Title: Key Concept Summary
1Key Concept Summary
2Atoms and the Atomic Theory
- All the matters can be broken down into elements.
Is matter continuously divisible into ever
smaller and smaller pieces, or is there an
ultimate limit? What is an element made of? - Greeks
- Aristotle- Continuous Theory of Matter
- Democritus- Discontinous Theory of Matter
- Atomos- indivisible
- I. Early Chemical Discoveries and Atomic
TheoryThree important fundamental laws in
chemistry1) Law of conservation of mass2) Law
of constant composition3) Law of multiple
proportions
3Law of Conservation of Mass
- 1774 Antoine Lavoisier showed heating the red
power HgO causes it to decompose into the silvery
liquid mercury and the colorless gas oxygen. 2HgO
? 2Hg O2 then show that oxygen is the key
substance involved in combustion. - Furthermore, results of combustion reactions
- Total mass of products total mass of reactants
- (tin air sealed glassed vessel) ?? (tin oxide
remaining air glass vessel) - Law of conservation of mass
-
4 E.g. A 0.382g sample of magnesium reacts with
2.652g of nitrogen gas. The sole product is
magnesium nitride. After reaction, the mass of
unreacted nitrogen is 2.505g. What mass of
magnesium nitride is produced?
5Law of Constant Composition
1799 Joseph Proust Law of constant
composition All samples of a compound have the
same composition- the same proportion by mass of
the constituent elements. This means that the
relative amount of each element in a particular
compound is always the same, regardless of the
source of the compound or how the compound is
prepared. E. g. Water is made up of two
elements H and O. The two sample of water below
have the same proportions of the two elements,
expressed as percentages by mass. Every sample of
water contains 1 part hydrogen and 8 parts oxygen
by mass. _________________________________________
sample A Composition sample
B 10.000g 27.000g 1.119g H H
11.19 3.031g H 8.881g O O 88.81 23.979g
O
6Daltons Atomic Theory
How can the Law of conservation of mass and Law
of constant composition be explain? Why do
element behave as they do? 1803-1808 John Dalton
proposed a new theory of matter. 1. 2.
7Daltons Atomic Theory
- 3. Atoms of an element are not changed into atoms
of a different element by chemical reactions
atoms are neither created nor destroyed in
chemical reactions. Chemical compounds are formed
when atoms combine with each other. - If atoms of an element are indestructible, then
the same remains unchanged. This explains the
law of conservation of mass.
8Daltons Atomic Theory
- 4. In each of their compounds, different elements
combine in a simple numerical ratio e.g. one
atom of A to one of B (AB) or one atom of A to
two of B (AB2). - If all atoms of an element are alike in mass
(assumption 2) and if atoms unite in fixed
numerical ratio (assumption 3), the percent
composition of a compound must have a unique
value, regardless of the origin of the sample
analyzed. This explains the law of constant
composition.
9Law of Multiple Proportions
Daltons theory leads to a prediction- the law of
multiple proportions. If two elements form more
than a single compound, the masses of one element
combined with a fixed mass of the second are in
the ratio of small whole numbers. Same elements
to combine in different ratios to give different
substances.
10- E.g. Oxygen and carbon can combine either in a
1 1.333 mass ratio to make a substance or in a
1 2.667 mass ratio to make a substance. - first 1 g carbon per 1.333 g oxygen CO mass
ratio 1 1.333 - second 1 g carbon per 2.667 g oxygen CO mass
ratio 1 2.667 - Compare two substances clearly the second
substance contains exactly twice as much oxygen
as the first for a given number of carbon. If
the first oxide has the molecular formula CO then
the second oxide will be CO2.
11There are two compound both contain nitrogen and
hydrogen. Compound A contains 1.50g of N and
0.216g H. Compound B contains 2.00g of N and
0.144g H. If the formula of compound B is N2H2,
what is the formula of compound A? NH ratio in
A 1.50 0.216g 1.00 0.144 NH ratio in B
200 0.144 1.00 0.0720 H in A is
(0.144/0.0720 2 ) twice as much in B IF B is
N2H2 then A is N2H4
12Atomic Mass Unit
Daltons theory enables us to set up a scale of
relative atomic masses. He cannot measure the
exact mass of atoms but relative mass. E.g.
Consider calcium sulfide, which consists of 55.6
calcium by mass and 44.4 sulfur by mass. Suppose
there is one calcium atom for each sulfur atom in
calcium sulfide. Because we know that the mass
of a calcium atom relative to that of a sulfur
atom must be the same as the mass in calcium,
we know that the ratio of the mass of a calcium
atom to that of a sulfur atom is mass of Ca
atom 55.6 1.25 mass of a S atom 44.4
or mass of a Ca atom 1.25 x mass of a sulfur
atom By continuing in this manner with other
compounds, it is possible to build up a table of
relative atomic masses. We define a quantity
called atomic mass ratio, which is the ratio of
the mass of a given atom to the mass of some
particular reference atom.
13The Structure of AtomsWhat is an atom made of ?
Discovery of subatomic particle The Discovery of
Electrons 1897 J.J. Thomson- cathode ray
experiment Thomsons experiment involved the use
of cathode-ray tube. When a sufficiently high
voltage is applied across the electrode, an
electric current flows through the tube from
negatively charged electrode ( the cathode) to
the positively charged electrode (the anode).
14Thomsons Experiment
-
Vacuum tube
Metal Disks
15Thomsons Model
Spherical cloud of positive charge
- Found the electron
- Couldnt find positive (for a while)
- Said the atom was like plum pudding
- A bunch of positive stuff, with the electrons
able to be removed - established the ratio of mass to electric charge
for cathode ray m/e -5.6857x10-9
g/coulomb.
Electrons
16Millikans Oil-Drop Experiment Mass of Electron
1909 Robert Millikan determined the electronic
charge through a series of oil-drop experiments.
The currently accepted value of the charge of the
e is 1.6022x10-19C. Substituting into
Thomsons mass to charge ratio then gives the
mass of electron as 1/1836( 9.1094x10-28g).
17 X-Ray and Radioactivity
Ernest Rutherford identified two type of
radiation from radioactive materials, alpha (?)
and beta (?). ?-particles (?He2)carry two
fundamental units of positive charge and have
essentially the same mass as He atoms.
?-particles are negatively charged particles
produced by changes occurring within the nuclei
of radioactive atoms and have the same properties
as electrons. A third form of radiation, that
is not affected by an electric field was
discovered in 1900 by Paul Villard. This
radiation, called ?-ray, is not made up of
particles it is electromagnetic radiation of
extremely high penetrating power. Properties of
the three radioactive emissions discovered
Original name Modern name Mass
(amu) Charge ?-ray ?-particle 4.00 2 ?-ray
?-particle (electron) 5.49x10-4 -1 ?-ray ?-ray
0 0_______
181909 Ernest Rutherford Scattering Experiment
used ? particle to study the inner structure of
atoms. directed a beam of ?-particles at a thin
gold foil
Florescent Screen
Lead block
Uranium
Gold Foil
19Rutherford Expected
- The alpha particles to pass through without
changing direction very much - WHY?
- The positive charges were spread out evenly.
Alone they were not enough to stop the alpha
particles
20What he expected
21Because
22Rutherford thought the mass was evenly
distributed in the atom
23Rutherford thought the mass was evenly
distributed in the atom?a particles should pass
through the low density model.
24What he got
The majority of ?-particles penetrated the foil
undeflected. ? Some ? particles experienced
slightly deflections. ? A few (about one in
every 20,000) suffered rather serious
deflections as they penetrated the foil. ? A
similar number did not pass through the foil at
all, but bounced back in the direction from which
they had come.
25How he explained it
26(No Transcript)
27The Nuclear Atom Protons and Neutrons
- 1911 Rutherford explained his results by
proposing a model of the atom known as the
nuclear atom and having these features. - Most of the mass and all of the positive charge
of an atom are centered in a very small region
called the nucleus. The atom is mostly empty
space. - The magnitude of the positive charge is
different for different atoms and is
approximately one-half the atomic weight of the
element. - There are as many electrons outside the nucleus
as there are units of positive charge on the
nucleus. The atom as a whole is electrically
neutral. -
- Rutherfords nuclear atom suggested the existence
of positively charged fundamental particles of
matter in the nuclei of atoms- called protons. He
predicted the existence in the nucleus of
electrically neutral particles. - 1932 James Chadwick
- verified that there is another type of
particles in atom called neutron.
28The Structure of Atoms
- Therefore
- Modern picture of an atom, then, consist of three
types of particles-electrons, protons and
neutron. - Electric Charge Mass
- Particle SI (C ) Atomic SI
(g) amu Located - Electron -1.602x10-19 -1
9.109x10-28 5.49x10-4 outside
nucleus - Proton 1.602x10-19 1
1.673x10-24 1.0073 in nucleus - Neutron 0 0
1.675x10-24 1.0087 in nucleus
29Size of an atom
- Atoms are small 10-10 meters
- Hydrogen atom, 32 pm radius
- Nucleus tiny compared to atom
- IF the atom was the size of a stadium, the
nucleus would be the size of a marble. - Radius of the nucleus near 10-15m.
- Density near 1014 g/cm
30Conclusion
- Matter is composed, on a tiny scale, of particles
called atoms. Atoms are in turn made up of
minuscule nuclei surrounded by a cloud of
particles called electrons. Nuclei are composed
of particles called protons and neutrons, which
are themselves made up of even smaller particles
called quarks. Quarks are believed to be
fundamental, meaning that they cannot be broken
up into smaller particles.
31Chemical Elements
- Atomic number
- What is that makes one atom different from
another? - Elements differ from one another according to the
number of protons in their nucleus - atomic number (Z)
- mass number (A)
32Isotopes
- Contrary to what Dalton thought, we know that
atoms of an element do not necessarily all have
the same mass. - Isotope-
33Isotopes of Hydrogen
34Mass Spectrometer- The most accurate means of
determining atomic and molecular weights.
35Mass Spectrum of Elemental Carbon
This small peak represents the relative abundance
of C13 in nature.
When 12C and 13C are analyzed in a mass
spectrometer, the ratio of their masses is found
to be Mass13C 1.0836129 Mass12C Since the
atomic mass unit is defined such that the mass of
12C is exactly 12 amu, then on this same
scale, Mass13C (1.0836129)(12amu) 13.003355
amu
36Average Atomic Mass
- When considering atomic masses from the P-Table,
recall that reported values are actually weighted
averages of all the naturally occurring isotopes. - Average atomic mass
- Boron has two isotopes 10B and 11B. They have
the abundance 18.7 and 81.3 respectively.
Determine the average atomic mass for Boron.
37When natural copper is vaporized and injected
into a mass spectrometer, the results shown below
are obtained. Use these data to compute the
average mass of copper. The mass values for 63Cu
and 65Cu are 62.93 amu and 64.93 amu respectively.
Computing Average Mass from Mass Spectrometer
Data Atomic Weight
38Isotopes and Average Atomic Mass Questions
- 1. Do either of the following pairs represent
isotopes of one another? - 40K19 and 40Ar18 b. 90Sr38 and 94Sr38
- 2. The nobel gas Neon, has three isotopes of
masses, 22, 21and 20. If the isotopes have the
abundance of 8.01, 1.99 and 90.00
respectively, what is the average atomic mass of
neon atoms? - 3. A naturally occurring sample of an element
consists of two isotopes, one of mass 85 and one
of mass 87. The abundance of these isotopes is
71 and 29. Calculate the average mass of an
atom of this element. - 4. If 69Ga and 71Ga occur in the s 62.1 and
37.9, calculate the average atomic mass of
gallium atoms.
39Mass Spectrum of Chlorine Molecule
(35Cl-35Cl), (35Cl-37Cl), or (37Cl-37Cl)
40 Ions
Ion an electrically charged particle obtained
from an atom or chemically bonded group of atoms
lose or gain electrons. The charge on an ion is
equal to the of protons minus the of
electrons. An atom that gains extra electrons
becomes a negatively charged ion, called an
anion. An atom that loses electrons becomes
positively charged ion, called a cation.
E.g. Determine numbers of electrons in Mg2
cation and the S2- anion? Mg2 number e
? S2- number e ?
41 Introduction to Periodic Table
- With discovery of many elements
- 1869 Mendeleev and Meyer
- independently proposed periodic table organized
the elements - In modern periodic table, The periodic table of
the elements is organized into 18 groups and 7
periods. Elements are represented by one or
two-letter symbols and are arranged according to
atomic number. - a horizontal row of elements- a period
- a vertical row of elements- a group or family
42Periodic Table of Elements
43It is customary also to divide the elements into
two broad categories known as Metals Except
mercury (liquid), metals are solid s at room
temperature. They are generally malleable,
ductile, good conductors of heat and electricity,
and have a lustrous or shiny appearance.
Nonmetals generally have opposite properties of
metals e.g. poor conductors of heat and
electricity. Metalloid (semimetal) is an element
having both metallic and nonmetallic
properties. Or into three groups Main group
elements are those in groups 1, 2 and 13-18. when
form ions, group 1, 2 lose the same e as their
group group 13 lose group -10 group 14-18
gain 18-group . Transition elements from group
3 to 12, and because all of them are metals, they
are also called the transition metals. The of
electrons lost in TM is not related to their
group . Inner transition metals which include
Lanthanides and Actinindes.
44Mole S.I. Unit for amount of substance
We buy a quantity of groceries in several ways.
by number such as eggs, apples and oranges by
mass such as rice and peanuts The quantity of
an element or a compound, which like grocery
items, can be measured by number or by mass.
Molecules and atoms are extremely small objects -
both in size and mass. Consequently, working with
them in the laboratory requires a large
collection of them. How large does this
collection need to be? Chemists have adopted the
mole concept as a convenient way to deal with the
enormous numbers of atoms, molecules or ions in
the sample they work with.
45The Concept of the Mole and the Avogadro Constant
definition A mole is an amount of substance that
contains the same number of elementary entities
(atoms, molecules or formula units) as the number
of atoms in exactly 12g of carbon-12. (the
quantity of a substance whose mass in gram is
numerically equal to the formula mass of the
substance). The value of Avogadros number (the
of elementary entities) is based on a
definition and a measurement. A mole of
carbon-12 is defined to be 12 gram. The mass of
one carbon-12 atom is measured using mass
spectrometer and found to be 1.9927x10-23g. The
ratio of this two mass is Avogadros number, NA.
Therefore, one mole of C 6.02214 x 10 23 atoms
12.011g one mole of O 6.02214 x
10 23 atoms 15.9994gThe mass of one mole of
atoms, called molar mass (g/mole).
46E.g. How many atoms of gold are present in
5.07x10-3mol Au? E.g. How many lead-206
atoms are present in 1.71g of lead? The nature
abundance of lead-206 is 24.1. First convert the
mass to mol
47Nuclear Chemistry
- Nuclear Changes
- Chemical Changes
- Uses
- 60Co- gamma ray emitter- ionizing radiation for
treatment of cancerous tumors. - 201Thallium stress test of heart muscle
- Radiocarbon dating? 14C ½ life 5730 years
- Nuclear power 20 of US electricity production
48Radioactivity
- Recall that all atoms of the same element have
the same number of protons. The number of
neutrons in the atoms nucleus, however, may be
different from one atom to the next Isotopes. - Uranium- 234 Uranium-235 Uranium-238
- 92 protons 92 protons 92 protons
- 142 neutrons 143 neutrons 146 neutrons
- Trace 0.7 99.3
- Different isotopes have different abundances
- Different isotopes have different stabilities
49Patterns of Nuclear Stability
As the atomic number increases, the neutron to
proton ratio of the stable nuclei increases. The
stable nuclei are located in the shaded area of
the graph known as the belt of stability. The
majority of radioactive nuclei occur outside this
belt.
50Nuclear Equations
238
234
U
4
Th
He
92
90
2
51Nuclear Equations
- Mass numbers and atomic numbers must be balanced
in all nuclear equations.
52What product is formed when thorium-232 undergoes
alpha decay?
53Types of Radioactive Decay
Alpha decay-
Beta decay-
Gamma- high energy, short wavelength
electromagnetic radiation- accompanies other
radioactive emissions.
54Types of Radioactive Decay
- Electron Capture-
- Positron-
55Penetrating Power of Radioactive Decay
56Radioactive Decay Particles
88
86
2
2
-1
53
54
-1
1
0
37
36
-1
1
-1
0
57Radioactive Decay Particles
6
5
1
1
0
1
Remember a positron has the same mass as an
electron, but the opposite charge
58Radioactive Decay Particles
59Half Life- the time required for half of any
given quantity of a substance to react / decay.
(independent of initial quantity of atoms)
Number of Th-232 atoms in a sample initially
containing 1 million atoms as a function of time.
Th-232 has a half-life of 14 billion years.
60Half Life Problems
- Example
- An isotope of cesium (cesium-137) has a half-life
of 30 years. If 1.0 mg of cesium-137
disintegrates over a period of 90 years, how many
mg of cesium-137 would remain? -
61Half Life Problems
1. A 2.5 gram sample of an isotope of
strontium-90 was formed in a 1960 explosion of an
atomic bomb at Johnson Island in the Pacific Test
Site. The half-life of strontium-90 is 28 years.
In what year will only 0.625 grams of this
strontium-90 remain? 2. Actinium-226 has a
half-life of 29 hours. If 100 mg of actinium-226
disintegrates over a period of 58 hours, how many
mg of actinium-226 will remain? 3.
Thallium-201 has a half-life of 73 hours. If 4.0
mg of thallium-201 disintegrates over a period of
6.0 days and 2 hours, how many mg of thallium-201
will remain? 4. Sodium-25 was to be used in an
experiment, but it took 3.0 minutes to get the
sodium from the reactor to the laboratory. If
5.0 mg of sodium-25 was removed from the reactor,
how many mg of sodium-25 were placed in the
reaction vessel 3.0 minutes later if the
half-life of sodium-25 is 60 seconds? 5.
Selenium-83 has a half-life of 25.0 minutes. How
many minutes would it take for a 10.0 mg sample
to decay and have only 1.25 mg of it remain?
62Uranium-238 an example of an unstable nucleus
decaying to form other unstable nuclei
Uranium-238 is radioactive, undergoing alpha
decay. But, the daughter nuclide is also
radioactive, undergoing beta decay, to produce
yet another radioactive nuclide, which decays.
The atom goes through a rather involved sequence
of radioactive decays (both alpha and beta),
until a stable isotope (lead-206) is reached.
63Fission Reaction
Collision of a neutron with a U-235 nucleus can
cause the nucleus to split, creating two smaller
nuclides and three free neutrons. The three
neutrons may travel outward from the fission,
colliding with nearby U-235 nuclei, causing them
to split as well. Each split (fission) is
accompanied by a large quantity of energy.
64Fission Chain Reaction
If sufficient neutrons are present, we may
achieve a chain reaction. If only one neutron
were produced with each fission, no chain
reaction would occur, because some neutrons would
be lost through the surface of the uranium sample.
65Fission Reaction
66Fusion Reaction
Tremendous energy needed to overcome the
repulsion between nuclei. Heat required for this
reaction is on the order of 40,000,000 K. The
energy from an atomic bomb could generate this
heat (hydrogen or thermonuclear weapon).