Transcript document

CP Chemistry – Chapter 3
Mrs. Albertson
Spring 2001
Lavoisier

Father of Modern Chemistry





The first to use truly quantitative research
Law of Conservation of Mass
Identified components of water as hydrogen
and oxygen
http://encarta.msn.com/encnet/refpages/RefA
rticle.aspx?refid=761571807
http://encarta.msn.com/encnet/refpages/RefM
edia.aspx?refid=461541281
The Structure of the Atom







http://www.watertown.k12.wi.us/hs/teachers/bue
scher/atomtime.asp
http://www.sci.tamucc.edu/pals/morvant/genche
m/atomic/index.htm
Atom: Smallest particle of an element that still
retains properties of that element
4th Century B.C. – Democritus first suggested
the idea of atoms
Nucleus – contains protons and neutrons
Electrons are found outside the nucleus
Smaller subatomic particles are not discussed
here
Discovery of Electrons

John Dalton


Noticed that % of each element in a
compound is always the same: Law of
Definite Proportions
Carbon Dioxide

Always 27.3% carbon and 72.9 % Oxygen
Dalton’s Atomic Theory





All elements are composed of indivisible
particles called atoms
Atoms of the same element are identical; atoms
of different elements are different
Atoms of different elements combine in small
whole number ratios to form compounds
Chemical reactions occur when atoms are
separated, joined, or rearranged
Atoms of one element are not changed into
atoms of another element, subdivided, or
destroyed
Crooke’s Experiment – 1870’s

Gas Tubes w/2 electrodes (conductors)



Anode – positive
Cathode – negative
Cathode ray tube – applied voltage &
beam of light composed of particles was
deflected by a magnet – able to determine
they were charged particles
The Discovery of Electrons



J.J. Thomson – Investigating the relationship
between matter & electricity
CRT w/fluorescent screen allowed him to
measure deflection when a magnet was used
Measure ratio of charge to mass and
determined particles were identical regardless of
the gas used/subatomic particles
Millikan - 1909



Approximated the mass of an electron to
be 1/2000 the mass of an H atom
Current 1/1837
9.109 x 10-31 kg
Protons





Atoms are neutral so a positive charge must
exist
Thomson – designed exp to test/H+ moved
toward negative end of CRT
Protons identified by 1920
Deflection of + particles varied w/different gases.
Hydrogen had the greatest deflection and
smallest mass
Mass of Proton 1.673 x 10-27 kg
Thomson’s “Plum Pudding” Model




Nobel Prize 1907
Pudding was + charge and most of the mass of
the atom
Plums: - charged electrons spread throughout to
make the atom neutral
Ions: + / - charged atoms: result from the loss
or gain of electrons



Cations – positive charge / lost electrons
Anions – negative charge / gain electrons
http://www.sci.tamucc.edu/pals/morvant/genchem/ato
mic/page6.htm
Radioactivity Discovered

1896 – Radioactivity discovered in
Uranium by Becquerel



Radiation: energy that is emitted from a
source and travels through space
Radioactivity: spontaneous radiation from the
nucleus of an atom
Marie/Pierre Curie – radium & polonium
Radioactivity

By 1900 3 types of radiation identified



Alpha – He ions w no elctrons; 1/10th the
speed of light; stopped by paper or clothing
Beta – electrons at high speeds / stopped by
a few mm of Al
Gamma – form of electromagnetic radiation;
more energetic than x-rays; stopped by
several cm of Pb or more concrete/ no mass
or charge
Rutherford’s Gold Foil







Resulted in a new model of the atom
Atoms contain a small dense nucleus
Electrons move around like bees in a hive
Diameter of nucleus 1/100,000 the size of the
atom
1920 Rutherford proposed neutral particles with
the same mass as protons
http://micro.magnet.fsu.edu/electromag/java/ruth
erford/
http://www.brainpop.com/science/matter/atomic
model/index.weml?&tried_cookie=true
Chadwick



Credited with the discovery of neutrons
Nobel Prize – 1935
Neutron Mass – 1.675 x 10-27 kg
Forces in the Nucleus




Like charges normally repel
Protons are strongly attracted to one
another in the nucleus
Also neutron/neutron and neutron/proton
attractions
These are the result of
NUCLEAR FORCES
Atomic Number & Mass Number


Atomic number – the number of protons in the
nucleus; defines what element an atom is
Mass number


Protons + Neutrons = Mass Number
Amu – atomic mass units – 1/12 the mass of a
carbon-12 atom



1 proton = 1.007276 amu
1 neutron = 1.008665 amu
http://www.sci.tamucc.edu/pals/morvant/genche
m/atomic/page8.htm
Isotopes






Atoms of the same element with different numbers of neutrons
http://www.sci.tamucc.edu/pals/morvant/genchem/atomic/page9.htm
Nuclide – general term for any isotope of any element
Each isotope has a % abundance in nature
Symbols for isotopes:
 Lithium – 6 / Lithium – 7
Isotopes differ by
 Number of neutrons
 Mass number
 Atomic mass
Isotopes Cont.


Of 1500 known isotopes, only 264 are
stable; others are radioactive
Radioactive decay – alpha or beta
particles are emitted and the nucleus
changes to form a new element or isotope
– continues until a stable form is reached
Isotopes Cont

Atomic mass – average of the mass of an
elements isotopes based on % abundance

Carbon – 12.011 amu



Carbon 13 = 1.11 %
Carbon 12 = 98.89 %
Example Problem – Find average atomic mass of
carbon:


.0111 x 13amu = .1443 amu
.9889 x 12 amu = 11.8668 amu
12.011 amu

Take relative abundance x mass of isotope and add together
Example Problem

Using the following information, determine
the atomic mass of chlorine: Two isotopes
are know: chlorine-35 (mass=35.0 amu)
and chlorine-37 (mass=37.0 amu). Their
relative abundances are 75.4% and 24.6%
respectively.
Sample Problems
Element
P
N
6
7
E
Mass *Avg.
#
Atomic
mass
Nitrogen-15
8
Mn(+2)
15
30
Relating Mass to Number of
Atoms

The MOLE




SI unit for amount of substance
Amt. of substance that contains as many
particles as there are atoms in exactly 12 g of
carbon-12
Counting unit – just like a dozen
Avogadro’s Number

Experimentally determined: 6.022 x 1023
Particles & the MOLE

4 Types of Particles






Atoms
Ions
Molecules
Formula Units
There are
6.022 x 1023 particles in 1
mole of any pure
substance
What is a pure
substance?
Classification of Matter
Classification of Matter
Matter
Pure Substances
Mixtures
Elements
Compounds
Homogeneous
Heterogeneous
Carbon, Nitrogen
NaCl, H(2)O
Salt Water
Any Solution
Beef Stew, Sand,
Different Phases
Molar Mass




The mass of 1 mole of a pure substance in a
unit of g/mol
Equal to atomic mass
A molar mass of an element contains 1 mol of
atoms
Examples:

Iron (Fe) = 55.85 g/mol
55.85 g of iron contains 6.022 x 1023 atoms

Water (HOH) = 2 mol H atoms x 1.01 g/mol = 2.02 g
+ 1 mol O atoms x 16.00 g/mol
= 16.00 g
18.02 g
Gram/Mole Conversions

What is the mass of 5.00 mol of Ni (in
grams)?





Examine
Plan
Organize
Evaluate
How many moles are in 70 g of carbon?
Conversions w/Avogadro’s
Number



How many atoms are in 3.0 mol of He?
How many atoms are in 52.63 g of Na?
How many H atoms are in 3 mol of water?

REMEMBER IF GOING FROM A COUNTING
UNIT TO GRAMS OR GRAMS TO
COUNTING UNIT – GO TO MOLES FIRST

gmolatoms
atomsmolg