Section 1: Matter and Energy

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Section 1: Matter and Energy Preview Key Ideas Bellringer Kinetic Theory States of Matter Energy’s Role

Key Ideas What makes up matter? What is the difference between a solid, a liquid, and a gas? What kind of energy do all particles of matter have?

Kinetic Theory What makes up matter? According to the kinetic theory of matter, matter is made of atoms and molecules. These atoms and molecules act like tiny particles that are always in motion.

Kinetic Theory, continued The following are observations of particles in motion: The higher the temperature of the substance is, the faster the particles move. At the same temperature, more massive particles move slower than less massive ones. The kinetic theory helps to explain the differences between the three common states of matter: solid, liquid, and gas.

Visual Concept: Kinetic Molecular Theory

States of Matter What is the difference between a solid, a liquid, and a gas? You can classify matter as a solid, a liquid, or a gas by determining whether the shape and volume are definite or variable.

States of Matter, continued Solids have a definite shape and volume. Liquids change shape, not volume. Gases change both shape and volume. fluid: a nonsolid state of matter in which the atoms or molecules are free to move past each other, as in a gas or liquid Plasma is the most common state of matter. plasma: a state of matter that consists of free-moving ions and electrons

Three States of Matter

Visual Concept: Solid, Liquid, and Gas

Energy’s Role What kind of energy do all particles of matter have? Because they are in motion, all particles of matter have kinetic energy. energy: the capacity to do work

Energy’s Role, continued Temperature is a measure of average kinetic energy. temperature: a measure of how hot (or cold) something is; specifically, a measure of the average kinetic energy of the particles in an object Thermal energy depends on particle speed and number of particles. thermal energy: the total kinetic energy of a substance’s atoms

Kinetic Energy and States of Matter

Understanding Concepts, continued 4. Plastic is put into molds to create specific shapes. In what state of matter should the plastic be when it is put in the mold, and why?

Understanding Concepts, continued 4. Plastic is put into molds to create specific shapes. In what state of matter should the plastic be when it is put in the mold, and why? Answer: The plastic should be in liquid form, because liquids conform to the shape of their containers.

Section 2: Changes of State Preview Key Ideas Bellringer Energy and Changes of State Conservation of Mass and Energy

Key Ideas What happens when a substance changes from one state of matter to another? What happens to mass and energy during physical and chemical changes?

Energy and Changes of State What happens when a substance changes from one state of matter to another? The identity of a substance does not change during a change of state, but the energy of a substance does change.

Changes of State

Energy and Changes of State, continued Some changes of state require energy. Changes of state that require energy are melting, evaporation, and sublimation. evaporation: the change of state from a liquid to a gas sublimation: the process in which a solid changes directly into a gas

Energy and Changes of State, continued Energy is released in some changes of state. Changes of state that release energy are freezing and condensation. condensation: the change of state from a gas to a liquid

Changes of State for Water

Interpreting Graphics, continued 9. Which arrow indicates evaporation? F. 1 H. 3 G. 2 I. 4

Interpreting Graphics, continued 9. Which arrow indicates evaporation? F. 1 H. 3 G. 2 I. 4

Interpreting Graphics, continued 10. Which arrow indicates sublimation? A. 2 C. 4 B. 3 D. 5

Interpreting Graphics, continued 10. Which arrow indicates sublimation? A. 2 C. 4 B. 3 D. 5

Interpreting Graphics, continued 11. Which three arrows indicate a phase change that occurs at 0 °C?

Interpreting Graphics, continued 11. Which three arrows indicate a phase change that occurs at 0 °C? Answer: 2, 3, and 5

Conservation of Mass and Energy What happens to mass and energy during physical and chemical changes? Mass and energy are both conserved. Neither mass nor energy can be created or destroyed.

Conservation of Mass and Energy, continued Mass cannot be created or destroyed. In chemical changes, as well as in physical changes, the total mass of the substances undergoing the change stays the same before and after the change. This is the law of conservation of mass.

Understanding Concepts, continued 3. In the year 2012, a space probe investigating Neptune scoops up a load of solid frozen oxygen from the planet’s atmosphere. Upon entry into Earth’s atmosphere, some of the solid oxygen immediately changes into a gas. Which of the following processes happened? A. evaporation C. sublimation B. condensation D. melting

Understanding Concepts, continued 3. In the year 2012, a space probe investigating Neptune scoops up a load of solid frozen oxygen from the planet’s atmosphere. Upon entry into Earth’s atmosphere, some of the solid oxygen immediately changes into a gas. Which of the following processes happened? A. evaporation C. sublimation B. condensation D. melting

Visual Concept: Law of Conservation of Mass

Conservation of Mass and Energy, continued Energy cannot be created or destroyed. Energy may be changed to another form during a physical or chemical change, but the total amount of energy present before and after the change is the same. This is the law of conservation of energy.

Visual Concept: Law of Conservation of Energy

Understanding Concepts, continued 5. A kitchen scientist combines 5.0 g of baking soda with 100.0 g of vinegar, which causes a gas (carbon dioxide) to be given off. After all of the gas has escaped, the liquid has a mass of 102.4 g. What is the mass of the escaped gas?

Understanding Concepts, continued 5. A kitchen scientist combines 5.0 g of baking soda with 100.0 g of vinegar, which causes a gas (carbon dioxide) to be given off. After all of the gas has escaped, the liquid has a mass of 102.4 g. What is the mass of the escaped gas? Answer: 2.6 g

Section 3: Fluids Preview Key Ideas Bellringer Pressure Buoyant Force Comparing Weight and Buoyant Force Pascal’s Principle Math Skills Fluids in Motion

Key Ideas How do fluids exert pressure? What force makes a rubber duck float in a bathtub? What happens when pressure in a fluid changes? What affects the speed of a fluid in motion? GLOBAL NOTE: Section 2 at top of slide needs to be changed to Section 3

Pressure How do fluids exert pressure? Fluids exert pressure evenly in all directions. pressure: the amount of force exerted per unit area of a surface example: when you pump up a bicycle tire, air particles constantly push against each other and against the tire walls

Pressure, continued Pressure can be calculated by dividing force by the area over which the force is exerted: The SI unit for pressure is the pascal. pascal: the SI unit of pressure; equal to the force of 1 N exerted over an area of 1 m2 (symbol, Pa)

Visual Concept: Equation for Pressure

Understanding Concepts An industrial thermometer is heated until the mercury inside it is exerting 400 N of force against the inner surface. That surface has a total area of 200 cm2. How much pressure is the mercury exerting against the inner surface of the thermometer? Note that 1 Pa = 1 N/m2. A. 800 Pa C. 8,000 Pa B. 2,000 Pa D. 20,000 Pa

Understanding Concepts 1. An industrial thermometer is heated until the mercury inside it is exerting 400 N of force against the inner surface. That surface has a total area of 200 cm2. How much pressure is the mercury exerting against the inner surface of the thermometer? Note that 1 Pa = 1 N/m2. A. 800 Pa C. 8,000 Pa B. 2,000 Pa D. 20,000 Pa

Interpreting Graphics, continued 12. In which tank is the greatest pressure being exerted on the tank’s inner surface?

Interpreting Graphics, continued In which tank is the greatest pressure being exerted on the tank’s inner surface? Answer: Tank A

Buoyant Force What force makes a rubber duck float in a bathtub? All fluids exert an upward buoyant force on matter. buoyant force: the upward force that keeps an object immersed in or floating on a fluid

Buoyant Force, continued Archimedes’ principle is used to find buoyant force. The buoyant force on an object in a fluid is an upward force equal to the weight of the fluid that the object displaces.

Comparing Weight and Buoyant Force

Buoyant Force, continued An object will float or sink based on its density. If an object is less dense than the fluid in which it is placed, it will float. If an object is more dense than the fluid in which it is placed, it will sink.

Density

Pascal’s Principle What happens when pressure in a fluid changes? Pascal’s principle states that a change in pressure at any point in an enclosed fluid will be transmitted equally to all parts of the fluid. In other words, if the pressure in a container is increased at any point, the pressure increases at all points by the same amount. Mathematically, Pascal’s principle is stated as P1 = P2. Because P = F/A, Pascal’s principle can also be expressed as F1/A1 = F2/A2.

Pascal’s Principle, continued Hydraulic devices are based on Pascal’s principle. Because the pressure is the same on both sides of the enclosed fluid, a small force on the smaller area (left) produces a much larger force on the larger area (right). The plunger travels through a larger distance on the side that has the smaller area.

Math Skills Pascal’s Principle A hydraulic lift uses Pascal’s principle to lift a 19,000 N car. If the area of the small piston (A1) equals 10.5 cm2 and the area of the large piston (A2) equals 400 cm2, what force needs to be exerted on the small piston to lift the car? 1. List the given and unknown values. Given: F2 = 19,000 N A1 = 10.5 cm2 A2 = 400 cm2 Unknown: F1

Math Skills, continued 2. Start with Pascal’s principle, and substitute the equation for pressure. Then, rearrange the equation to isolate the unknown value. P1 = P2

Math Skills, continued 3. Insert the known values into the equation, and solve. F1 = 500 N

Fluids in Motion What affects the speed of a fluid in motion? Fluids move faster through small areas than through larger areas, if the overall flow rate remains constant. Fluids also vary in the rate at which they flow.

Fluids in Motion, continued Viscosity depends on particle attraction. viscosity: the resistance of a gas or liquid to flow Fluid pressure decreases as speed increases. This is known as Bernoulli’s principle.

Visual Concept: Viscosity

Section 4: Behavior of Gases Preview Key Ideas Bellringer Properties of Gases Gas Laws Math Skills

Key Ideas What are some properties of gases? How can you predict the effects of pressure, temperature, and volume changes on gases?

Properties of Gases What are some properties of gases? Gases expand to fill their containers. They spread out easily and mix with one another. They have low densities and are compressible. Unlike solids and liquids, gases are mostly empty space. Also, gases exert pressure on their containers.

Visual Concept: Properties of Gases

Gas Laws How can you predict the effects of pressure, temperature, and volume changes on gases? The gas laws will help you understand and predict the behavior of gases in specific situations. gas laws: the laws that state the mathematical relationships between the volume, temperature, pressure, and quantity of a gas

Boyle’s law relates the pressure of a gas to its volume. Gas Laws Boyle’s law relates the pressure of a gas to its volume. Boyle’s law: For a fixed amount of gas at a constant temperature, the volume of a gas increases as the gas’s pressure decreases. Likewise, the volume of a gas decreases as the gas’s pressure increases. P1V1 = P2V2

Visual Concept: Boyle’s Law

Math Skills Boyle’s Law The gas in a balloon has a volume of 7.5 L at 100 kPa. The balloon is released into the atmosphere, and the gas expands to a volume of 11 L. Assuming a constant temperature, what is the pressure on the balloon at the new volume? 1. List the given and unknown values. Given: V1 = 7.5 L P1 = 100 kPa V2 = 11 L Unknown: P2

Math Skills, continued 2. Write the equation for Boyle’s law, and rearrange the equation to solve for P2. 3. Insert the known values into the equation, and solve. P1V1 = P2V2 P2 = 68 kPa

Gas Laws, continued Gay-Lussac’s law relates gas pressure to temperature. Gay-Lussac’s law: The pressure of a gas increases as the temperature increases, if the volume of the gas does not change. The pressure decreases as the temperature decreases. Charles’s law relates temperature to volume. Charles’s law: For a fixed amount of gas at a constant pressure, the volume of the gas increases as the gas’s temperature increases. Likewise, the volume of the gas decreases as the gas’s temperature decreases.

Visual Concept: Charles’s Law

Understanding Concepts, continued 2. A sealed refuse container is buried near a fault line, and seismic activity brings the container close to an underground source of geothermal heat. As the container gets warmer, what happens to the internal air pressure of the container? F. Particles are far apart and move freely. G. Particles are close together and vibrate in place. H. Particles are far apart and unable to change location. I. Particles are close together and move past each other easily.

Understanding Concepts, continued 2. A sealed refuse container is buried near a fault line, and seismic activity brings the container close to an underground source of geothermal heat. As the container gets warmer, what happens to the internal air pressure of the container? F. Particles are far apart and move freely. G. Particles are close together and vibrate in place. H. Particles are far apart and unable to change location. I. Particles are close together and move past each other easily.

Interpreting Graphics, continued 13. As more helium is released from the tank, the person who is inflating the balloons notices that the tank has become cold to the touch. Why does this happen?

Interpreting Graphics, continued As more helium is released from the tank, the person who is inflating the balloons notices that the tank has become cold to the touch. Why does this happen? Answer: Given a constant volume, as the pressure of a gas decreases, so does the temperature.