Chapter 13

Chapter 13 Electron Configuration

Evolution of Atomic Models • First Model: • John Dalton: • The atom is a solid, indivisible mass

Evolution of Atomic Models, cont. • Second Model: • JJ Thompson: • He discovered the electron. • He developed the plum pudding model. This was a positive material (pudding) with negative charges (raisins) stuck on it.

Evolution of Atomic Models, cont. • Third Model: • Ernest Rutherford: • Discovered the nucleus • His model had electrons surrounding a dense nucleus. • The rest of the atom is empty space.

Evolution of Atomic Models, cont. • Fourth Model: • Niels Bohr: • Electrons are arranged around concentric paths known as orbits. • Electrons in a particular path have a fixed amount of energy

Niels Bohr Model, cont. • Energy Levels: • The region around the nucleus where the electron is likely to be moving. • The lowest energy level has the lowest amount of energy. (Think of ladders.) • An electron cannot be between energy levels. • Quantum: • the amount of energy required to move an electron from its present energy level to a higher one. • Quantum Leap = abrupt change

Niels Bohr Model, cont. • Energy Levels, cont.: • The energy levels are not equally spaced. • The further away from the nucleus you are, the closer together the levels are. • Why is it easier to pull electrons away from the atom the further out you are?

Quantum Mechanical Model • Erwin Schrödinger: • Used the quantum theory to write and solve a mathematical equation describing the location and energy of an electron in a Hydrogen atom. • This became known as the Quantum Mechanical Model.

Quantum Mechanical Model, cont. • Quantum Mechanical Model: • Modern description, primarily mathematical of the behavior of electrons in atoms • The energy of electrons is restricted to certain values. • The electrons do not have exact paths around the nucleus. • This strictly ESTIMATES the probability of finding an electron in a certain position.

Quantum Mechanical Model, cont. • The probability of finding an electron is represented by a fuzzy cloud. • Theoretically this area could go on forever, so they show the area where the electron is found 90% of the time. • From this, we can start to see the shapes of the different clouds.

Atomic Orbitals • Energy Levels are also known as principal quantum numbers, represented with the letter n. • n=1, n=2, n=3, n=4, n=5, n=6, n=7 • Hint: This equals the row number on the periodic table. 

Atomic Orbitals, cont.

Atomic Orbitals, cont. • Within each energy level (principle quantum number) there are energy sublevels. • n=1 1 sublevel 1s • n=2 2 sublevels 2s, 2p • n=3 3 sublevels 3s, 3p, 3d • n=4 4 sublevels 4s, 4p, 4d, 4f • n=5 5 sublevels 5s, 5p, 5d, 5f, 5g (These are sublevels)

Sublevels • The s orbital: • Spherical • One orbital • Always the first orbital filled for any energy level. • 1s, 2s, 3s, 4s, 5s, 6s, 7s 3s 2s 1s

Sublevels, cont. • The p orbitals: • Dumbbell shaped • Three orbitals: x, y, and z • Electrons go into the p orbital after the s orbital is filled. pz px py

Sublevels, cont. • The d orbitals: • Cloverleaf shaped • There are 5 orbitals: d1, d2, d3, d4, d5 • Electrons fill the d orbitals after the s and p orbitals are completely filled. d2 d4 d1 d3 d5

Sublevels, cont. • The f orbitals: • These are complexly shaped. • There are 7 orbitals: f1, f2, f3, f4, f5, f6, f7 • These fill after the s, p, and d orbitals are completely filled. f3 f1 f2

f Orbitals, cont. f5 f6 f4 f7

Energy Levels with Orbitals • n=1 1s • n=2 2s, 2px, 2py, 2pz • n=3 3s, 3px, 3py, 3pz, 3d1, 3d2, 3d3, 3d4, 3d5 • n=4 4s, 4px, 4py, 4pz, 4d1, 4d2, 4d3, 4d4, 4d5, 4f1, 4f2, 4f3, 4f4, 4f5, 4f6, 4f7 • How do you remember how many orbitals there are in an energy level? • n2

Electrons • In any orbital, there is a maximum of 2 electrons. • How do you figure out how many electrons are in an energy level? • 2n2 • Example: • n=1, there is a max of 2 electrons • n=2, there is a max of 8 electrons

Periodic Table and All of This • Okay, so where does everything fit on the periodic table? • Group 1A and 2A: s orbitals • Group 3A – 0: p orbitals • Transition Metals: d orbitals • Inner transition Metals: f orbitals

Let’s Try  • Give the electron configuration for Be: • 1s22s2 • Give the electron configuration for H: • 1s1 • Give the electron configuration for S: • 1s22s22p63s23p4

Okay, Now the Harder Ones • Give the electron configuration for Mn: • 1s22s22p63s23p64s23d5 • Give the electron configuration for Au: • 1s22s22p63s23p64s23d104p65s24d105p66s24f145d9 • Give the electron configuration for Ra: • 1s22s22p63s23p64s23d104p65s24d105p66s24f14 5d10 6p67s2

So… • When you get to the transition metals, the number in front of the d, the energy level, is ONE less then the row you are on. • When you get to the inner transition metals, the number in front of the f, the energy level, is TWO less then the row you are on.

Section 13.2 • Electron Configuration: • The ways in which electrons are arranged around the nuclei of atoms • There 3 rules to finding the electron configuration: • Aufbau Principle • Pauli Exclusion Principle • Hund’s Rule

Aufbau Principle • This principle states that electrons enter orbitals of lowest energy first • Various orbitals within the sublevel are equal in energy • For each energy level the s sublevel is lowest in energy.

Pauli Exclusion Principle • This states that at most 2 electrons per atomic orbital. • If one electron is currently in an orbital, the 2nd electron can enter only if it spins in the opposite direction. One spins clockwise, one spins counterclockwise. • Shown:

Hund’s Rule • This states that when electrons occupy an orbital of equal energy, one electron enters each orbital until all orbitals contain one electron with parallel spins. • Example: 2px 2py 2pz

Practice • Write the orbital configurations and electron configurations for the following elements: • H • C • Na • Ti

Exceptional Electron Configurations • You can obtain correct electron configurations up to #23, V, after that it may change. • Reason: half-filled orbitals are more stable than “off balance” orbitals. • Example: Cu has 29 electrons • 1s22s22p63s23p64s23d9 is not as stable as 1s22s22p63s23p64s13d10

Section 13.3 • Electromagnetic radiation: • Includes radio waves, microwaves, infrared waves, visible light, ultraviolet waves, x-rays, and gamma rays. • Sunlight (white light) consists of a continuous range of wavelengths and frequencies. • When passed through a prism the different wavelengths separate into a spectrumof colors. • For example: a rainbow

Atomic Emission Spectrum • Every element emits light when it is excited by the passage of an electricity through its gas or vapor. • The atoms first absorb energy, then lose the energy as they emit light. • Passing this light emitted by and element through a prism gives the atomic emission spectrum. • Each line in the emission spectra corresponds to one exact frequency of light emitted by the atom.

Explanation of Atomic Emission Spectrum • Electrons start off in their own ground state (lowest energy level). • Excitation of the electron raises it from its ground state to an excited state (a higher energy level). • In order for the electron to jump up a level, it had to absorb a quantum of energy. When it falls back down, it releases this same amount of energy (as a photon) and we see the light.

Chapter 13

Chapter 13

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CHAPTER 13

CHAPTER 13

Chapter 13

chapter 13

Chapter 13

Chapter 13

Chapter 13

Chapter 13

Chapter 13

Chapter 13

Chapter 13

Chapter 13

Chapter 13

Chapter 13

Chapter 13

Chapter 13

Chapter 13

Chapter 13

Chapter 13

Chapter 13

Chapter 13

Chapter 13