CHAPTER 5

CHAPTER 5 The Structure of Atoms

Fundamental ParticlesThe following three fundamental particles make up atoms. The table below lists these particles together with their masses and their charges.

Structure of the Atom Videos 1. The earliest models http://www.youtube.com/watch?v=BhWgv0STLZs&feature=player_embedded 2. Smaller than the Smallest http://www.youtube.com/watch?v=WmmglVNl9OQ&feature=player_embedded 3. The Rutherford Model http://www.youtube.com/watch?v=FfY4R5mkMY8&feature=player_embedded 4. The Bohr Model http://www.youtube.com/watch?v=hpKhjKrBn9s&feature=player_embedded 5. Spectra http://www.youtube.com/watch?v=5z2ZfYVzefs&feature=player_embedded 6. Wave Mechanics http://www.youtube.com/watch?v=1bpG1lEjJfY&feature=player_embedded Take notes over each video. Check calendar for due date.

The Atomic Weight Scale & Atomic Weights define mass of 12C as 12 amu exactly 1 amu = (1/12) mass of 12C Ex. 1) Calculate the number of atomic mass units in one gram. mass of one 24Mg atom = 24.3050 amu experimentally determined 1 mol of 24Mg atoms = 24.3050 g

atomic weight - weighted average of the masses of its constituent isotopes • Ex 2) Naturally occurring chromium consists of four isotopes. It is 4.31% 2450Cr, mass = 49.946 amu, 83.76% 2452Cr, mass = 51.941 amu, 9.55% 2453Cr, mass = 52.941 amu, and 2.38% 2454Cr, mass = 53.939 amu. Calculate the atomic weight of chromium.

Naturally occurring Lithium exists as two isotopes, 6Li (mass = 6.015 amu) and 7Li (mass = 7.016 amu). The atomic weight is 6.941 amu. Which isotope is more abundant? Why? • Ex 3) The atomic number of boron is 10.811 amu. The masses of the two naturally occurring isotopes 510B and 511B, are 10.013 and 11.009 amu, respectively. Which isotope is most common? Calculate the fraction and percentage of each isotope. • requires a little algebra • remember X + (1-X) = 1

Ex 4) Nickel has five isotopes that occur in the following percentages and isotopic masses. What is the isotopic mass of 60Ni? IsotopeMass (amu)% 58Ni 57.935 68.27 60Ni ? 26.10 61Ni 60.931 1.13 62Ni 61.928 3.59 64Ni 63.928 0.91

Mass Spectrometry & Isotopic Abundances • Mass spectrometry is an analytical technique that measures the mass-to-charge ratio of charged particles. It is most generally used to find the composition of a sample by generating a mass spectrum representing the masses of sample components. The mass spectrum is measured by a mass spectrometer. http://www.youtube.com/watch?v=J-wao0O0_qM

An analytical technique for identification of chemical structures, determination of mixtures, and quantitative elemental analysis, based on application of the mass spectrometer. • Francis Aston - devised first mass spectrograph

In a mass spectograph ions pass down an evacuated path inside a magnet • Four factors which determine particle’s path in mass spectrometer • . accelerating voltage • . magnetic field strength • . masses of particles • . charge on particles

Mass spectrometers consist of three basic parts: an ion source, a mass analyzer, and a detector system. The stages within the mass spectrometer are: • Production of ions from the sample • Separation of ions with different masses • Detection of the number of ions of each mass produced • Collection of data to generate the mass spectrum

This technique is applicable in: • identifying unknown compounds by the mass of the compound molecules or their fragments • determining the isotopic composition of elements in a compound • determining the structure of a compound by observing its fragmentation • quantifying the amount of a compound in a sample using carefully designed methods • studying the fundamentals of gas phase ion chemistry (the chemistry of ions and neutrals in vacuum) • determining other important physical, chemical, or even biological properties of compounds with a variety of other approaches

How does a mass spectrometer work? Since different chemicals have different masses, this info is used to determine what chemicals are present in a sample. For example, table salt: • NaCl, may be vaporized, turned into gas and ionized into ions, electrically charged particles (Na+ and Cl-), in the first phase of the mass spectrometry.

The sodium ions are monoisotopic, with mass 23 u. Chloride ions have two isotopes of mass 35 u (~75%) and mass 37 u (~25%). Since they have a charge, the speed and direction may be changed with an electric or magnetic field. • An electric field accelerates the ions to a high speed. Next they are directed into a magnetic field which applies a force to each ion perpendicular to the plane of the particles' direction of travel and the magnetic field lines.

This force deflects the ions (makes them curve instead of traveling in a straight line) to varying degrees depending on their mass-to-charge ratio. Lighter ions get deflected more than the heavier ions. This is due to Newton’s 2nd law of Motion. The acceleration of a particle is inversely proportional to its mass. • Therefore, the magnetic field deflects the lighter ions more than it does the heavier ions.

The detector measures the deflection of each resulting ion beam. • From this measurement, the mass-to-charge ratios of all the ions produced in the source can be determined. So the chemical composition of the original sample (both sodium and chlorine are present in the sample) and the isotopic compositions of its constituents (the ratio of 35Cl to 37Cl atoms) can be determined.

Electromagnetic Radiation relationship for electromagnetic radiation c = l u c = velocity of light - 3.00 x 108 m/s

Ex. 5) What is the frequency of green light of wavelength 5200 Å? • Max Planck - 1900 • energy is quantized • light has particle character • Planck’s equation Ex. 6) What is energy of a photon of green light with wavelength 5200 Å?

Photoelectric Effect Particles – have mass, volume, and are countable. Photon – light composed of particles light has particle-like behavior light can strike the surface of some metals and cause an electron to be ejected Ex. ~ electronic door openers ~ light switches for street lights ~ exposure meters for cameras

Albert Einstein explained the photoelectric effect in 1905 • 1921 Nobel Prize in Physics • electrons are particle like b/c energy from a photon transfers to e- during collisions. If you increase energy, more electrons get kicked off. Each individual photon makes a spark, 1 e- per photon. The more intense the light, the more photons. Light strikes the surface of various metals and causes electrons to be ejected.

Atomic Spectra emission spectrum electric current passing through a gas in a vacuum tube (at very low pressure) causes the gas to emit light emission or bright line spectrum

absorption spectrum shining a beam of white light through a sample of gas gives an absorption spectrum shows the wavelengths of light that have been absorbed

Spectra are fingerprints of elements use spectra to identify elements can even identify elements in stars

The Origin of Spectral Lines Light of a characteristic wavelength (& frequency) is emitted when electron falls from higher E (orbit) to lower E (orbit) origin of emission spectrum light of a characteristic wavelength (& frequency) is absorbed when electron jumps from lower E (orbit) to higher E (orbit) origin of absorption spectrum

Atomic Spectra • how atoms talk to us” • we have to interpret their language • Bohr, Schrodinger, and Heisenberg were some of the first scientists to translate the language of atoms Ex. 7) An orange line of wavelength 5890 Å is observed in the emission spectrum of sodium. What is the energy of one photon of this orange light?

Quantum Mechanics • Werner Heisenberg - 1927 • Uncertainty Principle • It is impossible to determine simultaneously both the position & momentum of an electron. Why? The act of measuring a very small particle changes its position, so it is impossible to precisely determine both the position and momentum of that object. • electron microscopes use this phenomenon • devices for detecting motion of electron disturbs its position

Quantum Numbers Quantum numbers are description of the orbitals; solutions of the Schrodinger, Heisenberg & Dirac wave equations the quantum #’s help symbolize the solutions

There are four quantum numbers which describe the relative position and energy of an electron in an atom. 1. Principal quantum number 2. Angular momentum quantum number 3. Magnetic quantum number 4. Spin quantum number

Principal Quantum Number • Symbol “n” – refers to energy level n = 1, 2, 3, …  • The principal quantum number describes the relative distance from the nucleus. It is often referred to as Energy Level or Shell. • electron’s energy depends principally on n

Angular momentum, 2nd quantum number • angular momentum, tells shape of the atomic orbitals • Atomic Orbitals - regions of space where the probability of finding an electron around an atom is highest ~ volume that the electrons occupy 90-95% of the time • symbol ℓ to find ℓ plug into n-1 n=1 n=2 n=3 …. n=8 ℓ =0 ℓ = 0, 1 ℓ = 0, 1, 2 ℓ = 0, 1, 2, 3, 4, 5, 6, 7

represents the sublevels within an energy level: s, p, d, f (code letters for the shapes of orbitals) • s=0 • p=1 • d=2 • f=3 • Quantum number -ℓ ℓ = 0, 1, 2, 3, 4, 5, .......(n-1) ℓ = s, p, d, f, g, h, .......(n-1)

s orbitals s orbitals are spherical in shape. Every energy level has an s orbital s orbitals have angular momentum quantum number (l) equal to 0.

p orbitals p orbitals are shaped like dumbbells or peanuts. They are oriented along the x, y, and z coordinates. They have an angular momentum quantum number (l) equal to 1. 3 per n level, px, py, pz l = 1

p orbitals

d orbitals start with n = 3 4 clover leaf shaped and 1 peanut shaped with a doughnut around it on Cartesian axes and rotated 45o 5 per n level l= 2 ml = -2,-1,0,+1,+2 5 values of ml ml = Magnetic quantum number (info in a few slides)

d orbitals

f orbitals start with n = 4 most complex shaped orbitals 7 per n level, complicated names l = 3 ml = -3,-2,-1,0,+1,+2, +3 7 values of ml important effects in lanthanides & actinides

f orbitals

Magnetic quantum numbers • 3rd quantum number • symbol ml • Helps tell orientation of orbitals ml= - l to + l

theoretically, we can continue this series on to g, h, i, orbitals l=0 ml=0 • only 1 value s orbital l=1 ml= -1, 0, 1 • 3 values p orbitals l=2 ml= -2, -1, 0, 1, 2 • 5 values d orbitals l=3 ml= -3, -2, -1, 0, 1, 2, 3 • 7 values f orbitals

Spin Quantum Number • 4th quantum number, symbol = ms • ms = +1/2 or -1/2 • tells us the spin and orientation of the magnetic field of the electrons

spin effects • every orbital can hold up to two electrons • one spin up one spin down¯ • spin describes the direction of their magnetic field • e- have charges two allowable magnetic states

Diamagnetic vs. paramagnetic • paired electrons have spins unaligned ¯ • no net magnetic field • diamagnetic - repelled by a magnetic field, all electrons are paired • unpaired electrons have their spins aligned or ¯¯ • enhanced magnetic field • paramagnetic - attracted to a magnetic field, has unpaired electrons

Electronic ConfigurationsRules for assigning e- in orbitals: • Always fill orbitals in lowest energy level first. (Aufbau Principle) Aufbau Principle - The electron that distinguishes an element from the previous element enters the lowest energy atomic orbital available. (in other words fill one energy sublevel before moving up) • No two e- can have same 4 quantum numbers in an atom. (Pauli Exclusion Principle) Wolfgang Pauli - 1925 • No two electrons in an atom may have identical sets of 4 quantum numbers.

Spread e- out on a sublevel if possible. (Hund’s Rule) Electrons will spread themselves out among the orbitals individually and give unpaired, parallel spins. The pairing of electrons is an unfavorable process; energy must be expended in order to make it occur. Exception: If you can achieve full or half-full orbitals by moving one e- between s ~ d or s ~ f orbitals, do so. It’s lower in energy because there is an increased stability due to the decrease in the screening of electron/nuclear attractions

Electronic Configurations

use periodic chart - best method

Electronic Configurations and Orbital Diagrams 1st row Orbital Order 1s 2s 2p 3s 3p 4s 3d 4p 5s 4d 5p 6s 4f 5d 6p 7s 5f 6d 7p 8s

2nd row

3rd row

CHAPTER 5

CHAPTER 5

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Chapter 5

Chapter 5

Chapter 5

Chapter 5

Chapter 5 5

chapter 5

Chapter 5

Chapter 5

Chapter 5

Chapter 5

Chapter 5

CHAPTER 5

Chapter 5

CHAPTER 5

Chapter 5

Chapter 5

Chapter 5

Chapter 5

Chapter 5

Chapter 5

Chapter 5

Chapter 5