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Title: Atomic Structure and the periodic table


1
Atomic Structure and the periodic table
  • Chapter 7

2
Characterestics Of Light
  • Spectroscopy is the study of the interaction
    between radiation (electromagnetic radiation, or
    light, as well as particle radiation) and
    matter.
  • Spectrometry is the measurement of these
    interactions and an instrument which performs
    such measurements is a spectrometer or
    spectrograph.
  • A plot of the interaction is referred to as a
    spectrum.

3
  • The spectrum of colors emitted by atoms that have
    been heated to high temperatures is called an
    atomic emission spectrum.
  • Light is electromagnetic radiation, a wave of
    electric and magnetic field that travels at the
    speed of light(3.00?108m/s).

4
Dispersion of light as it passes through a prism
5
  • Light waves travel at a constant speed. Because
    of this there is a one to one relationship
    between light's wavelength and its frequency. If
    waves are short, there must be more of them in a
    set amount of time to travel the same distance in
    that time (the same speed).
  • The unit of frequency is Hertz(Hz) 1Hz1cycle/sec

6
  • The intensity of the light is proportional to the
    square of the amplitude of the wave.
  • The distance between adjacent peaks gives its
    wavelength,?.
  • ?c/?

7
  • Our eyes detect electromagnetic radiation with
    wavelengths from 700nm(red light) to 400nm(violet
    light). The electromagnetic radiation in this
    range is called as visible light.
  • Ultraviolet radiation(UV) has a frequency higher
    than that of violet light its wavelength is less
    than about 400nm.
  • Infrared radiation(IR) has a frequency lower than
    that of red light its wavelength is greater than
    about 800nm.
  • Microwaves, used in radars and microwave ovens,
    have wavelengths in the millimeter to centimeter
    range.

8
Class Practice
  • What is the wave length of orange light of
    frequency 4.8?1014Hz?

9
Quanta and photon
  • Electromagnetic radiation is a stream of many
    packets of electromagnetic energy. These packets
    are called as photons.
  • The photon is the elementary particle responsible
    for electromagnetic phenomena.
  • The photon travels (in vacuum) at the speed of
    light, c.
  • Energy is transferred in discrete amounts called
    as quantum(plural quanta)
  • Like all quanta, the photon has both wave and
    particle properties (wave particle duality ).
  • The more intense the light the greater the number
    of photons passing a given point each second.
  • The relation between the energy , E of a photon
    and the frequency ?, of the radiation as Eh?
    where h is Planks constant, with a value of
    6.63?10-34 J.s

10
Class Practice
  • What is the energy in kilojoules per mole of
    photons of amber light of frequency 5.2?1014 Hz?
  • A students favorite radio station broadcasts a
    signal at a frequency of 91.5MHz. What is the
    energy of the photons broadcast?

11
Home work
  • Page 314
  • 7.12,7.14 and 7.18

12
Atomic Spectra and energy levels
  • The Lyman series is the wavelengths in the
    ultraviolet (UV) spectrum of the hydrogen atom,
    resulting from electrons dropping from higher
    energy levels into the n 1 orbit.
  • The Balmer series is the wavelengths inthe
    visible light spectrum of the hydrogenatom,
    resulting from electrons falling fromhigher
    energy levels into the n 2 orbit.
  • The Paschen series is the wavelengths in the
    infrared spectrum of the hydrogenatom, resulting
    from electrons falling fromhigher energy levels
    into the n 3 orbit.

13
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14
  • Rydberg formula for hydrogen
  • Where
  • ?vac is the wavelength of the light emitted in
    vacuum, RH is the Rydberg constant for hydrogen.

15
Bohrs atom
  • The Bohr model of the hydrogen atom where
    negatively charged electrons confined to atomic
    shells encircle a small positively charged
    atomic nucleus, and that an electron jump between
    orbits must be accompanied by an emitted or
    absorbed amount of electromagnetic energy h?.
    The orbits that the electrons travel in are shown
    as grey circles their radius increases n2, where
    n is the principal quantum number. The 3?2
    transition depicted here produces the first line
    of the Balmer series, and for hydrogen (Z 1)
    results in a photon of wavelength 656 nm (red).

16
Wavelike properties of electrons
  • Louis-Victor formulated the de Broglie
    hypothesis, claiming that all matter, not just
    light, has a wave-like nature he related
    wavelength (denoted as ? ),
  • and momentum (denoted as p)
  • This is a generalization of Einstein's equation
    above, since the momentum of a photon is given by
    pE/c and the wavelength by ?c/f, where c is the
    speed of light in vacuum.

17
Class Practice
  • Calculate the wavelength of a marble of mass 5.00
    g traveling at 1.00m/s.

18
Models Of Atoms
  • Our current model of a hydrogen atom was proposed
    by the Austrian scientist Erwin Schrodinger. He
    devised an equation (Schrodingers Equation)that
    enabled him to calculate the shape of the wave
    associated with any particle.
  • Quantum theory is based on Schrodinger's
    equation H?E? in which electrons are considered
    as wave-like particles whose "waviness" is
    mathematically represented by a set of wave
    functions ?, obtained by solving Schrodinger's
    equation.

19
Atomic orbitals
  • The wave function for an electron is so important
    that it is given a special name an atomic
    orbital. Atomic orbitals have characterestic
    energy and shapes. The different shapes are
    identified by different letters.
  • An s orbital is a spherical cloud that becomes
    less dense as the distance from the nucleus
    increases. p-orbital is a cloud with two lobes
    on opposite sides of the nucleus. The lobes are
    separated by a nodal plane. The d and f orbital
    have complicated shapes.

20
The shapes of different orbitals
  • As for p-orbital the opposite shades of color
    denote opposite signs of wave.
  • The location of an electron is best described as
    a cloud of probable locations.

21
Home work
  • Page 314
  • 7.30,7.34,7.36

22
Energy levels
  • Each orbital has a characteristic energy. When
    Schrodinger solved his equation, he found that
    the allowed energies of the electron in a
    hydrogen atom are given by the expression E-hRH
    /n² n1,2
  • RH, is called as the Rydbergs constant. The
    experimental value of Rydbergs
    constant3.29?1015 Hz
  • Whenever the atom emits a photon of radiation,
    the energy emitted is equal to the difference in
    two of the allowed energy levels. Each transition
    corresponds to a line in the spectrum of atomic
    hydrogen.

23
Class Practice
  • Calculate the wavelength of a photon emitted by a
    hydrogen atom when an electron makes a transition
    from an orbital with n3 to one with n2.

24
Quantum Numbers
  • Schrodinger found that each atomic orbital is
    identified by three numbers called quantum
    numbers. The quantum number n is called the
    principal quantum number. The orbital angular
    momentum quantum number, l, specifies the shape
    of the orbital. The magnetic quantum number,ml
    specifies the individual orbital of a particular
    shape.

25
  • An orbital is specified by three quantum numbers
    orbitals are organized into shells and subshells.
  • An electron has the property of spin the spin
    is described by the quantum number ms which may
    have one of the two values.

26
Class Practice
  • Calculate the total number of orbitals in a shell
    with n6.

27
Orbital energies
  • In a many-electron atom, because of the effects
    of penetration and shielding, s-electrons have a
    lower energy than p-electrons of the same shell
    the order of increasing orbital energies within a
    given shell is sltpltdltf.

28
Paulis Exclusion Principle
  • No more than two electrons may occupy any given
    orbital. When two electrons do occupy one
    orbital, their spins must be paired.

29
Hunds Rule
  • If more than one orbital in a subshell is
    available, electrons will fill empty orbitals
    before pairing in one of them.

30
  • The ground state electron configuration of an
    atom of an element with atomic number Z is
    predicted by adding Z electrons to available
    orbitals so as to obtain the lowest total energy.

31
Class Practice
  • Predict the ground state electron configuration
    of a sulfur atom and draw the box diagram.
  • Predict the ground state electron configuration
    of a magnesium atom.

32
Electron configuration of an ion.
  • To predict the electron configuration of a cation
    , remove outermost electrons in the order np,
    ns,and(n-1)d
  • For an anion, add electrons until the next noble
    gas configuration has been reached.

33
Home work
  • Page 315
  • 7.42,7.44,7.48,

34
Periodicity of Atomic Properties
  • Atomic radius The atomic radius is defined as
    half the distance between the centers of
    neighboring atoms.
  • Atomic radii generally increase down a group and
    decrease from left to right.

35
Ionic radius
  • The ionic radius of an element is its share of
    the distance between neighboring ions in an ionic
    solid.
  • Ionic radii generally increase down a group and
    decrease from left to right across a period.
    Cations are smaller than their parent atoms and
    anions are larger.

36
Class Practice
  • Arrange each pair of ions in order of increasing
    ionic radius(a)Mg2 and Ca2
  • (b)O2- and F-

37
Ionization energies
  • The ionization energy of an element is the energy
    needed to remove an electron from an atom of the
    element in the gas phase.
  • For the first ionization energy we start with a
    neutral atom.

38
First and second ionization energies
  • For the first ionization energy,I1, we start with
    the neutral atom, for example, for copper,
    Cu(g)?Cu(g) e-(g)
  • I1 (energy of Cu e-)-(energy of Cu)
  • The experimental value for copper is
    785kJ/mol.The second ionization energy I2 is the
    energy required to remove an electron from a
    singly charged gas phase cation. For copper
  • Cu(g)? Cu2(g) e-(g)
  • I2(energy of Cu2 e-)-(energy of Cu)For copper
    I2 1958kJ/mol

39
  • The second ionization energy is always greater
    than the first because once the first electron is
    pulled off, you are now trying to remove the
    second electron from a positively charge ion.
    Because of the electrostatic attraction between
    and -, it is more difficult to pull an electron
    away from a positively charge ion than a neutral
    atom.

40
  • The first ionization energy is highest for
    elements close to helium and is lowest for
    elements close to cesium. Second ionization
    energies are higher than first ionization
    energies (of the same element). An ionization
    energy is very high if the electron is to be
    expelled from a closed shell.

41
Electron affinity
  • The electron affinity is a measure of the energy
    change when an electron is added to a neutral
    atom to form a negative ion. For example, when a
    neutral chlorine atom in the gaseous form picks
    up an electron to form a Cl- ion, it releases an
    energy of 349 kJ/mol or 3.6 eV/atom.
  • An electron affinity of -349 kJ/mol and this
    large number indicates that it forms a stable
    negative ion.
  • Small numbers indicate that a less stable
    negative ion is formed. Groups VIA and VIIA in
    the periodic table have the largest electron
    affinities.

42
  • Elements with the highest electron affinities are
    those close to oxygen, fluorine, and chlorine.
    Group 17 atoms can acquire one electron with a
    release of energy and group 16 atoms can accept
    two electrons with chemically attainable
    energies. The halogens typically form X- ions and
    group 16 elements form X2- ions.

43
Diagonal relationship
  • On moving diagonally across the periodic table,
    the elements show certain similarities in their
    properties which are quite prominent in some
    cases as shown below. This is called a diagonal
    relationship.

44
.
  • A Diagonal Relationship is said to exist between
    certain pairs of diagonally adjacent elements in
    the second and third periods of the periodic
    table. These pairs (Li Mg, Be Al, B Si
    etc.) exhibit similar properties for example,
    Boron and Silicon are both semiconductors form
    halides that are hydrolysed in water and have
    acidic oxides.
  • Such a relationship occurs because crossing and
    descending the periodic table have opposing
    effects.
  • On crossing a period of the periodic table, the
    size of the atoms decreases, and on descending a
    group the size of the atoms increases. Similarly,
    on moving along the period the elements become
    progressively more covalent, less reducing and
    more electronegative whereas on descending the
    group the elements become more ionic, more basic
    and less electronegative.

45
  • Thus, on both descending a group and crossing by
    one element the changes cancel each other out,
    and elements with similar properties which have
    similar chemistry are often found - the atomic
    size, electronegativity, properties of compounds
    (and so forth) of the diagonal members are
    similar.

46
Homework
  • Page 315
  • 7.62,7.64,
  • Page 316
  • 7.70,7.78,7.80,7.90
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