knowt logoknowt logo
HomeExploreExamsBlog
knowt logoKnowt
Rating
0.0(0)
Flashcard Icon
undefined Flashcards
0.0(0)

Studied by 0 people

Other AP Chemistry unit study guides
Unit 1: Atomic Structure and Properties
Unit 2: Molecular and Ionic Compound Structure and Properties
Unit 3: Intermolecular Forces and Properties
Unit 4: Chemical Reactions
Unit 5: Kinetics
Unit 6: Thermodynamics
Unit 7: Equilibrium
Unit 8: Acids and Bases
Unit 9: Applications of Thermodynamics
Studying for another AP Exam?
Check out our other AP study guides
Tags
ChemistryAP Chemistry11th
Top Exams
AP English Language and Composition
AP English Language and Composition
Study Guide
AP Biology
AP Biology
Study Guide
AP United States History
AP United States History
Study Guide
knowt ap exam guide logo

Chemistry A Molecular Approach AP Edition Chapter 11 Liquids, Solids, and Intermolecular Forces 

Chemistry A Molecular Approach AP Edition Chapter 11 Liquids, Solids, and Intermolecular Forces 

11.1 Climbing Geckos and Intermolecular Forces 

  • There are three states, or phases, of matter: solid, liquid, and gas
  • Solids and liquids are condensed states
  • Solids and liquids are more similar to each other than they are to gases 
  • Particles are closer together and have stronger attractive forces 
  • Intermolecular forces are the attractive forces between all atoms and molecules 
  • Intermolecular forces hold solids and liquids together 
  • Intermolecular forces allow geckos to stick to walls 
  • When thermal energy is high, matter is gaseous 
  • When thermal energy is low, matter is a liquid or a solid 

11.2 Solids, Liquids, and Gases: A Molecular Comparison 

  • The densities of solids and liquids are greater than the densities of gases 
  • Solids and liquids have similar density and molar volumes 
  • The molecules in solids and liquids are very close together 
  • The molecules in gases are very far apart for their size
  • In liquids, unlike solids, molecules have the freedom to move around each other
  • Liquids assume the shape of their containers because the molecules are free to flow 
  • Liquids and solids are not easily compressed because the molecules cannot be pushed any closer together
  • Gases have large spaces in between molecules, and if the pressure is great enough they can be easily compressed 
  • Crystalline solids are solids thats molecules are arranged in well ordered 3D arrays 
  • Amorphous solids are solids that have to long range order to their molecules

Changes between States 

  • States of matter can be changed by using temperature or pressure 
  • Increasing pressure causes more density, which can change a gas into a liquid 
  • Gases in their liquid form will occupy less space 

11.3 Intermolecular Forces: The Forces That Hold Condensed States Together 

  • Intermolecular forces determine if something is a solid, liquid, or gas at a given temperature 
  • Moderate to strong intermolecular forces are often liquids and solids at room temperature 
  • Weak intermolecular forces tend to be gases at room temperature 
  • Molecules with temporary charges are attracted to each other because the potential energy decreases as distance decreases 
  • Intermolecular forces are weaker than bonding forces 
  • Intermolecular forces are between molecules 

Dispersion Forces 

  • Dispersion forces are also called London Dispersion forces
  • Dispersion forces are present in all molecules and atoms 
  • All atoms have electrons, so they have dispersion forces 
  • Dispersion forces are a temporary change that comes from the electrons being unevenly shared 
  • Charge separation is called an instantaneous or a temporary dipole 
  • The positive end of an atom is attracted to the negative end of another atom. This attraction is the dispersion force 
  • Polarize is the formation of a dipole moment 
  • The magnitude of the force depends on how easy electrons can move or polarize 
  • The movement and polarization of electrons depend on how large the electron cloud is 
  • In larger electron clouds, electrons are not held as tightly and can polarize easier 
  • Dispersion forces increase as molar mass increases 
  • Shape also influences dispersion forces  

Dipole Dipole Force

  • Dipole dipole forces can be found in all polar molecules 
  • Polar molecules have partial negative and partial positive regions 
  • Permanent dipoles do not switch from being positive or negative. They are always one or the other 
  • The positive end of a permanent dipole being attracted to the negative end of another permanent dipole is the dipole dipole force 
  • Polar molecules have higher melting and boiling points that nonpolar molecules (of the same mass) 
  • Miscibility is the ability to mix without separating into two states, for example water and pentane 
  • Polarity determines miscibility 
  • Polar molecules are miscible with polar molecules. They are not miscible with nonpolar molecules 
  • Nonpolar molecules are miscible with nonpolar molecules 

Hydrogen Bonding 

  • Polar molecules that have hydrogen atoms can have hydrogen bonding 
  • The hydrogen atoms will typically be connected to fluorine, oxygen, or nitrogen atoms 
  • Hydrogen atoms will have partial positive charges while the other atoms will have partial negative charges 
  • The strong attractions between these atoms is a hydrogen bond 
  • Hydrogen bonds are NOT chemical bonds 
  • Hydrogen bonds are the stronger than dipole dipole and dispersion forces 

Ion Dipole Forces 

  • Ion dipoles occur when an ionic compound is mixed with a polar compound 
  • Ion dipoles are important in aqueous solutions 
  • Ion dipole forces are the strongest type of intermolecular force

11.4 Intermolecular Forces in Action: Surface Tension, Viscosity, and Capillary Action 

Surface Tension 

  • Liquids tend to minimize their surface tension 
  • Surface tension is the energy required to increase the surface area by a unit amount 
  • Surface tension decreases as intermolecular forces decrease 
  • Surface tension allows water droplets to be sphere shaped 

Viscosity 

  • Viscosity is the resistance of a liquid to flow 
  • Viscosity is measure in posie (P)
  • Viscosity is 1g /cm x s
  • Viscosity is greater in substances with stronger intermolecular forces 
  • Viscosity depends on molecular shape
  • Viscosity increases with increasing molar mass, magnitude of dispersion forces, and increasing length 
  • Viscosity depends on temperature 

Capillary Action

  • Capillary action is the ability of a liquid to flow against gravity and up a tube 
  • Capillary action results from the combination of cohesive and adhesive forces
  • Cohesive forces are the attractions between molecules in a liquid 
  • Adhesive forces are the attractions between molecules and the surface of the tube 
  • Adhesive forces cause the liquid to spread across the surface of the tube
  • Cohesive forces cause the liquid to stick together 
  • If adhesive forces are greater than cohesive forces, the liquid will climb up the tube 
  • The thinner the tube, the higher the liquid will rise 

11.5 Vaporization and Vapor Pressure 

The Process of Vaporization 

  • The higher the temperature, the greater the average energy of the collection of molecules 
  • Some molecules have more thermal energy than others
  • Some molecules have less thermal energy than others 
  • The transition from the liquid state to the gas state is vaporization 
  • The opposite of vaporization, the transition from gas to liquid, is condensation 
  • Vaporization occurs quicker at higher temperatures 
  • Vaporization occurs quicker on larger surfaces 
  • The rate of vaporization increases as intermolecular force strength decreases 
  • Liquids that vaporize easily are volatile 
  • Liquids that do not vaporize easily are nonvolatile 

The Energetics of Vaporization

  • Vaporization is an endothermic process because it energy is absorbed to change from a liquid to a gas 
  • Energy is needed to break the intermolecular forces 
  • Condensation is exothermic
  • Heat is released when a gas condenses to a liquid 
  • The heat (or enthalpy) of vaporization is the amount of heat required to vaporize one mole of a liquid to gas 
  • The heat of vaporization is always positive because the process is endothermic 
  • When a substance condenses, the value will be negative 

Vapor Pressure and Dynamic Equilibrium 

  • Once water molecules enter the gas state, some will start condensing back into a liquid 
  • As the number of gaseous water molecules increases, so does the rate of condensation 
  • Once the rate of vaporization and condensation are equal, they have reached dynamic equilibrium 
  • Vapor pressure is the pressure of a fas in dynamic equilibrium with its liquid 
  • Vapor pressure depends of intermolecular forces and temperature 
  • Weak intermolecular forces have higher vapor pressure 
  • Strong intermolecular forces have low vapor pressure
  • When a balanced system is disturbed, it will work its way back to equilibrium and try to minimize the disturbance
  • When temperature increases, vapor pressure rises 
  • Boiling point is when the liquids vapor pressure is equal to the external pressure 
  • At the boiling point, thermal energy is enough that molecules break free of their neighbors and enter the gas state 
  • Normal boiling point is when vapor pressure equals 1 atm
  • Lower pressures result in lower boiling points 
  • Once the boiling point is reached, heating the temperature will not cause the process to occur faster 
  • As long as the liquid is present, temperature cannot rise above its boiling point 
  • Vapor pressure and temperature have a exponential relationship 

The Critical Point: The Transition to an Unusual State of Matter 

  • As temperature and pressure increase, the density of a gas increases 
  • As temperature increases, the density of a liquid decreases 
  • A supercritical fluid is a substance that forms above the critical point 
  • The temperature where supercritical fluids occur is the critical temperature 
  • The pressure where supercritical fluids occur is the critical pressure 
  • Supercritical fluids have properties of both liquids and gases 

11.6 Sublimation and Fusion 

Sublimation 

  • Sublimation is the transition form solid to gas 
  • The opposite of sublimation, transitioning from gas to solid, is deposition 
  • The vapor pressure of the solid is the pressure of a gas in dynamic equilibrium with its solid 
  • Sublimation will occur at a greater rate 
  • Colder temperatures will lower the vapor pressure 

Fusion 

  • An increase in thermal energy causes molecules to vibrate faster 
  • At the melting point, molecules have enough energy to turn from solids into liquids 
  • Melting is the transition from solid to liquid 
  • Melting is also called fusion 
  • The opposite of melting, the transition from liquid to solid, is freezing 
  • Once the melting point is reached, going to a higher temperature will not speed up the process

Energetics of Melting and Freezing

  • Melting is endothermic 
  • The heat of fusion is the amount of heat required to melt one mole of a solid 
  • The heat of fusion is a positive value 
  • Freezing is exothermic 
  • Different substances will have different heat of fusions 
  • Heat of fusion is generally less than the heat of vaporization because liquids and solids are similar 

11.7 Heating Curve for Water

  • Heating curves show at what temperatures each phase occurs
  • Heating curves have 5 segments: Solid warming, melting, liquid warming, vaporization, and gas warming 
  • Melting and vaporization are constant because these are the transition stages 
  • Melting and vaporization are in equilibrium and the temperature will remain constant 
  • In the warming stages, temperature increases linearly 
  • The specific heat capacity is different for different substances 

11.8 Phase Diagrams 

  • A phase diagram shows a map of a substance based on pressure and temperature 

The Major Features of a Phase Diagram 

  • The y-axis displays pressure in the unit torr
  • The x-axis displays the temperature in Celsius 
  • The three main regions of the phase diagram represent solid, liquid, and gas
  • The phrase diagram represents conditions where that phase is occurring
  • Low temperatures and higher pressures tend to be solids 
  • High temperatures and low pressures tend to be gases
  • Middle temperatures and middle pressures tend to be liquids 
  • Each of the lines, or curves, represent the temperatures and pressures where equilibrium between states is occurring 
  • The line separating liquid and gas is the vaporization curve 
  • The sublimation curve separates solids and gases 
  • The fusion curve separates solids and liquids 
  • The triple point is where all three phases occur in equilibrium 
  • The critical point is the temperature and pressure above which a supercritical fluid exists 

Navigation within a Phase Diagram 

  • As temperature rises, move right along the x-axis 
  • As pressure rises, move up along the y-axis 

The Phase Diagrams of Other Substances 

  • The fusion curve for carbon dioxide and iodine have positive slopes 
  • The fusion curve for water has a negative slope 

11.9 Water: An Extraordinary Substance 

  • Life is impossible without water 
  • Water has a low molar mass, but is a liquid at room temperature 
  • Water has a high boiling point 
  • Water molecules are bent in shape 
  • Water molecules are highly polar 
  • Water's high polarity allows it to dissolve other polar and ionic compounds 
  • Water is the main solvent in living organisms 
  • Water has a high specific heat capacity 
  • Water expands when it freezes, most substances contract 

11.10 Crystalline Solids: Determining Their Structure by X-Ray Crystallography 

  • X-ray distraction allows scientists to determine the arrangement of atoms and measure the distance between them 
  • Waves interact through interference 
  • Constructive interference occurs when two waves interact with crests and troughs aligning with each other 
  • Destructive interference occurs when two waves interact with crests and trough aligning with the other 
  • Interference patterns consists of alternating light and dark lines 
  • Atoms of crystal structures act similarly 
  • The pattern of a diffraction reveals the spacing between atoms 

11.11 Crystalline Solids: Unit Cells and Basic Structures 

  • The arrangement of atoms in a crystalline solid is called the crystalline lattice 
  • Crystalline lattices are represented with small collections of atoms, ions, or molecules
  • This representation is called a unit cell 
  • When unit cells are repeated, an entire lattice is produced 
  • The lattice point is a space occupied by an atom, ion, or molecule 
  • Unit cells are classified by their symmetry 
  • Cubic unit cells have equal edge lengths and 90 degree angles
  • A unit cell may seem like it contains 8 atoms, but in reality there is only 1
  • The coordination number is the number of atoms which each atom is in direct contact with 
  • Packing efficiency is the percentage of the volume of the unit cell occupied by the spheres 
  • The higher the coordination number, the higher the packing efficiency 
  • Body centered unit cells contain two atoms per cell 
  • Face centered unit cells contain four atoms per cell

Closest Packed Structures 

  • Crystal structures have lots of empty space 
  • Packing efficiency can be increased by not placing the next layer directly on top of the first 
  • In hexagonal closest packing, the third layer is lined up directly above the first layer 
  • In cubic closest packing, the third layer is lined up off the first layer 

11.12 Crystalline Solids: The Fundamental Types 

  • There are three categories of crystalline solids: Molecular, ionic, and atomic 
  • Atomics are classified into non bonded, metallic, and network covalent 

Molecular Solids 

  • Molecular solids are solids whose units are molecules 
  • Ice is an example of a molecular solid 
  • They are held together by intermolecular forces 
  • They tend to have low melting points 

Ionic Solids 

  • Ionic solids are made up of ions 
  • NaCl and CaF2 are examples of ionic solids 
  • They are held together by coulombic interactions between cations and anions 
  • Ionic solids have higher melting points than molecular solids 

Atomic Solids

  • Atomic solids are made up of atoms 
  • Nonbonding atoms are held together by weak dispersion forces 
  • Nonbonding atoms form closest packing structure to maximize interactions 
  • Nonbonding atoms have very low melting points 
  • Nonbonding atomic solids are noble gases in their solid form 
  • Metallic atomic solids are held together by metallic bonds 
  • Metals form closest packed crystal structures 
  • Some metals have high melting points while other metals have very low melting points 
  • Network covalent atomic solids are held together by covalent bonds 
  • Network covalent solids do not form closest packed structures  

11.13 Crystalline Solids: Band Theory 

  • The band theory combines atomic orbitals of the atom within a solid crystal to from orbitals that are not localized on individual atoms 
  • Electrons become mobile when they make a transition from the highest occupied molecular orbital into higher energy empty molecular orbitals 
  • Occupied molecular orbitals are the valence band
  • Unoccupied orbitals are conduction bands 
  • When a metal is heated, electrons are excited and go to a higher molecular orbital 
  • An energy gap, the band gap, exists between valence and conduction bands in semiconductors and insulators 

Doping: Controlling the Conductivity of Semiconductors

  • Dope semiconductors contain holes in the valence band  
GB
homeHomeknowt breadcrumb
Science
knowt breadcrumb
AP Chemistry

Chemistry A Molecular Approach AP Edition Chapter 11 Liquids, Solids, and Intermolecular Forces 

Chemistry A Molecular Approach AP Edition Chapter 11 Liquids, Solids, and Intermolecular Forces 

11.1 Climbing Geckos and Intermolecular Forces 

  • There are three states, or phases, of matter: solid, liquid, and gas
  • Solids and liquids are condensed states
  • Solids and liquids are more similar to each other than they are to gases 
  • Particles are closer together and have stronger attractive forces 
  • Intermolecular forces are the attractive forces between all atoms and molecules 
  • Intermolecular forces hold solids and liquids together 
  • Intermolecular forces allow geckos to stick to walls 
  • When thermal energy is high, matter is gaseous 
  • When thermal energy is low, matter is a liquid or a solid 

11.2 Solids, Liquids, and Gases: A Molecular Comparison 

  • The densities of solids and liquids are greater than the densities of gases 
  • Solids and liquids have similar density and molar volumes 
  • The molecules in solids and liquids are very close together 
  • The molecules in gases are very far apart for their size
  • In liquids, unlike solids, molecules have the freedom to move around each other
  • Liquids assume the shape of their containers because the molecules are free to flow 
  • Liquids and solids are not easily compressed because the molecules cannot be pushed any closer together
  • Gases have large spaces in between molecules, and if the pressure is great enough they can be easily compressed 
  • Crystalline solids are solids thats molecules are arranged in well ordered 3D arrays 
  • Amorphous solids are solids that have to long range order to their molecules

Changes between States 

  • States of matter can be changed by using temperature or pressure 
  • Increasing pressure causes more density, which can change a gas into a liquid 
  • Gases in their liquid form will occupy less space 

11.3 Intermolecular Forces: The Forces That Hold Condensed States Together 

  • Intermolecular forces determine if something is a solid, liquid, or gas at a given temperature 
  • Moderate to strong intermolecular forces are often liquids and solids at room temperature 
  • Weak intermolecular forces tend to be gases at room temperature 
  • Molecules with temporary charges are attracted to each other because the potential energy decreases as distance decreases 
  • Intermolecular forces are weaker than bonding forces 
  • Intermolecular forces are between molecules 

Dispersion Forces 

  • Dispersion forces are also called London Dispersion forces
  • Dispersion forces are present in all molecules and atoms 
  • All atoms have electrons, so they have dispersion forces 
  • Dispersion forces are a temporary change that comes from the electrons being unevenly shared 
  • Charge separation is called an instantaneous or a temporary dipole 
  • The positive end of an atom is attracted to the negative end of another atom. This attraction is the dispersion force 
  • Polarize is the formation of a dipole moment 
  • The magnitude of the force depends on how easy electrons can move or polarize 
  • The movement and polarization of electrons depend on how large the electron cloud is 
  • In larger electron clouds, electrons are not held as tightly and can polarize easier 
  • Dispersion forces increase as molar mass increases 
  • Shape also influences dispersion forces  

Dipole Dipole Force

  • Dipole dipole forces can be found in all polar molecules 
  • Polar molecules have partial negative and partial positive regions 
  • Permanent dipoles do not switch from being positive or negative. They are always one or the other 
  • The positive end of a permanent dipole being attracted to the negative end of another permanent dipole is the dipole dipole force 
  • Polar molecules have higher melting and boiling points that nonpolar molecules (of the same mass) 
  • Miscibility is the ability to mix without separating into two states, for example water and pentane 
  • Polarity determines miscibility 
  • Polar molecules are miscible with polar molecules. They are not miscible with nonpolar molecules 
  • Nonpolar molecules are miscible with nonpolar molecules 

Hydrogen Bonding 

  • Polar molecules that have hydrogen atoms can have hydrogen bonding 
  • The hydrogen atoms will typically be connected to fluorine, oxygen, or nitrogen atoms 
  • Hydrogen atoms will have partial positive charges while the other atoms will have partial negative charges 
  • The strong attractions between these atoms is a hydrogen bond 
  • Hydrogen bonds are NOT chemical bonds 
  • Hydrogen bonds are the stronger than dipole dipole and dispersion forces 

Ion Dipole Forces 

  • Ion dipoles occur when an ionic compound is mixed with a polar compound 
  • Ion dipoles are important in aqueous solutions 
  • Ion dipole forces are the strongest type of intermolecular force

11.4 Intermolecular Forces in Action: Surface Tension, Viscosity, and Capillary Action 

Surface Tension 

  • Liquids tend to minimize their surface tension 
  • Surface tension is the energy required to increase the surface area by a unit amount 
  • Surface tension decreases as intermolecular forces decrease 
  • Surface tension allows water droplets to be sphere shaped 

Viscosity 

  • Viscosity is the resistance of a liquid to flow 
  • Viscosity is measure in posie (P)
  • Viscosity is 1g /cm x s
  • Viscosity is greater in substances with stronger intermolecular forces 
  • Viscosity depends on molecular shape
  • Viscosity increases with increasing molar mass, magnitude of dispersion forces, and increasing length 
  • Viscosity depends on temperature 

Capillary Action

  • Capillary action is the ability of a liquid to flow against gravity and up a tube 
  • Capillary action results from the combination of cohesive and adhesive forces
  • Cohesive forces are the attractions between molecules in a liquid 
  • Adhesive forces are the attractions between molecules and the surface of the tube 
  • Adhesive forces cause the liquid to spread across the surface of the tube
  • Cohesive forces cause the liquid to stick together 
  • If adhesive forces are greater than cohesive forces, the liquid will climb up the tube 
  • The thinner the tube, the higher the liquid will rise 

11.5 Vaporization and Vapor Pressure 

The Process of Vaporization 

  • The higher the temperature, the greater the average energy of the collection of molecules 
  • Some molecules have more thermal energy than others
  • Some molecules have less thermal energy than others 
  • The transition from the liquid state to the gas state is vaporization 
  • The opposite of vaporization, the transition from gas to liquid, is condensation 
  • Vaporization occurs quicker at higher temperatures 
  • Vaporization occurs quicker on larger surfaces 
  • The rate of vaporization increases as intermolecular force strength decreases 
  • Liquids that vaporize easily are volatile 
  • Liquids that do not vaporize easily are nonvolatile 

The Energetics of Vaporization

  • Vaporization is an endothermic process because it energy is absorbed to change from a liquid to a gas 
  • Energy is needed to break the intermolecular forces 
  • Condensation is exothermic
  • Heat is released when a gas condenses to a liquid 
  • The heat (or enthalpy) of vaporization is the amount of heat required to vaporize one mole of a liquid to gas 
  • The heat of vaporization is always positive because the process is endothermic 
  • When a substance condenses, the value will be negative 

Vapor Pressure and Dynamic Equilibrium 

  • Once water molecules enter the gas state, some will start condensing back into a liquid 
  • As the number of gaseous water molecules increases, so does the rate of condensation 
  • Once the rate of vaporization and condensation are equal, they have reached dynamic equilibrium 
  • Vapor pressure is the pressure of a fas in dynamic equilibrium with its liquid 
  • Vapor pressure depends of intermolecular forces and temperature 
  • Weak intermolecular forces have higher vapor pressure 
  • Strong intermolecular forces have low vapor pressure
  • When a balanced system is disturbed, it will work its way back to equilibrium and try to minimize the disturbance
  • When temperature increases, vapor pressure rises 
  • Boiling point is when the liquids vapor pressure is equal to the external pressure 
  • At the boiling point, thermal energy is enough that molecules break free of their neighbors and enter the gas state 
  • Normal boiling point is when vapor pressure equals 1 atm
  • Lower pressures result in lower boiling points 
  • Once the boiling point is reached, heating the temperature will not cause the process to occur faster 
  • As long as the liquid is present, temperature cannot rise above its boiling point 
  • Vapor pressure and temperature have a exponential relationship 

The Critical Point: The Transition to an Unusual State of Matter 

  • As temperature and pressure increase, the density of a gas increases 
  • As temperature increases, the density of a liquid decreases 
  • A supercritical fluid is a substance that forms above the critical point 
  • The temperature where supercritical fluids occur is the critical temperature 
  • The pressure where supercritical fluids occur is the critical pressure 
  • Supercritical fluids have properties of both liquids and gases 

11.6 Sublimation and Fusion 

Sublimation 

  • Sublimation is the transition form solid to gas 
  • The opposite of sublimation, transitioning from gas to solid, is deposition 
  • The vapor pressure of the solid is the pressure of a gas in dynamic equilibrium with its solid 
  • Sublimation will occur at a greater rate 
  • Colder temperatures will lower the vapor pressure 

Fusion 

  • An increase in thermal energy causes molecules to vibrate faster 
  • At the melting point, molecules have enough energy to turn from solids into liquids 
  • Melting is the transition from solid to liquid 
  • Melting is also called fusion 
  • The opposite of melting, the transition from liquid to solid, is freezing 
  • Once the melting point is reached, going to a higher temperature will not speed up the process

Energetics of Melting and Freezing

  • Melting is endothermic 
  • The heat of fusion is the amount of heat required to melt one mole of a solid 
  • The heat of fusion is a positive value 
  • Freezing is exothermic 
  • Different substances will have different heat of fusions 
  • Heat of fusion is generally less than the heat of vaporization because liquids and solids are similar 

11.7 Heating Curve for Water

  • Heating curves show at what temperatures each phase occurs
  • Heating curves have 5 segments: Solid warming, melting, liquid warming, vaporization, and gas warming 
  • Melting and vaporization are constant because these are the transition stages 
  • Melting and vaporization are in equilibrium and the temperature will remain constant 
  • In the warming stages, temperature increases linearly 
  • The specific heat capacity is different for different substances 

11.8 Phase Diagrams 

  • A phase diagram shows a map of a substance based on pressure and temperature 

The Major Features of a Phase Diagram 

  • The y-axis displays pressure in the unit torr
  • The x-axis displays the temperature in Celsius 
  • The three main regions of the phase diagram represent solid, liquid, and gas
  • The phrase diagram represents conditions where that phase is occurring
  • Low temperatures and higher pressures tend to be solids 
  • High temperatures and low pressures tend to be gases
  • Middle temperatures and middle pressures tend to be liquids 
  • Each of the lines, or curves, represent the temperatures and pressures where equilibrium between states is occurring 
  • The line separating liquid and gas is the vaporization curve 
  • The sublimation curve separates solids and gases 
  • The fusion curve separates solids and liquids 
  • The triple point is where all three phases occur in equilibrium 
  • The critical point is the temperature and pressure above which a supercritical fluid exists 

Navigation within a Phase Diagram 

  • As temperature rises, move right along the x-axis 
  • As pressure rises, move up along the y-axis 

The Phase Diagrams of Other Substances 

  • The fusion curve for carbon dioxide and iodine have positive slopes 
  • The fusion curve for water has a negative slope 

11.9 Water: An Extraordinary Substance 

  • Life is impossible without water 
  • Water has a low molar mass, but is a liquid at room temperature 
  • Water has a high boiling point 
  • Water molecules are bent in shape 
  • Water molecules are highly polar 
  • Water's high polarity allows it to dissolve other polar and ionic compounds 
  • Water is the main solvent in living organisms 
  • Water has a high specific heat capacity 
  • Water expands when it freezes, most substances contract 

11.10 Crystalline Solids: Determining Their Structure by X-Ray Crystallography 

  • X-ray distraction allows scientists to determine the arrangement of atoms and measure the distance between them 
  • Waves interact through interference 
  • Constructive interference occurs when two waves interact with crests and troughs aligning with each other 
  • Destructive interference occurs when two waves interact with crests and trough aligning with the other 
  • Interference patterns consists of alternating light and dark lines 
  • Atoms of crystal structures act similarly 
  • The pattern of a diffraction reveals the spacing between atoms 

11.11 Crystalline Solids: Unit Cells and Basic Structures 

  • The arrangement of atoms in a crystalline solid is called the crystalline lattice 
  • Crystalline lattices are represented with small collections of atoms, ions, or molecules
  • This representation is called a unit cell 
  • When unit cells are repeated, an entire lattice is produced 
  • The lattice point is a space occupied by an atom, ion, or molecule 
  • Unit cells are classified by their symmetry 
  • Cubic unit cells have equal edge lengths and 90 degree angles
  • A unit cell may seem like it contains 8 atoms, but in reality there is only 1
  • The coordination number is the number of atoms which each atom is in direct contact with 
  • Packing efficiency is the percentage of the volume of the unit cell occupied by the spheres 
  • The higher the coordination number, the higher the packing efficiency 
  • Body centered unit cells contain two atoms per cell 
  • Face centered unit cells contain four atoms per cell

Closest Packed Structures 

  • Crystal structures have lots of empty space 
  • Packing efficiency can be increased by not placing the next layer directly on top of the first 
  • In hexagonal closest packing, the third layer is lined up directly above the first layer 
  • In cubic closest packing, the third layer is lined up off the first layer 

11.12 Crystalline Solids: The Fundamental Types 

  • There are three categories of crystalline solids: Molecular, ionic, and atomic 
  • Atomics are classified into non bonded, metallic, and network covalent 

Molecular Solids 

  • Molecular solids are solids whose units are molecules 
  • Ice is an example of a molecular solid 
  • They are held together by intermolecular forces 
  • They tend to have low melting points 

Ionic Solids 

  • Ionic solids are made up of ions 
  • NaCl and CaF2 are examples of ionic solids 
  • They are held together by coulombic interactions between cations and anions 
  • Ionic solids have higher melting points than molecular solids 

Atomic Solids

  • Atomic solids are made up of atoms 
  • Nonbonding atoms are held together by weak dispersion forces 
  • Nonbonding atoms form closest packing structure to maximize interactions 
  • Nonbonding atoms have very low melting points 
  • Nonbonding atomic solids are noble gases in their solid form 
  • Metallic atomic solids are held together by metallic bonds 
  • Metals form closest packed crystal structures 
  • Some metals have high melting points while other metals have very low melting points 
  • Network covalent atomic solids are held together by covalent bonds 
  • Network covalent solids do not form closest packed structures  

11.13 Crystalline Solids: Band Theory 

  • The band theory combines atomic orbitals of the atom within a solid crystal to from orbitals that are not localized on individual atoms 
  • Electrons become mobile when they make a transition from the highest occupied molecular orbital into higher energy empty molecular orbitals 
  • Occupied molecular orbitals are the valence band
  • Unoccupied orbitals are conduction bands 
  • When a metal is heated, electrons are excited and go to a higher molecular orbital 
  • An energy gap, the band gap, exists between valence and conduction bands in semiconductors and insulators 

Doping: Controlling the Conductivity of Semiconductors

  • Dope semiconductors contain holes in the valence band