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Title: Chapter 2 Matter and Energy


1
Chapter 2Matter and Energy
2
Representations of Matter
  • Goal 1
  • Identify and explain the differences among
    observations of matter at the macroscopic,
    microscopic, and particulate levels.
  • Goal 2
  • Define the term model as it is used in chemistry
    to represent pieces of matter too small to see.

3
Representations of Matter
  • Anything that has mass (sometimes expressed as
    weight) and takes up space is called matter.
  • Matter can be observed and/or thought about at
    different levels
  • Macroscopic
  • Microscopic
  • Particulate

4
Representations of Matter
  • Macroscopic Samples of Matter
  • Mountains
  • Rocky cliffs
  • Huge boulders
  • Rocks and stones
  • Gravel
  • Sand
  • Macro- means large

5
Representations of Matter
  • Microscopic Samples of Matter
  • Tiny animals or plants
  • Cells
  • Crystals on rock surfaces
  • Micro- means small

6
Representations of Matter
  • Particulate Samples of Matter
  • Too small to see, even with the most
  • powerful optical microscope.
  • Chemists imagine the nature of the behavior of
    the tiny particles that make up matter, based on
    experimental measurements and models of matter,
    and they use that knowledge to carry out changes
    from one type of matter to another.

7
Representations of Matter
  • Macroscopic, Microscopic, and Particulate Matter

8
Representations of Matter
  • Model
  • A representation of something.
  • Geologists model the earth (globe).
  • Biologists model cells.
  • Chemists model atoms and molecules.

9
Representations of Matter
  • Ball-and-Stick Model
  • Symbolizes atoms as balls and the electrons that
  • connect those atoms as sticks.
  • Space-Filling Model
  • Shows the outer boundaries of the particle
  • in three-dimensional space.

10
Representations of Matter
11
Representations of Matter
  • Models are represented in writing with symbols.
  • Chemical symbols are letters that represent atoms
    of elements.
  • H represents an atom of hydrogen.
  • O Represents an atom of oxygen.
  • H2O represents a molecule of water
  • Two hydrogen atoms and one oxygen atom.

12
Representations of Matter
  • Chemists make mental transformations between
    visible macroscopic matter (the liquid water) and
    models of the particulate-level molecules that
    make up the matter (red and white space-filling
    models). Written symbols (HOH on the board)
    serve as simpler representations of the
    particulate-level models.

13
States of Matter
  • Goal 3
  • Identify and explain the differences among gases,
    liquids, and solids in terms of (a) visible
    properties, (b) distance between particles, and
    (c) particle movement.

14
States of Matter
  • States of Matter
  • Familiar examples of the states of matter
  • The air you breathe is a gas.
  • The water you drink is a liquid.
  • The food you eat is a solid.

15
States of Matter
  • Kinetic Molecular Theory
  • All matter consists of extremely tiny particles
  • that are in constant motion.
  • Kinetic refers to motion.
  • Molecular comes from molecule, the smallest
  • unit particle that can exist independently and
  • possess the identity of the substance.
  • Theory is a hypothesis that has been tested and
  • confirmed by many experiments.

16
States of Matter
  • The speed at which particles move is faster at
    higher temperatures and slower at lower
    temperatures.
  • There is an attraction among particles in all
    samples of matter.
  • The state of matter of any sample depends on
    temperature (the speed at which particles move)
    and the attractions among the particles that make
    up the sample.

17
States of Matter
  • Particulate-Level Behavior of States of Matter
  • Gas
  • Particles are independent of one another,
  • moving in random fashion
  • Liquid
  • Particles move freely among themselves, but clump
    together
  • Solid
  • Particles vibrate in fixed positions relative to
    one another

18
States of Matter
19
Properties and Changes
  • Goal 4
  • Distinguish between physical and chemical
    properties at both the particulate level and the
    macroscopic level.
  • Goal 5
  • Distinguish between physical and chemical changes
    at both the particulate level and the macroscopic
    level.

20
Properties and Changes
  • Physical Properties
  • Description as detected by senses
  • Color, shape, odor, etc.
  • Measurable properties
  • Density, boiling point, etc.
  • Examples
  • Charcoal is black
  • Glass is hard
  • The normal boiling point of water is 100C

21
Properties and Changes
  • Physical Changes
  • Alteration of the physical form of matter
  • without changing its chemical identity
  • No new substance formed
  • Examples
  • Ice melts to liquid water
  • Dry ice changes to gaseous carbon dioxide
  • A rock is ground into sand

22
Properties and Changes
  • In a Physical Change, the Molecules are Unchanged

23
Properties and Changes
  • Chemical Changes
  • Chemical identity of a substance is destroyed
  • A new substance is formed
  • Examples
  • Water decomposes to hydrogen and oxygen gases
    when subjected to an electrical current
  • Iron rusts
  • Food is digested

24
Properties and Changes
  • In a Chemical Change, the Molecules Change

25
Properties and Changes
26
Properties and Changes
  • Chemical Properties
  • The types of chemical change a substance
  • is able to participate in.
  • Examples
  • A chemical property of water is that it can be
    decomposed to its elements when subjected to an
    electrical current.
  • A chemical property of iron is that it will
  • rust under certain conditions.
  • A chemical property of starch is that it reacts
    to form
  • sugar during digestion.

27
Properties and Changes
Chemical Physical
Changes Chemical identity of a substance is destroyed New substances formed New form of same substance No new substances formed
Properties Types of chemical changes possible Description as detected by the senses Measurable properties
28
Substances and Mixtures
  • Goal 6
  • Distinguish between a pure substance and a
    mixture at both the macroscopic level and the
    particulate level.
  • Goal 7
  • Distinguish between homogeneous and heterogeneous
    matter.

29
Substances and Mixtures
  • Pure Substance
  • A sample consisting of only one kind of matter,
  • either compound or element
  • made up entirely of one kind of particle.
  • Unique set of physical and chemical properties.
  • Cannot be separated into parts by a physical
    change.

30
Substances and Mixtures
  • Mixture
  • A sample of matter that consists of two or more
    substances.
  • Physical and chemical properties of a mixture
    vary with
  • different relative amounts of the parts.
  • Can be separated into parts via physical
    processes.

31
Substances and Mixtures
  • Pure water has a constant boiling pointa
    physical property.
  • The boiling point of a mixture (solution) changes
    as the composition of the mixture changes.

32
Substances and Mixtures
  • You cannot distinguish a pure substance from a
    mixture of uniform appearance by observation
    alone at the macroscopic level.

33
Substances and Mixtures
  • Solution
  • A homogeneous mixture of two or more components.
  • Homogeneous
  • A sample that has uniform
  • appearance and composition throughout.
  • Examples Tea, paint, gasoline
  • Heterogeneous
  • A sample with different phases, usually visible.
  • Examples Carbonated beverages, salad dressings

34
Substances and Mixtures
  • Homogeneous Matter may be Either a Pure Substance
    or a Mixture

35
Separation of Mixtures
  • Goal 8
  • Describe how distillation and filtration rely on
    physical changes and properties to separate
    components of mixtures.

36
Separation of Mixtures
  • Most natural substances are mixtures.
  • Separation processes are an important part of
    chemistry.
  • Nitrogen and oxygen are separated from the
    mixture called air.
  • Pure water is separated from the mixture called
    natural water.
  • Gasoline is separated from the mixture called
    crude oil.

37
Separation of Mixtures
  • A Physical Property, Magnetism, Allows a Mixture
    of Iron and Sulfur to be Separated

38
Separation of Mixtures
  • Distillation
  • Separation of the parts of a mixture by heating a
    liquid solution until one component boils,
    changing into the gaseous state.
  • The pure substance in the gaseous state is then
  • collected and cooled into the liquid state.
  • Boiling is a physical change.
  • Distillation allows components in a homogeneous
    mixture
  • to be separated into one or more pure substances.

39
Separation of Mixtures
  • Laboratory Distillation Apparatus

40
Separation of Mixtures
  • Filtration
  • Separation of the components of a mixture by
    physical means by using a porous medium, such as
    filter paper, to separate components based upon
    relative particles sizes.
  • Filtration is based on the physical properties of
    a mixture
  • The particle sizes of a component to be separated
  • must be significantly larger or smaller than the
  • pore size of the filtration medium.

41
Separation of Mixtures
  • Gravity Filtration

42
Elements and Compounds
  • Goal 9
  • Distinguish between elements and compounds.
  • Goal 10
  • Distinguish between elemental symbols and the
    formulas of chemical compounds.
  • Goal 11
  • Distinguish between atoms and molecules.

43
Elements and Compounds
  • Element
  • Pure substance that cannot be decomposed into
    other pure substances by ordinary chemical means.
  • Atom
  • Smallest particle of an element that can combine
    with atoms of other elements to form chemical
    compounds.
  • Compound
  • Pure substance that can be broken down into two
    or more
  • other pure substances by a chemical change.

44
Elements and Compounds
  • The Element Silver and a Particulate-Level Model
    of Silver Atoms

45
Elements and Compounds
  • Mixtures are separated into pure substances by
    physical means compounds are separated into pure
    substances by chemical changes.

46
Elements and Compounds
  • Elements
  • At least 88 elements occur in nature.
  • Examples copper, sulfur, gold, silver
  • 11 elements occur in nature as gases
  • 2 occur as liquids (mercury and bromine)
  • the others occur as solids.
  • Name of an element is always a single word
  • compound names are usually two words
  • or a polysyllabic compound word.

47
Elements and Compounds
  • Major Elements of the Human Body
  • Element Percentage Composition by Number of Atoms
  • Hydrogen 63.0
  • Oxygen 25.5
  • Carbon 9.45
  • Nitrogen 1.35
  • These four elements make up 99.3 of the atoms in
    your body.

48
Elements and Compounds
  • Familiar Objects that are Composed of Nearly Pure
    Elements

49
Elements and Compounds
  • Familiar Objects that are Compounds

50
Elements and Compounds
  • Elemental Symbols
  • Letters that symbolize elements
  • The first letter of the name of the element,
  • written in uppercase, is often its symbol.
  • Examples Hydrogen, H
  • Oxygen, O
  • Carbon, C
  • If more than one element begins with the same
    letter,
  • a second lowercase letter is added.
  • Examples Helium, He
  • Osmium, Os
  • Chlorine, Cl

51
Elements and Compounds
  • Chemical Formulas
  • Symbolic representations of the particles of a
    pure substance.
  • A combination of the symbols of all the elements
    in a substance.
  • The formula of most elements is the same as the
    symbol of the element, e.g., helium He sodium,
    Na.
  • Other elements exists in nature as molecules and
    their formulas indicate the number of atoms of
    the element in the molecule, e.g., hydrogen, H2
    oxygen, O2.

52
Elements and Compounds
  • Formula Unit
  • Molecule or simplest ratio of particles for
    non-molecular species.
  • Ammonia molecules have the formula NH3
  • 1 atom of nitrogen and 3 atoms of hydrogen.
  • Magnesium chloride exists as an orderly,
    repeating pattern
  • of magnesium and chlorine in a 12 ratio
  • Its formula unit is MgCl2.

53
Elements and Compounds
  • Law of Definite Composition or
  • Law of Constant Composition
  • Any compound is always made up of elements in
  • the same proportion by mass (weight).
  • No matter its source, water (H2O) is
  • 11.1 parts hydrogen per 88.9 parts oxygen.

54
Elements and Compounds
  • The Properties of a Compound are Different from
    the
  • Properties of the Elements that Make Up the
    Compound
  • Water, H2O
  • Liquid at 25C, melts at 0C, boils at 100C
  • Hydrogen, H2
  • Gas at 25C, melts at 259C, boils at 253C
  • Oxygen, O2
  • Gas at 25C, melts at 219C, boils at 183C

55
Elements and Compounds
  • Particulate and Macroscopic Views of Elements and
    Compounds

56
Elements and Compounds
  • Particulate and Macroscopic Views of Elements and
    Compounds

57
Elements and Compounds
  • Particulate and Macroscopic Views of Elements and
    Compounds

58
Elements and Compounds
  • Summary of the Classification System for Matter

59
Electrical Character of Matter
  • Goal 12
  • Match electrostatic forces of attraction and
    repulsion with combinations of positive and
    negative charge.

60
Electrical Character of Matter
  • Two of the fundamental forces that govern
  • the operation of the universe are
  • Force of gravity
  • Electromagnetic force
  • The electromagnetic force plays an important role
    in understanding chemistry.
  • It includes electricity and magnetism.

61
Electrical Character of Matter
  • Force Field
  • Region in space where the force is effective.
  • Electrostatic Force
  • The force of an electrical charge that does not
    move.
  • A charged object exerts an invisible
    electrostatic force.

62
Electrical Character of Matter
  • Experimental evidence shows that
  • There are only two types of electrical charge,
  • positive and negative.
  • Two objects having the same charge,
  • both positive or both negative, repel each other.
  • Two objects having unlike charges,
  • one positive and one negative, attract each other.

63
Electrical Character of Matter
  • Electrostatic forces show that matter has
    electrical properties.
  • These forces are responsible for the energy
    absorbed or released in chemical changes.

64
Chemical Change
  • Goal 13
  • Distinguish between reactants and products in a
    chemical equation.
  • Goal 14
  • Distinguish between exothermic and endothermic
    changes.
  • Goal 15
  • Distinguish between potential energy and kinetic
    energy.

65
Chemical Change
  • Chemical Equation
  • A symbolic representation of chemical change,
    with the formulas of the beginning substances to
    the left of an arrow that points to the formulas
    of the substances formed.
  • Reactant
  • Original substance
  • Product
  • Substance formed as a result of chemical change
  • 2 H2O 2 H2 O2
  • Reactant Products

66
Chemical Change
  • Exothermic Reaction
  • A chemical change that releases energy to its
    surroundings.
  • ExampleBurning charcoal
  • C O2 CO2 energy

67
Chemical Change
  • Endothermic Reaction
  • A chemical change that absorbs energy from its
    surroundings.
  • Example
  • Decomposition of water to its elements
  • 2 H2O energy 2 H2 O2

68
Chemical Change
  • Energy
  • The ability to do work.
  • Potential Energy
  • Energy due to position in a field where forces of
  • attraction and/or repulsion are present.
  • Gravitational Potential Energy
  • Position in the earths gravitational field.
  • Electrical Potential Energy
  • Position in an electrical field.

69
Chemical Change
  • Minimization of energy
  • One of the driving forces that cause chemical
    reactions to occur.
  • Chemical energy comes largely from the
    rearrangement of
  • charged particles in an electrostatic field.

70
Chemical Change
  • Kinetic Energy
  • Energy of motion
  • The temperature of an object is proportional to
    the
  • average kinetic energy of its particles.

71
Conservation Laws
  • Goal 16
  • State the meaning of, or draw conclusions based
    on, the Law of Conservation of Mass.
  • Goal 17
  • State the meaning of, or draw conclusions based
    on, the Law of Conservation of Energy.

72
Conservation Laws
  • The Conservation Law
  • In any change, the sum of mass plus energy is
    conserved
  • they are neither created nor destroyed.
  • ?E ?m ? c2
  • Matter is an extremely concentrated form of
    energy.

73
Conservation Laws
  • Law of Conservation of Mass
  • In a nonnuclear change, mass is conserved
  • it is neither created nor destroyed.
  • Mass may change form, however.
  • In any ordinary chemical change,
  • Total mass of reactants Total mass of products

74
Conservation Laws
  • Law of Conservation of Energy
  • In a nonnuclear change, energy is conserved
  • it is neither created nor destroyed.
  • Energy may change form, however.
  • The energy lost in one form is always exactly
    equal
  • to the energy gained in another form.

75
Conservation Laws
  • Common Events in which Energy Changes
  • from One Form to Another
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