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