CHE1112 Lecture I-part II PDF

Summary

This document is a lecture on the Bohr model of the atom, focusing on the hydrogen atom and its spectral lines. It explains the theoretical foundations in terms of physics and quantum mechanics.

Full Transcript

The Bohr Model of the Atom
Which series releases most energy?

The larger the fall the
{ExcitedElectrons*} greater the energy
Bohr’s model for hydrogen atom
 The Bohr model of hydrogen (original argument)
Bohr explained the line
spectrum of hydrogen with a
model in which the single
Ln=rp=m vn rn
hydrogen electron can only be
in certain definite orbits.
In the nth allowed orbit, the
electron has orbital angular
momentum nh/2π.
Bohr proposed that angular
momentum is quantized.

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 The Bohr model of hydrogen
Let’s use a different argument based on
deBroglie waves to obtain the same conclusions.

Think of a standing wave with wavelength λ
that extends around the circle.

2p rn = nln
Q: How is the momentum of the atomic electron
related to its wavelength ? (remember the Prince)
h
2p rn = nln = n
mvn
h Same as the Bohr
mvn rn = n quantization
2p condition
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 The Bohr model of hydrogen
(The mass m is that
Now let’s use a Newtonian
h of the electron.)
mvn rn = n argument for a planetary
2p model of the atom but use
the Bohr quantization
condition.

e mvn2 2
Fe = = Fc = Balance electrostatic
4pe 0 rn 2
rn and centripetal forces

e2 mvn 2 rn 2 (mvn rn )2 e2 (nh / 2p )2
= = Þ =
4pe 0 rn rn 4pe 0 rn
Here we used the Bohr quantization condition
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 The Bohr model of hydrogen (Bohr radius)

e 0 (nh) 2
rn =
p me2

e 0 (nh)2
rn = Þ r = n 2
a0
p me 2 n

Here n is the “principal quantum number” and a0 is the “Bohr
radius”, which is the minimum radius of an electron orbital.

e 0h 2
a0 = Þ r = n 2
a0 a0 = 5.29 ´10-11 m
p me 2 n

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The Bohr model of hydrogen (Energy levels, derivation)

h e2
mvn rn = n Þ vn =
2p e 0 (2nh)
1 me 4
K n = mvn 2 = 2 2
2 8n h
e 0 (nh) 2
-me4
rn = En = K n +Un = 2 2 2
p me2 e 0 8n h
-me-e 2 4
Un = = 2 2 2
4pe 0 rn e 0 4n h Note that E and U are
negative (1/8-1/4=-1/8)
This expression for the allowed energies can be rewritten and used
to predict atomic spectral lines !
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The Bohr model of hydrogen (Energy levels)

-me4 -hcR me4
En = 2 2 2 = 2 ; R =
e 0 8n h n 8 e 0 2 h 3c

-hcR Here R is the “Rydberg
En = 2
n constant”, R=1.097 x 107 m-1
Also hcR = 13.60 eV is a useful result.

Question: How can we find the energies of
photon transitions between atomic levels ?
hc 1 1
= EUpper - ELower = hcR( - )
l n 2
Upper n 2
Lower

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The Bohr model of hydrogen (It works)

1 1 1
= R( - )
l n 2
Upper n 2
Lower

Here R is the Rydberg
constant, R=1.097 x 107 m-1

If nupper=3, nlower=2, let’s calculate the
wavelength.
1 1 1 -1 1 1
= R( 2 - 2 ) = (1.097 ´10 m )( - ) = 656.3nm
7

l 2 3 4 9

Balmer Hα line, agrees with experiment within 0.1%
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 Hydrogen spectrum (also has other spectral lines)
The line spectrum at the bottom of the previous slide is not the entire
spectrum of hydrogen; it is just the visible-light portion.
Hydrogen also has series of spectral lines in the infrared and the
ultraviolet.

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 Hydrogen-like atoms
The Bohr model can be applied to any atom with a single electron. This
includes hydrogen (H) and singly-ionized helium (He+). See the Figure
below.

-hcR me4
En = 2 ; R =
n 8 e 0 2 h 3c
Question: How should this
formula be modified for
singly-ionized helium ?
Ans: He has 2p. If an
atom is singly ionized,
then rnrn/ZEnZ2E

Ze2 (nh / 2p )2
= But the Bohr model does not
4pe 0 rn work for other atoms; need QM
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Copyright © 2012 Pearson Education Inc.
Copyright © 2012 Pearson Education Inc.
Atomic Spectra and the Bohr Atom

Notice that the wavelength calculated from
the Rydberg equation matches the wavelength
of the green colored line in the H spectrum.

  4.865 x 10-7 m E  0.4088 x 10-18 J
 Limitations of Bohr Theory
theory fails to explain :
could not account the spectra of atoms
more complex than hydrogen.
to give any information regarding the
distribution and arrangement of electrons
in atoms.
does not explain the experimentally
observed variations in intensity of the
spectral lines of an element.
 the transitions of electrons from one level to
another, the rate at which they occur or the
selection rules which apply to them.
the fine structure of spectral lines.
Bohr’s theory does not throw any light on it.
when electric Stark effect or magnetic
fieldZeeman effec is applied to the atom,
each spectral line is splitted into several
lines.
 Extensions of Bohr Theory
Finite nuclear mass
Elliptical orbits (Bohr-Sommerfeld
model)s
we assumed that the nucleus is so
massive that it is effectively at rest.
But the mass of the nucleus is finite and
the classical model of the atom therefore
envisages that the electron and the
nucleus both revolve around their
common centre of mass.