Alright class we are going back to quantum numbers.

Alright class we are going back to quantum numbers.

I decided this would be a better lead into dipole then just throwing you

into the mess.

Do you remember Wave and Frequency?

• Do you remember plank. Well he is back it is time to work on his constant and what it means.

• Also the electromagnetic spectrum.

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Properties of Waves

Wavelength () is the distance between identical points on successive waves.

Amplitude is the vertical distance from the midline of a wave to the peak or trough.

Frequency () is the number of waves that pass through a particular point in 1 second (Hz = 1 cycle/s).

The speed (u) of the wave = x

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Maxwell (1873), proposed that visible light consists of electromagnetic waves.

Electromagnetic radiation is the emission and transmission of energy in the form of electromagnetic waves.

Speed of light (c) in vacuum = 3.00 x 108 m/s

All electromagnetic radiation x c

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A photon has a frequency of 6.0 x 104 Hz. Convert this frequency into wavelength (nm). Does this frequency fall in the visible region?

The wavelength of the green light from a traffic signal is centered at 522 nm. What is the frequency of this radiation?

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Problem 1

What is the wavelength (in meters) of an electromagnetic wave whose frequency is 3.64 x 107 Hz?

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Mystery #1, “Heated Solids Problem”Solved by Planck in 1900

Energy (light) is emitted or absorbed in discrete units (quantum).

E = h x Planck’s constant (h)h = 6.63 x 10-34 J•s

When solids are heated, they emit electromagnetic radiation over a wide range of wavelengths.

Radiant energy emitted by an object at a certain temperature depends on its wavelength.

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Calculate the energy (in joules) of a photons with a wavelength of 5.00 x 104 nm (infrared region).

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Calculate the energy (in joules) of a photons with a wavelength of 5.00 x 10-2 nm (x-ray region).

Problem 2

The energy of a photon is 5.87 x 10-20 J. What is its wavelength in nanometers?

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Light has both:1. wave nature2. particle nature

h = KE + W

Mystery #2, “Photoelectric Effect”Solved by Einstein in 1905

Photon is a “particle” of light

KE = h - W

h

KE e-

where W is the work function anddepends how strongly electrons are held in the metal

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When copper is bombarded with high-energy electrons, X rays are emitted. Calculate the energy (in joules) associated with the photons if the wavelength of the X rays is 0.154 nm.

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The work function of cesium metal is 3.42 x 10-19 J. Calculate the minimum frequency of light necessary to eject electrons from the metal.

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The work function of cesium metal is 3.42 x 10-19 J. Calculate the kinetic energy of the ejected electron if light of frequency 1.00 x 1015 s-1 is used for irradiating the metal.

Problem 3

The work function of titanium metal is 6.93 x 10-19 J. Calculate the energy of the ejected electrons if light of frequency 2.50 x 1015 s-1 is used to irradiate the metal.

KE = _____x 10-19 J

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Line Emission Spectrum of Hydrogen Atoms

Mystery #3, “Emission Spectra”

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1. e- can only have specific (quantized) energy values

2. light is emitted as e- moves from one energy level to a lower energy level

Bohr’s Model of the Atom (1913)

En = -RH ( )1n2

n (principal quantum number) = 1,2,3,…

RH (Rydberg constant) = 2.18 x 10-18J

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E = h

E = h

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Ephoton = E = Ef - Ei

Ef = -RH ( )1n2

f

Ei = -RH ( )1n2

i

i fE = RH( )

1n2

1n2

nf = 1

ni = 2

nf = 1

ni = 3

nf = 2

ni = 3

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Calculate the wavelength (in nm) of a photon emitted by a hydrogen atom when its electron drops from the n = 5 state to the n = 3 state.

Problem 4

What is the wavelength (in nm) of a photon emitted during a transition from ni=6 to nf=4 in the H atom?

ν = _____x 103 nm

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De Broglie (1924) reasoned that e- is both particle and wave.

Why is e- energy quantized?

u = velocity of e-

m = mass of e-

2r = n = hmu

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What is the de Broglie wavelength (in nm) associated with a 2.5 g Ping-Pong ball traveling at 15.6 m/s?

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Calculate the wavelength of the ‘particle’ in each of the following two cases: (a) The fastest serve ever recorded in tennis was about 150 miles per hour, or 68 m/s. Calculate the wavelength associated with a 6.0 x 10-2 kg tennis ball travelling at this speed.

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Calculate the wavelength of the ‘particle’ in each of the following two cases: (b) Calculate the wavelength associated with an electron (9.1094 x 10-31kg) travelling at this speed.

Problem 5

Calculate the wavelength (in nm) of a H atom (mass = 1.674 x 10-27 kg) moving at 7.00 x 102 cm/s.

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Chemistry in Action: Laser – The Splendid Light

Laser light is (1) intense, (2) monoenergetic, and (3) coherent

Light Amplification by Stimulated Emission of Radiation

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Chemistry in Action: Electron Microscopy

STM image of iron atomson copper surface

e = 0.004 nm

Electron micrograph of a normal red blood cell and a sickled redblood cell from the same person

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Shortcomings of Bohr’s model

•Did not account for the emission spectra of atoms containing more than on electron.

•Did not explain extra lines in the emission spectra for hydrogen when magnetic field is applied.

•Conflict with discovery of ‘wavelike’ properties – how can you define the location of a wave?

Heisenberg Uncertainty PrincipleIt is impossible to know simultaneously both the

momentum p (defined as mass times velocity) and the position of a particle with certainty.

Schrodinger Wave Equation

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t

triHtrV

m

h

δδψ

ψ

),(

2),(

82

2

2

=⎭⎬⎫

⎩⎨⎧

+∇−

In 1926 Schrodinger wrote an equation that described both the particle and wave nature of the e-

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Schrodinger Wave EquationWave function (ψ) describes:

1. energy of e- with a given ψ

2. probability of finding e- in a volume of space

Schrodinger’s equation can only be solved exactly for the hydrogen atom. Must approximate its solution for multi-electron systems.

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Schrodinger Wave Equation ψ is a function of four numbers called quantum numbers (n, l, ml, ms)

principal quantum number n

n = 1, 2, 3, 4, ….

n=1 n=2 n=3

distance of e- from the nucleus

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Where 90% of thee- density is foundfor the 1s orbital

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quantum numbers: (n, l, ml, ms)

angular momentum quantum number l

for a given value of n, l = 0, 1, 2, 3, … n-1

n = 1, l = 0n = 2, l = 0 or 1

n = 3, l = 0, 1, or 2

Shape of the “volume” of space that the e- occupies

l = 0 s orbitall = 1 p orbitall = 2 d orbitall = 3 f orbital


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l = 0 (s orbitals)

l = 1 (p orbitals)

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l = 2 (d orbitals)

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magnetic quantum number ml

for a given value of lml = -l, …., 0, …. +l

orientation of the orbital in space

if l = 1 (p orbital), ml = -1, 0, or 1if l = 2 (d orbital), ml = -2, -1, 0, 1, or 2


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ml = -1, 0, or 1 3 orientations is space

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ml = -2, -1, 0, 1, or 2 5 orientations is space

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(n, l, ml, ms)

spin quantum number ms

ms = +½ or -½


ms = -½ms = +½

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Existence (and energy) of electron in atom is described by its unique wave function ψ.

Pauli exclusion principle - no two electrons in an atomcan have the same four quantum numbers.



Each seat is uniquely identified (E, R12, S8)Each seat can hold only one individual at a time

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Schrodinger Wave Equationquantum numbers: (n, l, ml, ms)

Shell – electrons with the same value of n

Subshell – electrons with the same values of n and l

Orbital – electrons with the same values of n, l, and ml

How many electrons can an orbital hold?

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How many 2p orbitals are there in an atom?

How many electrons can be placed in the 3d subshell?

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List the values of n, ℓ, and mℓ for orbitals in the 4d subshell.

What is the total number of orbitals associated with the principle quantum number n=3?

Problem 6

Give the values of the quantum numbers associated with the orbitals in the 3p subshell.

n = ____

ℓ = ____

mℓ=____

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Problem 7

What is the total number of orbitals associated with the principle quantum number n=4.

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Energy of orbitals in a single electron atom

Energy only depends on principal quantum number n

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Energy of orbitals in a multi-electron atom

Energy depends on n and l

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“Fill up” electrons in lowest energy orbitals (Aufbau principle)

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The most stable arrangement of electrons in subshells is the one with the greatest number of parallel spins (Hund’s rule).

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Order of orbitals (filling) in multi-electron atom

1s < 2s < 2p < 3s < 3p < 4s < 3d < 4p < 5s < 4d < 5p < 6s

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Write the four quantum numbers for an electron in a 3p orbital.

Problem 8

Write the four quantum numbers for an electron in a 4d orbital.

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Electron configuration is how the electrons are distributed among the various atomic orbitals in an atom.

1s1

principal quantumnumber n

angular momentumquantum number l

number of electronsin the orbital or subshell

Orbital diagram

H

1s1

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What is the electron configuration of Mg?

What are the possible quantum numbers for the last (outermost) electron in Cl?

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What is the maximum number of electrons that can be present in the principle level for which n=3?

Problem 9

Calculate the total number of electrons that can be present in the principle level for which n=4

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An oxygen atom has a total of eight electrons. Write the four quantum numbers for each of the electrons in the ground state..

Problem 10

Write a complete set of quantum numbers for each of the electrons in boron.

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Paramagnetic

unpaired electrons

2p

Diamagnetic

all electrons paired

2p

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Outermost subshell being filled with electrons

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Write the ground state electron configuration for sulfur

Write the ground state electron configuration for palladium which is diamagnetic

Problem 11

Write the ground state configuration for phosphorus.

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Alright class we are going back to quantum numbers.

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Transcript of Alright class we are going back to quantum numbers.