Chapter 12

Chapter 12 States of Matter

Kinetic Molecular Theory • Composition and structure (types of atoms & arrangments) determine chem properties of matter • Also affect physical properties • Kinetic Molecular Theory – describes behavior of matter in terms of particles in motion • Kinetic is Greek for “to move” • Ludwig Boltman & James Maxwell proposed model to explain properties of gases

Kinetic Molecular Theory • Several assumptions are made by the model: • Particle Size • Gases consist of small particles separated by empty space. • Volume of particles are small compared to volume of empty space • No significant attractive/repulsive forces since particles are so far apart • Particle Motion • Particle Energy

Kinetic Molecular Theory • Several assumptions are made by the model: • Particle Size • Particle Motion • Particles are in constant, random motion that move in straight lines until they collide • Collisions between gas particles are elastic. No kinetic energy is lost (may be transferred). • Particle Energy

Kinetic Molecular Theory • Several assumptions are made by the model: • Particle Size • Particle Motion • Particle Energy • Mass and velocity determine kinetic energy • m=mass • v=velocity (speed and direction) • Temperature measure of average KE in a sample of matter

Behavior of Gases • KMT explains behavior of gases • Constant motion of particles allows gas to expand and fill container • Low Density () • Gas with lower density => fewer molecules than another element in the same volume • Compression/Expansion • Compression – reduce volume • Air is compressible • Expansion – larger volume

Behavior of Gases • Diffusion & Effusion: • Since gas particles are not attracted to one another, they easily pass by each other • When gas flows from one space to another space already occupied by a gas, the gases will mix until evenly distributed (diffusion) • Diffusion – movement of one material through another • Particles diffuse from area of high concentration to low concentration • Ex: food coloring in water, smell when cooking, etc.

Behavior of Gases • Diffusion & Effusion ~ cont.: • Effusion – gas escapes through tiny opening • Graham’s Law of Effusion – • means “inversely proportional to”

Behavior of Gases • Heavier particles diffuse slower than lighter particles • Therefore, Graham’s Law can also set up a proportion to compare diffusion rates of 2 gases:

Example 1 Ammonia has molar mass = 17 g/mol, hydrogen chloride has molar mass of 36.5 g/mol. What is ratio of diffusion rates? **On the right track as HCl is about twice as massive as ammonia!

Example 2 Calculate ratio of effusion rates for nitrogen (N2) and neon (Ne). Soln: 0.849

Gas Pressure • Pressure – force per unit area • Air Pressure (atmospheric) – pressure is exerted in all directions and varies in different locations due to gravity changes (at different elevations). • P is lower at higher altitudes • At sea level,

Gas Pressure • Measuring Air Pressure: • Barometer – instrument used to measure atmospheric pressure • At sea level, ~760 mmHg • Changes in air temp or humidity changes pressure! • Manometer – instrument used to measure gas pressure in closed container

Units of Pressure • Units of Pressure: • SI unit is a pascal (Pa) • ** • At sea level, average air pressure is 101.3 kPa when

Comparison of Pressure Units

Dalton’s Law of Partial Pressure • Dalton’s Law of Partial Pressures – Total pressure of mixture of gases = sum of the pressures of all gases in mixture • Each gas in a mixture exerts pressure independently of other gasses

Example 3 A mixture of O2 gas, CO2 and N2 has a total pressure of 0.97 atm. What is the partial pressure of O2 if the partial pressure of CO2=0.70 atm and N2=0.12 atm?

Chapter 12.2 Forces of Attraction

Intermolecular Forces • Intramolecular Forces: • Attractive forces that hold particles together in ionic, metallic, and covalent bonds • “intra-” means forces within • Intermolecular Forces • The forces occur between or among particles • 3 types: • Dispersion Forces: weak forces that result in temporary shifts in density of electron clouds • Dipole-Dipole – attraction between oppositely charged regions of polar molecules • Hyrdrogen Bonding – (type of dipole-dipole) bond that exists between H and one of the following: F, O, N

Dispersion Forces • Weak forces • Sometimes called London forces after physicist Fritz London • Electrons in electron cloud are in constant motion • When 2 electron clouds come in contact, they repel • For q quick moment, the electron density is greater in one region forming a temporary dipole • All particles consist of dispersion forces • As size of particle increase, dispersion forces increase too (stronger)

Dipole-Dipole Forces • Polar molecules contain permanent dipoles (some regions are always partially pos/neg) • Neighboring molecules orient themselves so oppositely charged particles will align

Hydrogen Bonds • Typically stronger than dipole-dipole and dispersion • H bonding only occurs with F, O, N (FON or “phone”)

Comparison

Chapter 12.3 Liquids and Solids

Liquids • Recall, (Chap 3) • Take shape of container! • Forces of attraction keep molecules closely packed in fixed volume, but not in fixed position. • Density and Compression: • Liquids are much denser than gases - stronger intermolecular forces holds particles together. • Large amounts of pressure must be applied to compress liquids to very small amounts. • Liquids considered incompressible

Liquids • Fluidity - ability to flow and diffuse; liquids and gases are fluids. • Liquids diffuse slower than gases at the same temp due to intermolecular forces interfering with flow • Viscosity - measure of resistance of a liquid to flow • Determined by type of intermolecular forces, size and shape of particles, and temp • Particles in liquid are close enough for attractive forces to slow their movement as they flow past one another • The stronger the intermolecular attractive forces, the higher the viscosity

Liquids • Viscosity~Cont. • Larger molecules create greater viscosity. • Long chains of molecules result in higher viscosity. • Increasing the temp decreases viscosity - adds energy that allows molecules to overcome intermolecular forces and flow more freely.

Liquids • Surface Tension - energy required to increase the surface area of a liquid by a given amount. • Particles in middle can be attracted to particles above, below and on either side • No attractive forces above for particles on surface to balance forces from below • Net forces is pulled down => surface pulled tight • Stronger attractive forces means stronger surface tension **Soaps/detergents decrease surface tension by disrupting H-Bonds. When bond is broken, water spreads out allowing dirt to be carried away! • Surfactants- compounds that lower the surface tension of water.

Liquids **When water placed in glass tube, the surface of the water is not straight (meniscus) • Cohesion - force of attraction between identical molecules • Adhesion - force of attraction between molecules that are different • Capillary action- upward movement of liquid into a narrow cylinder, or capillary tube (how paper towels work!)

Solids • Recall: • Definite volume • Definite shape • Most solids are more dense than liquids. • Ice is not more dense than water. • Particles in solid ARE in constant motion! • Particles in a solid vibrate in a fixed position • To be solid vs. liquid at room temp, there must be strong attractive intermolecular forces • These forces limit motion of particles in vibration creating order

Solids • Crystalline Solids - solids with atoms, ions, or molecules arranged in orderly, geometric shape • Location of particles is are represented by points on crystal lattice frame work

Solids • Unit Cell – smallest arrangement of atoms in crystal lattice that has same symmetry as whole crystal (building block) • Crystal shapes differ since surfaces/faces of unit cells do not always meet at right angles

Solids • 5 Categories of Crystalline Solids: • Molecular Solids • Solids held together by dispersion, dipole-dipole or H-Bonding • Most not solid at room temp • Poor conductors of heat and electricity • Covalent Network Solids • Form multiple covalent bonds (C, Si, etc) • Ex: carbon forms diamonds • Ionic Solids • Metallic Solids • Amorphous Solids

Solids • 5 Categories of Crystalline Solids: • Ionic Solids • Each ion is surrounded by ions of opposite charge • High MP and Hardness • Strong but brittle • Metallic Solids • Positive metal surrounded by sea of electrons • Malleable and ductile • Good conductors of heat and electricity • Amorphous Solids • Particles not arranged in regular, repeating pattern (no crystals) • Generally form when molten material cools too quickly to allow crystals to form • Ex: glass, rubber, plastics

Chapter 12.4 Phase Changes

Phase Changes • Phase changes require energy! • When Energy is added/removed from system, one phase can change into another

Phase Changes • Melting: • What happens when you put ice cubes in water? • Water is @ high temp & heat flows from water to ice! • Heat is transfer of energy from object with higher temp to object with lower temp • At ice’s MP, the E ice absorbs disrupts the H-bonds that hold water molecule together in ice crystal • When enough E is absorbed, the H-bonds break and move apart to enter liquid phase • Melting Point – temp in which forces holding crystal lattice together are broken & become liquid

Phase Changes • Vaporization: • Process by which liquid changes from liquid to a gas/vapor • When ice melts, temp of ice and water remain constant until ice is melted completely • If heat still being added, THEN temp will increase • **Vapor – gas phase of substance that is usually a liquid at room temp • If input of E is gradual, molecules tend to escape from surface of liquid. When vaporization occurs only at surface of a liquid, you get evaporation.

Phase Changes

Phase Changes • Vapor Pressure – pressure exerted by a vapor over a liquid • Boiling Point – temp where VP of liquid = the atmospheric pressure • At BP, bubbles begin to form indicating an increase in E • Sublimation – process of a solid changing directly to a gas • Ex: dry ice, moth balls, air fresheners, etc.

Phase Changes • Phase changes that Release E: • Freezing Point – temp where liquid is converted into crystalline solid • Heat is removed from system, KE decreases & velocity decreases • H-bonding increases creating a solid • Condensation – process where gas/vapor becomes a liquid • Vapor loses E, velocity decreases, H-bonding increase • Ex: condensation on glass, dew on grass, etc.

Phase Changes • Deposition – process of gas/vapor changing to solids without becoming a liquid • Ex: frost

Phase Changes • Phase Change Diagrams – graphs of P vs. T that show phase of different substances under different conditions • temp & pressure control phase of substance • Pts on curve is where 2 phases coexist • Triple Point – point that represents temp and pressure where all 3 phases exist • Critical Point – point of critical temp and pressure water can NOT exist as liquid

Phase Changes

Chapter 12

Chapter 12

Presentation Transcript

Chapter 12

Chapter 12

Chapter 12

Chapter 12

Chapter 12

Chapter 12

Chapter 12

Chapter 12

Chapter 12

Chapter 12

Chapter 12

Chapter 12

CHAPTER 12

Chapter 12

Chapter 12

Chapter 12

Chapter 12

Chapter 12

Chapter 12

Chapter 12

Chapter 12

Chapter 12