1. IB Chemistry Power Points
Topic 02
Atomic Structure
Atomic Structure

2. 2.1: The nuclear atom 2.1 The nuclear atom 2.1 Application and skills
Understandings: • Atoms contain a positively charged dense nucleus composed of protons and neutrons (nucleons). • Negatively charged electrons occupy the space outside the nucleus. • The mass spectrometer is used to determine the relative atomic mass of an element from its isotopic composition.
Use of the nuclear symbol notation 𝑋𝑋 𝑍𝑍 𝐴𝐴 to deduce the number of protons, neutrons and electrons in atoms and ions.
Calculations involving non-integer relative atomic masses and abundance of isotopes from given data, including mass spectra.

3. ATOM.. Atomos
An atom is the smallest particle of an element that retains its identity in a chemical reaction.
Although early philosophers and scientists could not observe individual atoms, they were still able to propose ideas about the structure of atoms.

4. Once upon a time… Democritus atomic theory
Democritus reasoned that atoms were indivisible and indestructible.
Although, Democritus’s ideas agreed with later scientific theory, they did not explain chemical behavior
They also lacked experimental support because Democritus’s approach was not based on the scientific method.

5. Democritus who? John Daltons Atomic theory
By using experimental methods, Dalton transformed Democritus’s ideas on atoms into a scientific theory.
Dalton studied the ratios in which elements combine in chemical reactions.
All elements are composed of tiny indivisible particles called atoms.
Atoms of the same element are identical. The atoms of any one element are different from those of any other element.
Atoms of different elements can physically mix together or can chemically combine in simple whole-number ratios to form compounds.
Chemical reactions occur when atoms are separated from each other, joined, or rearranged in different combinations. Atoms of one element are never changed into atoms of another element as a result of a chemical reaction.

6. Thomson’s Plum Pudding model
Discovered Electrons
So maybe the atom is divisible after all
Thomson discovered the “electron” by conducting his cathode ray experiment.
He then proposed the plum pudding model of the atom.

7. Rutherford’s Gold-Foil Experiment
Rutherford’s results were that most alpha particles went straight through, or were slightly deflected.
What was surprising is that a small fraction of the alpha particles bounced off the gold foil at very large angles.
Some even bounced straight back toward the source.
Which lead to the discovery of the nucleus.

8. Review – Basic Atomic Structure
NUCLEUS
NUCLEUS
ELECTRONS
ELECTRONS
PROTONS
PROTONS
NEUTRONS
NEUTRONS
NEGATIVE CHARGE
POSITIVE CHARGE
POSITIVE
CHARGE
NEUTRAL
CHARGE

9. Review – Basic Atomic Model
Subatomic components
Relative
Mass
Charge
Proton 1 +1
Neutron
Electron
5 x 10-4 -1

10. A-Z notation mass number A element symbol atomic number Z
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The atomic number equals the number of protons. Each element has a unique atomic number.

11. Mass Number mass number A = protons + neutrons always a whole number
NOT the value given on the Periodic Table!
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12. Practice: determine the required values and write the chemical symbol in A-Z notation.
Chlorine-37
atomic #:
mass #:
# of protons:
# of electrons:
# of neutrons: 17 37 20

13. p+ > e- p+ < e- cation anion
Ions
ions are electrically charged atoms
Neutral atom
lose electrons
gain electrons
positive ion
negative ion
p+ > e-
p+ < e-
cation
anion

14. Practice: determine the required values for the negative chloride ion 37 Cl -1
atomic #:
mass #:
# of protons:
# of electrons:
# of neutrons: 17 37 18 20

15. Practice: determine the required values for the positive calcium ion 40 Ca +2
atomic #:
mass #:
# of protons:
# of electrons:
# of neutrons: 20 40 18

16. carbon-12 and carbon-14 are isotopes
Isotopes: Atoms of the same element with different mass numbers.
carbon-12 and carbon-14 are isotopes
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stable
similar chemical properties
radioactive

17. Radioisotopes and Their Uses
Radioisotopes are unstable isotopes that undergo radioactive decay. Radioisotopes have a number of uses:
U-235 is used as fuel in nuclear reactors
Co-60 is used in cancer radiation therapy
C-14 is used as a tracer and for archeological dating
Am-241 is used in smoke detectors

18. Mass Spectrometer
A mass spectrometer is used to detect, identify and measure the abundance of different atoms, molecules or molecular fragments.
Mass spectrometer studies are used to determine the average atomic mass for an element. The operation of a mass spectrometer can be divided into 5 steps:
Vaporization
Ionization
Acceleration
Deflection
Detection

19. Vaporization: the element to be analyzed is heated and vaporized (gaseous form).
=>
Chapter 12

20. Ionization: the gaseous element is injected slowly into a vacuum chamber where the atoms are bombarded by electrons. This forms ions positive ions X (g) + e-  X+(g) + 2 e-
=>
Chapter 12

21. Acceleration: the gaseous ions are accelerated through an electric field (towards a negative plate)
=>
Chapter 12

22. Deflection: Ions are deflected in an adjustable magnetic field oriented at right angles to the path. Heavier ions are deflected less.
=>
Chapter 12

23. => Detection: ions of a specific mass are counted Chapter 12
Chapter 12

24. A sample mass spectrograph
Output provides the abundances of the elemental isotopes of different relative mass

25. Atomic Mass is Relative
12C atom = × g
atomic mass unit (amu)
1 amu = 1/12 the mass of a 12C atom
1 p = amu 1 n = amu 1 e- = amu
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26. Average Atomic Mass Avg. Atomic Mass
a weighted average of all isotopes of an element
based on the % abundance data from mass spectrometer
this value is found on the Periodic Table
Avg.
Atomic
Mass

27. Average Atomic Mass
EXAMPLE: Calculate the average atomic mass of chlorine if its abundance in nature is 75.77% 35Cl, and 24.23% 37Cl.
Avg.
Atomic
Mass
35.48
amu

28. Average Atomic Mass
Gallium has two naturally occurring isotopes, Ga-69 and Ga-71, with masses of amu and amu, respectively. Calculate the percent abundances of these isotopes
Average relative mass of Ga amu
Solve to get 60.1% Ga-69 and 39.9% Ga-71

29. 2.2 Electron Configuration
Understandings
Emission spectra are produced when photons are emitted from atoms as excited electrons return to a lower energy level.
The line emission spectrum of hydrogen provides evidence for the existence of electrons in discrete energy levels, which converge at higher energies.
The main energy level or shell is given an integer number, n, and can hold a maximum number of electrons, 2n2.
A more detailed model of the atom describes the division of the main energy level into s, p, d and f sub-levels of successively higher energies.
Sub-levels contain a fixed number of orbitals, regions of space where there is a high probability of finding an electron.
Each orbital has a defined energy state for a given electronic configuration and chemical environment and can hold two electrons of opposite spin.
Applications -and Skills
Description of the relationship between colour, wavelength, frequency and energy across the electromagnetic spectrum.
Distinction between a continuous spectrum and a line spectrum.
Description of the emission spectrum of the hydrogen atom, including the relationships between the lines and energy transitions to the first, second and third energy levels.
Recognition of the shape of an s atomic orbital and the px, py and pz atomic orbitals.
Application of the Aufbau principle, Hund’s rule and the Pauli exclusion principle to write electron configurations for atoms and ions up to Z = 36.

31. All EM radiation is fundamentally the same
All EM radiation is fundamentally the same. The only difference between a gamma ray and a radio wave is the frequency/wavelength/energy.

32. Visible light is one category of EM radiation
Visible light is one category of EM radiation. The visible light spectrum is subdivided into six “colors”.
White Light
Prism
RED
ORANGE
YELLOW
GREEN
BLUE
VIOLET

33. A continuous spectrum includes all wavelengths of radiation in a given range. When white light is passed through a prism a continuous spectrum is produced.

34. Colored lights do not emit all the wavelengths of the visible light spectrum. For example, a red light emits mostly wavelengths from the red end of the spectrum. An energized gas sample will emit light of specific wavelengths characteristic of the gas. This is called a line spectrum

35. Emission spectra are unique for each element

37. a central dense positive nucleus composed of protons and neutrons.
The Bohr model of the atom was developed using information from hydrogen emission spectrum studies. Bohr envisioned an atomic model with:
a central dense positive nucleus composed of protons and neutrons.
negative electrons at specific energies orbit the nucleus
mostly empty space. Nucleus is 10-5 times smaller than atom.

38. Bohr further stated that the orbiting electrons occupy discrete energy levels. Electrons can only “jump” between energy levels if they absorb or emit a specific amount of energy.

39. Bohr saw the line spectrum of hydrogen as a direct result of energized electrons releasing a specific amount of energy by emitting a photon of light at a certain wavelength. The different lines in the hydrogen spectrum were evidence for a number of different energy levels.

40. Visible spectrum for hydrogen atom
lower energy longer wavelength
higher energy
shorter wavelength
Visible spectrum for hydrogen atom
convergence

41. Electrons fill the lowest energy orbitals first.
Lower energy = more stable electron orbit
Electrons fill the lowest energy orbitals first.
Each orbital has a maximum possible number of electrons. As you should recall:
1st energy level (ground state) = 2 electrons
2nd energy level = 8 electrons

42. s p d f 1A 2A 3B 4B 5B 6B 7B 8B 1B 2B 3A 4A 5A 6A 7A 8A
group # = # valence (outside) e- s 1 2 3 4 5 6 7 p
Row =
# shells d f

43. Electron Configuration
1s1
group #
# valence e-
possibilities are:
s: 1 or 2
p: 1-6
d: 1-10
f: 1-14
Total e- should equal
Atomic #
row #
shell #
possibilities are 1-7
7 rows
subshell
possibilities are
s, p, d, or f
4 subshells
What element has an electron configuration of 1s1?

44. Practice: Ask these questions every time you have to write an electron configuration
Lithium:
find the element on the periodic table
what is the period number?
how many shells?
what is the group number?
how many valence electrons?
what subshell(s) does Li have?
what is the electron configuration?
atomic # = 3 2 2 1 1 s
1s2 2s1

45. Practice: Ask these questions every time you have to write an electron configuration
Boron:
find the element on the periodic table
what is the row #?
how many shells?
what is the group #?
how many valence electrons?
what subshell(s) does B have?
what is the electron configuration?
atomic # = 5 2 2 3 3 p
1s2 2s2 2p1

46. Order of Electron Subshell Filling: It does not go “in order”
2p6
3s2
3p6
3d10
4s2
4p6
4d10
4f14
5s2
5p6
5d10
5f14
6s2
6p6
6d10
7s2
7p6
1s2
2s2
2p6
3s2
3p6
4s2
3d10
4p6
5s2
4d10
5p6
6s2
4f14
5d10
6p6
7s2
5f14
6d10
7p6

47. Subshells d and f are “special”
group # = # valence e- 1 2 3 4 5 6 7 3d d
period # = # e- shells 4d 5d 6d f 4f 5f

48. Electron Configuration
1s1
group #
# valence e-
possibilities are:
s: 1 or 2
p: 1-6
d: 1-10
f: 1-14
Total e- should equal
Atomic #
row #
shell #
possibilities are 1-7
7 rows
subshell
possibilities are
s, p, d, or f
4 subshells
What element has an electron configuration of 1s1?

49. Practice: Ask these questions every time you have to write an electron configuration
Lithium:
find the element on the periodic table
what is the row #?
how many shells?
what is the group #?
how many valence electrons?
what subshell(s) does Li have?
what is the electron configuration?

50. Practice: Ask these questions every time you have to write an electron configuration
Boron:
find the element on the periodic table
what is the row #?
how many shells?
what is the group #?
how many valence electrons?
what subshell(s) does B have?
what is the electron configuration?

51. Order of Electron Subshell Filling: It does not go “in order”
2p6
3s2
3p6
3d10
4s2
4p6
4d10
4f14
5s2
5p6
5d10
5f14
6s2
6p6
6d10
7s2
7p6