ O2(g) CH3OH(l) DH = – 239.2 kJ

2 C(s) + 4H2(g) + O2(g) 2 CH3OH(l) DH = – 478.4 kJ

Enthalpy of reaction is an extensive property !

Standard enthalpy of formation == enthalpy of reaction for the formation of ONE MOLE
of a substance from the elements in their STANDARD STATES

H2(g) + ½ O2(g) H2O(l) DH f o = – 285.8 kJ (exothermic)

A special type of notation for a specific type of enthalpy change !

3

Thermochemical properties are tabulated by substance

Example Problem : What is the chemical equation corresponding to the formation of liquid carbon tetrachloride
from the elements in their standard states?

C(s) + 2 Cl2(g) CCl4(l) DH = – 128.2 kJ

DHo
f = – 128.2 kJ / mole

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Example Problem : Enthalpy Calculation

When 1.34 g of zinc metal reacts with 60.0 mL of 0.750 M hydrochloric acid, 3.14 kJ of heat is produced and
hydrogen gas is released. What is the enthalpy change for the reaction?

a. Balanced chemical equation
b. Enthalpy change in kJ/mole of Zn Zn(s) + HCl(aq) ZnCl2(aq) + H2(g)

Zn(s) + 2 HCl(aq) ZnCl2(aq) + H2(g)

1 mole Zn
1.34 g Zn x = 0.0205 mole Zn
65.38 g Zn

0.0600 L HCl sol'n x 0.750 mole HCl
= 0.0450 mole HCl | 0.0450 mole / 2 mole = 0.0225, so Zn is limiting
1 L HCl sol'n

– 3.14 kJ
DH = = – 153 kJ / mole Zn
0.0205 mole Zn

5

Hess’s Law gives us a method for calculating enthalpies

Suppose we want to know the standard enthalpy of formation for FeCl3(s):

Fe(s) + 3/2 Cl2(g) FeCl3(s)

Fe(s) + Cl2(g) FeCl2(s) DHo = – 341.8 kJ

FeCl2(s) + ½ Cl2(g) FeCl3(s) DHo = – 57.7 kJ

Fe(s) + 3/2 Cl2(g) FeCl3(s) DHo = – 399.5 kJ

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A bit more challenging example...
Let's use experimental measurements of enthalpies of reaction to calculate
the standard enthalpy of formation for AlCl3(s)...

Al(s) + 3/2 Cl2(g) AlCl3(s) DHof = ?

Experimental Measurements

HCl(g) HCl(aq) DHo = – 75 kJ

½ H2(g) + ½ Cl2(g) HCl(g) DHo = – 93 kJ

AlCl3(aq) AlCl3(s) DHo = + 323 kJ

Al(s) + 3 HCl(aq) AlCl3(aq) + 3/2 H2(g) DHo = – 525 kJ

7

Putting the pieces together...
Al(s) + 3/2 Cl2(g) AlCl3(s)

1. Al(s) + 3 HCl(aq) AlCl3(aq) + 3/2 H2(g) DHo = – 525 kJ

2. 3 HCl(g) 3 HCl(aq) DHo = – 225 kJ

3. 3/2 H2(g) + 3/2 Cl2(g) 3 HCl(g) DHo = – 279 kJ

4. AlCl3(aq) AlCl3(s) DHo = + 323 kJ

Al(s) + 3/2 Cl2(g) AlCl3(s) DHo = – 706 kJ

DHo
f (AlCl3 , s) = -706 kJ / mole

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Hess's Law can be extended to a more general form
DHo
f
Elements in their standard states at 25 oC are reference states.

CH4(g) + 2 O2(g) CO2(g) + 2 H2O(l)

DHo = S DHof (products) – S DHof (reactants)

DHo = [DHo
f (CO2) + 2 DHo
f (H2O)] – [2 DHo
f (O2) + DHo
f (CH4)]

DHo = [(1 mole CO2)(-393.5 kJ/mole) + (2 mole H2O)(-285.8 kJ/mole)]

– [2 mole O2)(0 kJ/mole)] + (1 mole CH4)(-74.6 kJ/mole)]

9

Be sure to keep track of your negative signs ! !

DHo = [ (1 mole CO2) (-393.5 kJ/mole) + (2 mole H2O) (-285.8 kJ/mole) ]

– [ (2 mole O2) (0 kJ/mole) + (1 mole CH4) (-74.6 kJ/mole) ]

DHo = [ (-395.5 kJ) + (-571.6 kJ) ] – [ ( 0 kJ) + (-74.6 kJ) ]

DHo = [ - 967.1 kJ ] – [ - 74.6 kJ ] = - 892.5 kJ

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Practice Problem
Let's calculate the standard enthalpy change DHo for the reaction of solid lithium hydroxide with carbon dioxide gas
to form solid lithium carbonate and liquid water.

LiOH(s) + CO2(g) Li2CO3(s) + H2O(l)

2 LiOH(s) + CO2(g) Li2CO3(s) + H2O(l)

DHo = S DHo
f (P) –S DHo
f (R)

DHo = [DHo
f (Li2CO3) + DHo
f (H2O)] – [2 DHo
f (LiOH) + DHo
f (CO2)]

DHof

11

Practice Problem, continued.

DHo = [DHo
f (Li2CO3) + DHo
f (H2O)] – [2 DHo
f (LiOH) + DHo
f (CO2)]

DHo = [ (1 mole Li2CO3) (-1216.0 kJ/mole) + (1 mole H2O) (-285.8 kJ/mole) ]
– [ (2 mole LiOH) (-487.5 kJ/mole) + (1 mole CO2) (-393.5 kJ/mole) ]

DHo = [ (-1216.0 kJ) + (-285.8 kJ) ] – [ (-975.0 kJ) + (-393.5 kJ) ]

DHo = [ -1501.8 kJ ] – [ -1368.5 kJ ] = - 133.3 kJ

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 10/14/24

Chemistry 116
Fall 2024
Lecture 20

Lecture Topics Recap

Orthoclase

Eclogite
KAlSi3O8 Calcite, CaCO3

1

1. Reaction Chemistry
Chemical Reactivity Types
Balance Chemical Equations
Metathesis Reactions – Predict reactivity through solubility rules
Reaction Stoichiometry
Acid-Base Reactions – Predict reaction products by neutralization
Limiting Reactants
Oxidation-Reduction Reactions – Analysis through change in oxidation states

2. Volume and Density Conversions

Convert between volume units

Convert density between kg/m3 and g/cm3

3. Combustion Analysis

Determination of empirical molar mass from masses of CO2 and H2O or CO2, H2O and NO2
Titration analysis to determine molar mass, and then true molecular formula

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4. Thermochemistry

Kinetic and potential energy

First Law of Thermodynamics : Definitions of heat and work

Enthalpy function : Equivalence of q and DH for reactions at constant pressure

Thermochemical equations

Definition of the Standard Enthalpy of Formation

Hess’s Law

Enthalpy of reaction DHo from tabulated values of DHfo

3

How do we determine uncertainty for a quotient or a product ?
Suppose we want to determine the uncertainty in the density of a substance from laboratory measurements. In this
case we would have a quotient.

m = 7.629 ± 0.002 g
d = 4.04 g/cm3
v = 1.89 ± 0.02 cm3

In order to propagate the error in this measurement, we must determine the relative uncertainties first. The reason is that
we are DIVIDING measurements to get a different type of measurement, so we cannot simply add the squares of the
absolute uncertainties as we did for a sum or difference. In this case, we must calculate the relative uncertainties in each
measurement first, and then carry out the calculation of the uncertainty as before:

e1 = 0.002 / 7.629 x 100 % = 0.02 %
e = [ 0.02 % 2 + 1 % 2 ] ½ = 1.0004 ½ = 1%
e2 = 0.02 / 1.89 x 100 % = 1 %

So, in terms of the relative uncertainty : d = 4.04 g/cm3 ± 1 %

The absolute uncertainty is then 0.01 x 4.04 g/cm3 = 0.04 g/cm3, so in terms of absolute uncertainty, d = 4.04 ± 0.04 g/cm3

4

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Chemistry 116
Fall 2024
Lecture 21

Focus Area 1 : Atoms

1A : Electromagnetic Radiation
1B : Quantum Theory and the Bohr Model

Calcite, CaCO3 Granite Half Dome, Yosemite
Quantum theory starts with the visible emission spectrum of atomic hydrogen !

Balmer Series
(visible)

H2(g) 2H(g)
121.6 nm

Key Observation : Only specific energies of Lyman Series
light were observed to be emitted from the (ultraviolet)
hydrogen atom !!
 Light is composed of oscillating electric and magnetic fields

Electromagnetic Spectrum
James Clerk Maxwell
visible range == 425 – 750 nm University College, London
Rumford Medal, 1860
All electromagnetic radiation travels with the same speed in a vacuum

Wavelength == meters / wave == l

Frequency second == n
== waves / ==
meters waves
speed of light = c = l n == x
wave second

== meters / second

= 3.00 x 10 m/s
8
Interactions between waves can produces interference patterns

Nodal points in 1 dimension Nodal surfaces in 2 dimensions
Practice Problems

1. What is the frequency of green light with l = 514 nm ?

514 nm = 514 x 10 –9 m

c = l n

c 3.00 x 10 m/s 8

= n = = 5.84 x 10 14 /s
l 514 x 10 –9 m

2. What region of the electromagnetic spectrum would correspond to a frequency of 1.80 x 10 18 /s ?

c = l n

c 3.00 x 10 m/s 8

= l = = 1.67 x 10 – 10 m = 1.67 Å (recall that 1 Å = 10 – 10 m)
n 1.80 x 10 18 /s

1 nm
1.67 x 10 – 10 m x = 0.167 nm
10 –9 m
Max Planck showed that light is emitted in discrete "packets"

classical physics prediction

Max Planck
Universität München
Nobel Prize in Physics, 1918

For any temperature, there must be a specific energy at which light is emitted, which is
directly proportional to the frequency:

E=hn h = 6.626 x 10 – 34 J s == Planck's constant
Five spectral series are observed for the hydrogen atom

Light energy is emitted from the atom in an
organized, predictable pattern !

The electron in the hydrogen atom must be losing energy, and this energy is released as electromagnetic radiation.

Electromagnetic radiation is released as PHOTONS, which have both wave and particle properties.

The electron must only be allowed to have a specific set of energies within the atom.

Therefore, these energy states in the hydrogen atom are QUANTIZED.

The energy of the light emitted by the atom must be equal to the difference between different energy states.
The Bohr model of the hydrogen atom explains the emission spectra !
Energy levels must be more closely spaced with increasing energy !!

Neils Bohr
University of Copenhagen
Nobel Prize in Physics, 1922

ℎ𝑐 !"#
1 1
∆𝐸 = ℎ𝜐 = = 2.179 × 10 J %− %
𝜆 𝑛$ 𝑛&
Practice Problems

1. Calculate the wavelength of light emitted when an electron in the hydrogen atom undergoes a transition from
n = 3 to n = 1. To what region of the electromagnetic spectrum does this wavelength correspond?
2. A line in the Paschen series of the hydrogen emission spectrum has l = 1280 nm. To what region of the
electromagnetic spectrum does this wavelength correspond? What are the initial and final states
of the electron involved in this transition?
Sure, but what about helium?

H: 2-body problem

He: 3-body problem
 10/18/24

Chemistry 116
Fall 2024
Lecture 22

Focus Area 1: Atoms

Quantum Mechanics
The Wavefunction
Atomic Orbitals

S22- ions
Pyrite, FeS2 Ammonite

Calcite, CaCO3 Trilobite Half Dome, Yosemite

1

Practice Problems

1. Calculate the wavelength of light emitted when an electron in the hydrogen atom undergoes a transition from
n = 3 to n = 1. To what region of the electromagnetic spectrum does this wavelength correspond?

2

1
 10/18/24

2. A line in the Paschen series of the hydrogen emission spectrum has l = 1280 nm. To what region of the
electromagnetic spectrum does this wavelength correspond? What are the initial and final states
of the electron involved in this transition?

3

Sure, but what about helium?

H: 2-body problem

He: 3-body problem

4

2
 10/18/24

If waves can behave like matter, can matter behave like a wave?

Louis de Broglie
University of Paris
Nobel Prize in Physics, 1929

h
l =
mv

Electron at 1.00 x 107 m/s
l = 7.27 x 10 – 11 m = 72.7 pm = 0.0727 nm

Baseball at 85.0 mph = 40.0 m/s
l = 4 x 10 – 34 m ~ 4 x 10 – 22 pm !

Softball at 40.0 mph = 17.9 m/s
l = 2 x 10 – 34 m ~ 2 x 10 – 22 pm !

5
l

How can we completely describe the behavior of an electron?

Quantum (Wave) Mechanics – the laws of physics for very small objects
with speeds close to the speed of light

What we need is...

Erwin Schrödinger
Friedrich Wilhelm University
Berlin A mathematical function, like Newton's laws but
Nobel Prize in Physics, 1933 that will describe a particle emitting a wave...
the WAVEFUNCTION

To predict motion motion, energies of the electron

To take into account complex potential energies

For the mathematics to reduce to classical
mechanics as objects get larger and speeds get
lower
Wolfgang Pauli
Federal Technical Institute of Technology
Zurich
Nobel Prize in Physics, 1945

6

3
 10/18/24

Quantum Mechanics starts with the Schrödinger Equation

ℎ! 𝜕! 𝜕! 𝜕! "Eigenvalue Problem" == Solving for the value of Y will
− + + + 𝑉(𝑥, 𝑦, 𝑧! Ψ = 𝐸 Ψ give back the wavefunction Y along with the energy
8𝜋 !𝑚 𝜕𝑥 ! 𝜕𝑦 ! 𝜕𝑧 !

"OPERATOR" calculates kinetic and potential energies Operator Algebra

Many solutions – describe the "stationary states" of the hydrogen f(x) = x + 2 O = ( )2
atom
O [ f(x) ] = (x+2)2 = x2 + 4x + 4
Must specify the potential energy expression

f(x) = x2 O=Ö

O [ f(x) ] = Ö x2 = ± x

7

The Quantum Numbers index the solutions to the Schrödinger Equation
Key Point : Solutions to the Schrödinger equation tell us what types of motion the electron is ALLOWED to have !

First Solution : PRINCIPAL quantum number, n == the "energy level" quantum number

Allowed values : n = 1, 2, 3...

For 1 - electron atoms or ions (H, He+, Li2+), energy of Bohr model is reproduced EXACTLY !!

n=7

397 nm BUT... this is as far as the Bohr model would go !

Balmer Series

8

4
 10/18/24

Angular momentum describes the TYPE of motion the electron is allowed to have

Second Solution : Angular momentum quantum number,

Allowed values : = 0, 1, 2, 3... n-1

The number of values of that are allowed depends on the energy level AND is equal to the energy level number

The specific value of defines a type of ORBITAL – a region of space in which the electron is ALLOWED to move

2p

If = 1, the electron is in a p-type orbital

n=2 = 0, 1 only : If = 0, the electron is in an s-type orbital 2s

1s
n=1 = 0 only : If = 0, the electron is in an s-type orbital

9

Angular momentum, continued.
If = 2, the electron is
in a d-type orbital 3d

3p

n=3 3s

= 0, 1, 2 only
3d

2p Key Points:

n=2 2s Atomic orbitals are mathematical functions (also called
wavefunctions !) that describe the motion an electron
is allowed to have based on its energy.

The atomic orbitals along with their energies are
solutions to the Schrödinger Equation.

n=1 1s

10

5
 10/21/24

Chemistry 116
Fall 2024
Lecture 23

Focus Area 1: Atoms

Quantum Mechanics
The Wavefunction
Atomic Orbitals
Electron Spin

1m Zebra Rock
East Kimberly, Australia

Earth and Space
Chemistry 2023, 7,
2042-2049.

Calcite, CaCO3 Half Dome, Yosemite

1

How can we completely describe the behavior of an electron?

Quantum (Wave) Mechanics – the laws of physics for very small objects
with speeds close to the speed of light

What we need is...

Erwin Schrödinger
Friedrich Wilhelm University
Berlin A mathematical function, like Newton's laws but
Nobel Prize in Physics, 1933 that will describe a particle emitting a wave...
Method : Differential Equations (difficult)
the WAVEFUNCTION

To predict motion motion, energies of the electron

To take into account complex potential energies

For the mathematics to reduce to classical
mechanics (Newton’s Laws) as objects get larger
Wolfgang Pauli and speeds get lower
Federal Technical Institute of Technology
Zurich
Nobel Prize in Physics, 1945
Method : Matrix Mechanics (extremely difficult)

2

1
 10/21/24

Quantum Mechanics starts with the Schrödinger Equation

ℎ! 𝜕! 𝜕! 𝜕! "Eigenvalue Problem" == Solving for the value of Y will
− + + + 𝑉(𝑥, 𝑦, 𝑧! Ψ = 𝐸 Ψ give back the wavefunction Y along with the energy
8𝜋 !𝑚 𝜕𝑥 ! 𝜕𝑦 ! 𝜕𝑧 !

Operator Algebra

"OPERATOR" calculates kinetic and potential energies f(x) = x + 2 O = ( )2

O [ f(x) ] = (x+2)2 = x2 + 4x + 4
Many solutions – describe the "stationary states" of the hydrogen
atom
f(x) = x2 O=Ö
Must specify the potential energy expression
O [ f(x) ] = Ö x2 = ± x

Key Points:

We propose a wavefunction based on all the physics of We iterate on the wavefunction until the Ψ we put in
the proton-electron interaction is the same as the Ψ we get out (convergence)

We operate on the wavefunction with the energy operator In so doing, we generate many solutions to the
(“Hamiltonian” operator) Schrödinger Equation (many Ψ , many E )

3

Angular momentum describes the TYPE of motion the electron is allowed to have

Second Solution : Angular momentum quantum number,