Unit 5 - Atomic Theory and Chemical Bonding Emission of Energy by Atoms (pg 284) Energy Levels of Hydrogen (pgs 285-287) Hydrogen Orbitals (pgs 289-292)
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Unit 5 - Atomic Theory and Chemical Bonding
Emission of Energy by Atoms (pg 284)Energy Levels of Hydrogen (pgs 285-287)
Hydrogen Orbitals (pgs 289-292)Electron Arrangements (pgs 295-298)Electron Configuration (pgs 299-303)
Types of Chemical Bonds (pgs 317-319)Electronegativity (pgs 319-321)
Stable Electron Configurations (pgs 323-326)Lewis Structures (pgs 328-332)
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Unit 5 - Atomic Theory and BondingUpon completion of this unit, you should be able to do the following:
1. Write the electron configuration for an atom or ion using the periodic table.
2. Be able to draw an orbital notation diagram for any atom or ion.
3. Determine the valence electrons of an atom.4. Predict the types of bonds formed between two atoms and
describe the properties of each.5. Use electronegativity to predict the percent ionic character
of bonds and the polarity of molecules.6. Draw Lewis dot structures to represent how atoms share
or transfer valence electrons to become more stable.7. Explain how multiple bonds can form between the same
two atoms.
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Atomic Theory• The concept of atoms explains many important
observations, such as why compounds always have the same composition (a specific compound always contains the same types and numbers of atoms) and how chemical reactions occur (they involve a rearrangement of atoms).
• We learned to picture the atom as a positively charged nucleus composed of protons and neutrons at its center and electrons moving around the nucleus in a space very large compared to the nucleus.
• In this unit, we develop a picture of the electron arrangements in atoms.
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Emission of Energy by Atoms• When compounds are heated, they emit a color
characteristic of the cation. Li+, for example, emits a red flame when heated. Na+ emits a yellow flame, Cu2+ a green flame.
• The colors of the flames result from atoms releasing energy in the form of visible light of specific wavelengths, or colors.
• The heat from the flame causes the atom to absorb energy. The atom becomes excited. Some of the excess energy is released as light. The atom moves to a lower energy state as it emits a photon of light.
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Emission of Energy by Atoms• When atoms receive energy, they become excited.
They can release the energy by emitting light. The emitted energy is carried away by a photon.
• The energy of the photon corresponds exactly to the energy change of the emitting atom.
• High energy photons correspond to short wavelength light. Low energy photons correspond to long wavelength light.
• The photons of red light have less energy than the photons of blue light because red light has a longer wavelength than blue light.
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Energy Levels of Hydrogen• When we study the photons of visible light emitted,
we see only certain colors.• Only certain types of photons are produced.• Because only certain photons are emitted, only
certain energy changes are occurring.• So, hydrogen atoms must have certain discrete
energy levels.• We say the energy levels of hydrogen are quantized,
that is, only certain values are allowed.• Energy levels of all atoms are quantized.
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Energy Levels of Hydrogen
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The Hydrogen OrbitalsThe probability map is called an orbital. The orbital shown in Figure 10.20 is called the 1s orbital and describes the ground (lowest) state of energy for hydrogen.
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The Hydrogen OrbitalsHydrogen has discrete energy levels. They are called principal energy levels and labeled with an integer. Each principal energy level has sublevels.
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The Hydrogen Orbitals
Principal level 2 has 2 sublevels. They are called 2s and 2p. Principal level 3 has 3 sublevels called 3s, 3p and 3d. Principal level 4 has 4 sublevels called 4s, 4p, 4d and 4f.
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The Hydrogen Orbitals
The principal levels describe size and shape. The s orbital is spherical. Level 1 is smaller than level 2, which is smaller than level 3.
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The Hydrogen OrbitalsThe three 2p orbitals are lobed, not spherical. They are oriented along the x, y or z axis.
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Electron Arrangements
• An atom has as many electrons as it does protons, so all atoms beyond hydrogen have more than one electron.
• Each electron appears to spin like a top on its axis. It can only spin in one direction. We represent spin with an arrow, ↑ or ↓. Electrons in the same orbital must have opposite spins.
• This leads to the Pauli exclusion principle: an atomic orbital can hold a maximum of two electrons and those two electrons must have opposite spins.
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Electron Arrangements• Hydrogen has an atomic number of 1 (Z =1) and
therefore a single electron to have a net charge of zero. To show its electron configuration, we write the principal energy level followed by the sublevel, 1s. The number of electron in the orbital is placed as a superscript, 1s1.• The electron configuration can also be shown using
an orbital diagram, or box diagram, as below.
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Electron Configuration• Hydrogen (Z=1) 1s1
• Helium (Z=2) 1s2
• Lithium (Z=3) 1s2 2s1
• Berylium (Z=4) • Boron (Z=5) 1s2 2s2 2p1
• Carbon (Z=6) • Nitrogen (Z=7) • Oxygen (Z=8) • Fluorine (Z=9) • Neon (Z=10) 1s2 2s2 2p6
The orbital diagram for nitrogen is below.
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Electron Configuration
• Sodium (Z=11) 1s2 2s2 2p6 3s1 or [Ne] 3s1
• Magnesium (Z=12) • Aluminum (Z=13)• Silicon (Z=14)• Phosphorous (Z=15)• Sulfur (Z=16)• Chlorine (Z=17)• Argon (Z=18)
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Electron Configuration
• Valence electrons are the electrons in the outermost (highest) principal energy level of an atom. These are the electrons involved in bonding of atoms to each other.• Also note that the atoms of elements in the same
group have the same number of electrons in a given type of orbital, except that the orbitals are in different principal energy levels. Elements with the same valence electron arrangement show very similar chemical behavior.
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Electron Configuration
• The order of filling orbitals changes for Z=19. Experiments show that the chemical properties of potassium are very similar to lithium and sodium. We predict that the 4s orbital will fill before the 3d orbital. This means that principal energy level 4 begins to fill before level 3 is full.
• Potassium (Z=19) [Ar] 3s2 3p6 3d 1
• Potassium (Z=19) [Ar] 3s2 3p6 4s1
• Calcium (Z=20) [Ar] 3s2 3p6 4s2
• Scandium (Z=21) [Ar] 3s2 3p6 4s2 3d1
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Electron Configuration
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Electron Configuration
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Electron ConfigurationPractice problems:
Determine the electron configuration for:
1. C (Z= 6)2. Al (Z=13)3. Cl (Z=17)
Types of Chemical Bonds
• A bond is a force that holds two or more atoms together and makes them function as a unit.
• In water, the fundamental unit is the H-O-H molecule, which is held together by the two O-H bonds.
Types of Chemical Bonds
• Ionic compounds are formed when an atom that loses an electron relatively easily reacts with an atom that accepts an electron. This occurs when a metal reacts with a non-metal. The resulting bonds are called ionic bonds.
• In an ionic bond, electrons are transferred.
Types of Chemical Bonds
• Consider diatomic hydrogen H – H .• When two hydrogen atoms are brought close
together, the electrons are equally attracted to both nuclei.
• When two similar atoms form a bond, the electrons are equally attracted to the nuclei of the two atoms. This is called a covalent bond.
• In a covalent bond, the electrons are shared by nuclei.
Types of Chemical Bonds• Ionic bonding and covalent bonding are
extremes. Between the extremes are cases where atoms are not so different that electrons are transferred, but different enough that unequal sharing of the electrons results. These bonds are called polar covalent bonds.
• In HF, the fluorine atom has a stronger attraction for the shared electrons than the hydrogen atom does.
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Types of Chemical Bonds
Electronegativity• The unequal sharing of electrons between two
atoms is described by a property called electronegativity, the relative ability of an atom in a molecule to attract shared electrons to itself.
• The higher the atoms electronegativity value, the closer the shared electrons tend to be to that atom when it forms a bond.
• Fluorine has the highest electronegativity value at 4.0. Cesium and Francium have the lowest electronegativity value at 0.7
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Electronegativity
Electronegativity• The polarity of a bond depends on the
difference between the electronegativity values of the atoms forming the bonds.
• If the atoms have similar electronegativities, the electrons are shared almost equally and the bond shows little polarity.
• If the atoms have very different electronegativities, a very polar bond is formed.
Electronegativity• In extreme cases, one or more electrons are
actually transferred and ions and an ionic bond are formed.
• Consider NaCl , for example. When a Group 1 metal reacts with a Group 17 element, ions are formed and an ionic substance results.
ElectronegativityPage 321, example 11.1
Using the electronegativity values given in Figure 11.3, arrange the following bonds in order of
increasing polarity: H-H, O-H, Cl-H, S-H, F-H
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Stable Electron Configurations
• Representative metals form ions by losing enough electrons to attain the configuration of the previous noble gas that occurs before the metal. For example, sodium will lose one electron to attain the configuration of neon.
• Nonmetals form ions by gaining enough electrons to attain the configuration of the next noble gas. For example, chlorine will add one electron to attain the configuration of argon.
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Stable Electron Configurations
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Stable Electron Configurations
• In observing millions of stable compounds, chemists have observed that in almost all stable compounds, all of the atoms have achieved a noble gas configuration.
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Stable Electron Configurations
• When a non-metal and a Group 1, 2 or 3 metal react to form a binary ionic bond, the ions form so that the non-metal completes the valence-electron configuration of the next noble gas and the metal empties the valence orbitals to achieve the configuration of the previous noble gas.
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Stable Electron Configurations
• When two non-metals react to form a covalent bond, they share electrons in a way that completes the valence-electron configuration of both atoms.
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Lewis Structures• Bonding involves just the valence electrons of
atoms. (See slide 18.) The Lewis structure is a representation of a molecule that shows how the valence electrons are arranged among the atoms in the molecule. Dots are used to represent the valence electrons.
Examples: K Br
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Lewis Structures
• Duet rule – hydrogen
• Octet rule – elements are surrounded by 8 electrons. Electrons that are shared form bonds.
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Lewis StructuresPractice problems:
Draw the Lewis structure for:
1. HF2. NH3
3. CH4
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