Chem 161 Dr. Jasmine Bryant
Chapter 1: Matter, Energy, and the Origins of the Universe Problems: 1.1-1.10, 1.14-1.22, 1.24-1.93, 1.96 Science: study of nature that results in a logical explanation of the observations Chemistry: study of matter, its properties, and the changes it undergoes In what fields is chemistry used today? How is it used?
1.2 Matter: An Atomic View We study matter at different levels: macroscopic: the level which we can observe with the naked eye (geologists study rocks at the macroscopic level) microscopic: the level which we can observe using a microscope (scientists study tiny animals, plants, or crystals at the microscopic level) atomic or molecular (also called particulate): at the level of atoms and molecules can only be observed using the most powerful microscopes most atoms and molecules are a few nanometers in size The term nanotechnology refers to materials created or developed by manipulating atoms and/or molecules
1.1 Classes of Matter matter: anything that has mass and occupies volume Types of matter we deal with: pure substances (elements & compounds): a single chemical consisting of only one kind of matter mixtures (homogeneous & heterogeneous): Two or more pure substances can combine to form mixtures
Pure Substances Two types of pure substances: elements: consist of only one type of atom atoms cannot be broken down into smaller components by chemical reaction Examples: copper wire (Cu), sulfur powder (S 8 ), sodium (Na), barium (Ba), hydrogen gas (H 2 ), oxygen gas (O 2 ), and chlorine gas (Cl 2 ). compounds: consist of more than one type of atom and have a specific chemical formula Examples include hydrogen chloride (HCl), water (H 2 O), sodium chloride (NaCl) [table salt], barium chloride (BaCl 2 )
Mixtures Two or more pure substances can combine to form mixtures. mixtures: consist of many compounds and/or elements, with no specific formula Matter having variable composition with definite or varying properties can be separated into component elements and/or compounds Examples: Any alloy like brass, steel, 10-K to 18-K gold (anything less than 24K gold); course mixtures like sea water, carbonated soda; air is a mixture consisting of nitrogen (~78%), oxygen (21%), and other trace gases.
Mixtures Mixtures can be homogeneous or heterogeneous: Homogeneous mixtures have a uniform appearance and composition. e.g. solutions (salt water, soda, etc.), metallic alloys, homogenized milk Heterogeneous mixtures do not have a uniform composition e.g. chocolate chip cookie, coarse mixture of sand and iron filings, raw milk
1.6 States of Matter Matter exists in one of three physical states: solid, liquid, gas Ex. 1: A few drops of food coloring is added to a beaker of water. How would you expect the water to appear after a few minutes? Why? Ex. 2: If you add a drop of food coloring on top of an ice cube, would you expect the same result? Why? To understand matter, we must recognize how particles behave at the molecular level.
States of Matter
Gas Volume is variable, particles are widely spaced Takes the shape of the container because particles are moving If container volume expands, particles move apart to fill container If container volume decreases, particles move closer together Particles are in constant random motion
Liquid Fixed (or constant) volume, but shape can change Takes the shape of the container because particles are moving Particles are packed closely together but move around each other
Solid Has definite shape, rigid volume Particles can only vibrate in place
Sublimation Changes of State Gas Condensation Vaporization Liquid Freezing Deposition Melting Solid
Properties of Matter Intensive Properties: properties independent of quantity Density Boiling point Freezing point Extensive Properties: properties that depend on quantity Mass Volume
Physical and Chemical Properties and Changes Physical Properties: physical state (solid, liquid, gas) electrical and heat conductivity color solubility (amount of solid that dissolves in liquid) density hardness melting and boiling points odor Chemical Properties: how a substance reacts with other substances e.g. hydrogen reacts explosively with oxygen
Chemical vs. Physical Changes Physical Change: a process that does not alter the chemical makeup of the starting materials changing shape, changing physical state, dissolving boiling water, melting ice, hammering gold into foil, dissolving salt in water Note: In the images here, the chemical makeup of H 2 O does not change as it goes from a solid to a liquid and to a gas.
Chemical vs. Physical Changes Chemical Change: a process that does changes the chemical makeup of the starting materials We can use space-filling models to show what happens at the molecular-level when H 2 and O 2 react to form water (H 2 O) of each molecule. Notice that the H 2 O has a different chemical makeup than H 2 and O 2.
Chemical vs. Physical Changes The following examples are all chemical changes that convert the reactants to completely different compounds and/or elements. release of gas bubbles (fizzing) formation of insoluble solid (precipitation) oxidation of matter (burning or rusting)
Example Problem 1 Consider the following molecular-level representations of different substances: A B C E D F For each figure above, indicate if it represents an element, a compound, or a mixture AND if it represents a solid, liquid, or gas.
Example Problem 2 Match the following substances with the correct molecular-level representation. A B C E D F ammonia (NH 3 ) air hydrogen sodium chloride mercury copper
Example Problem 3 Which of the following are chemical changes? burning condensing dissolving melting vaporizing rusting
Making Measurements and Expressing Results Accuracy vs. Precision accuracy: indicates how close a measurement is to the true value precision: refers to how closely two or more measurements agree with one another For each diagram (above), what is the level of accuracy and precision? accurate inaccurate precise imprecise
Testing a Hypothesis The Big Bang Revisited In the 1960s, the US launched the first communication satellites, called Echo and Telstar, which were basically reflective spheres that bounced microwave signals from transmitters to receivers back on Earth. Bell Labs in NJ had built an antenna to receive such signals, and two Bell Lab scientists, Robert W. Wilson and Arno A. Penzias, were trying to improve the antenna s reception. But they kept picking up a background signal, no matter where they directed the antenna.
Testing a Hypothesis The Big Bang Revisited Assuming the signal was just an artifact, even attributing it to pigeons roosting on the antenna, the pair continued testing the equipment until they finally realized their original hypothesis must have been wrong, that the nuisance signal was not an artifact but actually significant.
Testing a Hypothesis The Big Bang Revisited Wilson and Penzias learned that a Princeton University physicist named Robert Dicke had predicted residual energy left over from the Big Bang. Their nuisance signal matched Professor Dicke s predicted Big Bang microwave echo Wilson and Penzias shared the Nobel Prize in Physics in 1978 for discovering the cosmic microwave background radiation of the universe.