ENERGY ENERGY CHART Definition WORK POWER ENERGY Transfer

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ENERGY

ENERGY

ENERGY CHART Definition WORK POWER ENERGY Transfer of energy Rate in which energy is

ENERGY CHART Definition WORK POWER ENERGY Transfer of energy Rate in which energy is being transferred The ability to do work Calculation Formula Force X Distance Energy transferred Time Kinetic energy = ½ X Mass X Velosity² Gravitational Potential Energy = Weight X Height Units of Measure Newton meters Watts Joule Symbol N·m W J

WORK: • When a force moves an object through a distance. • The transfer

WORK: • When a force moves an object through a distance. • The transfer of energy.

POWER • The rate in which energy is transferred • The amount of energy

POWER • The rate in which energy is transferred • The amount of energy transferred in a unit of time

ENERGY • The ability to do work • Anytime work is being done on

ENERGY • The ability to do work • Anytime work is being done on an object it gains energy.

VELOCITY • Speed and direction of an object

VELOCITY • Speed and direction of an object

newton • The newton is the unit of force derived in the SI system

newton • The newton is the unit of force derived in the SI system • It is equal to the amount of force required to give a mass of one kilogram an acceleration of one meter per second squared. • Newton = Mass (kg) X the acceleration of gravity (9. 8)

KINETIC ENERGY • Energy of motion • Increases as the mass increases • Increases

KINETIC ENERGY • Energy of motion • Increases as the mass increases • Increases as the velocity increases

POTENTIAL ENERGY • Stored energy • Held in readiness • Has the potential of

POTENTIAL ENERGY • Stored energy • Held in readiness • Has the potential of doing work

Calculating Potential Energy Gravitational Potential Energy is the Potential Energy related to an objects

Calculating Potential Energy Gravitational Potential Energy is the Potential Energy related to an objects height. Gravitational Potential Energy = Weight X Height

Elastic Potential Energy • Potential Energy associated with objects that can be stretched. •

Elastic Potential Energy • Potential Energy associated with objects that can be stretched. • Example: An archer readying his bow and arrow.

CONVERTING MASS (kg) to newtons The average cell phone weighs. 100 kg. How much

CONVERTING MASS (kg) to newtons The average cell phone weighs. 100 kg. How much does it weigh in newtons? MASS (kg) X 9. 8 = newtons. 100 kg X 9. 8 =. 98 n

YOU TRY… An object has a mass of 3. 8 kg. How much force

YOU TRY… An object has a mass of 3. 8 kg. How much force does it have?

MASS (kg) x 9. 8 (gravitational force) 3. 8 kg X 9. 8 (gravitational

MASS (kg) x 9. 8 (gravitational force) 3. 8 kg X 9. 8 (gravitational force) 37. 24 n

CALCULATING KENETIC ENERGY Kinetic Energy = ½ X Mass X Velocity²

CALCULATING KENETIC ENERGY Kinetic Energy = ½ X Mass X Velocity²

An object has a mass of 5. 7 kg is moving at 3. 5

An object has a mass of 5. 7 kg is moving at 3. 5 m/s. What is its KENETIC ENERGY? • KE = ½ X MASS X VELOCITY² • KE= ½ X (5. 7 kg X 9. 8) X (3. 5 X 3. 5) • KE = ½ X 55. 89 n X 12. 25 • KE = 342. 32 J

YOU TRY… An object with a mass of 11. 12 kg is moving at

YOU TRY… An object with a mass of 11. 12 kg is moving at 5. 5 m/s. How much kinetic energy does it have? KE = ½ X MASS (n) X Velocity² KE= ½ X (11. 12 kg X 9. 8) X 5. 5² KE = ½ X 108. 97 n X 5. 5² KE = ½ X 108. 97 n X 30. 25 m/s² KE = 1648. 17 J

Potential Energy An object weighs 50 n and is sitting on a shelf 3.

Potential Energy An object weighs 50 n and is sitting on a shelf 3. 5 meters from the floor. What is its potential energy? PE = W X H PE = 50 n X 3. 5 PE = 175 J

YOU TRY… An object is sitting on a brick wall at the height of

YOU TRY… An object is sitting on a brick wall at the height of 5. 8 m. The mass of the object is 10. 3 kg. What is its POTENTIAL ENERGY? DID YOU REMEMBER TO CONVERT kg to n? PE = W X H PE = 100. 94 n X 5. 8 m PE = 585. 45 J

INSTRUCTIONS #1: • Fold a piece of paper in half 3 times hamburger style.

INSTRUCTIONS #1: • Fold a piece of paper in half 3 times hamburger style. • Draw a roller coaster • Number each area where the fold meets the coaster lines.

INSTRUCTIONS #2 Make the chart below in your folder Kinetic 1 2 3 4

INSTRUCTIONS #2 Make the chart below in your folder Kinetic 1 2 3 4 5 6 7 Potential

At each number describe whether the roller coasters KINETIC ENERGY is increasing or decreasing.

At each number describe whether the roller coasters KINETIC ENERGY is increasing or decreasing. Describe weather the potential energy is increasing or decreasing.

EXAMPLE #1 The average cell phone weighs. 100 kg. How much does it weigh

EXAMPLE #1 The average cell phone weighs. 100 kg. How much does it weigh in newtons? Kinetic Energy =½ X. 100 kg X 9. 8 (force of gravity) Kinetic Energy = ½ X. 98 n Kenetic Energy =

EXAMPLE Wile E. Coyote is attempting to push a 50000 kg safe on the

EXAMPLE Wile E. Coyote is attempting to push a 50000 kg safe on the roadrunner below. How much KENETIC ENERGY will the street absorb?

USING THE FORMULA Kinetic Energy = ½ X Mass X Velocity ² ½ X

USING THE FORMULA Kinetic Energy = ½ X Mass X Velocity ² ½ X 50000 kg X 9. 8² ½ X 50000 kg X (9. 8 X 9. 8) ½ X 50000 kg X 96. 04 ms/s 2401000. 0 n

CALCULATE WORK newton: • unit of force based on the metric system • It

CALCULATE WORK newton: • unit of force based on the metric system • It is the force that produces an acceleration of 1 meter per second when exerted on a mass of 1 kilogram. • The newton is named for Sir Isaac Newton.

JOULE • One joule is the work done, or energy expended. • Can also

JOULE • One joule is the work done, or energy expended. • Can also be called a newton meter

FORMS OF ENERGY

FORMS OF ENERGY

MECHANICAL ENERGY • Associated with the position and motion of an object. • Objects

MECHANICAL ENERGY • Associated with the position and motion of an object. • Objects in motion have mechanical energy only. ( A car racing down the road) • Objects can have gravitational potential energy only. (A trophy sitting on the shelf) • Sometimes objects can have both. (A football being thrown)

MECHANICAL ENERGY + / OR KINETIC ENERGY POTENTIAL ENERGY

MECHANICAL ENERGY + / OR KINETIC ENERGY POTENTIAL ENERGY

KENETIC ENERGY Gravitational Potential Energy

KENETIC ENERGY Gravitational Potential Energy

MECHANICAL ENERGY = Potential Energy + Kinetic Energy

MECHANICAL ENERGY = Potential Energy + Kinetic Energy

FORMS OF ENERGY THAT INVOLVE THE MOVEMENT OF PARTICLES TO SMALL TO SEE.

FORMS OF ENERGY THAT INVOLVE THE MOVEMENT OF PARTICLES TO SMALL TO SEE.

THERMAL ENERGY ALL OBJECTS ARE MADE UP OF PARTICLES CALLED ATOMS AND MOLECULES. ATOMS

THERMAL ENERGY ALL OBJECTS ARE MADE UP OF PARTICLES CALLED ATOMS AND MOLECULES. ATOMS ARE IN CONSTANT MOTION, THEREFORE, THE FASTER THEY MOVE, THE MORE KINETIC ENERGY THEY HAVE.

THERMAL ENERGY IS THE TOTAL POTENTIAL AND KINETIC ENERGY OF THE PARTICLES IN AN

THERMAL ENERGY IS THE TOTAL POTENTIAL AND KINETIC ENERGY OF THE PARTICLES IN AN OBJECT.

ELECTRICAL ENERGY • ENERGY OF ELECTRICAL CHARGES • Lightning has Kinetic Energy • Batteries

ELECTRICAL ENERGY • ENERGY OF ELECTRICAL CHARGES • Lightning has Kinetic Energy • Batteries have Potential Energy

CHEMICAL ENERGY • Chemical compounds are objects made up of two or more elements.

CHEMICAL ENERGY • Chemical compounds are objects made up of two or more elements. –Salt ( Sodium + Chlorine) –Carbon Dioxide (Carbon + Oxygen)

 • Chemical energy hold these bonds together • Chemical energy is stored in

• Chemical energy hold these bonds together • Chemical energy is stored in foods we eat, matches and cells in your body. • When the bonds in the chemical compounds break, new chemical compounds may form and chemical energy may be released.

NUCLEAR ENERGY • Potential Energy because it is stored in the NUCLEUS of the

NUCLEAR ENERGY • Potential Energy because it is stored in the NUCLEUS of the atom

 • Nuclear energy is released during a nuclear reaction –Nuclear fission occurs when

• Nuclear energy is released during a nuclear reaction –Nuclear fission occurs when the nucleus splits. Used in power plants to make electricity. –Nuclear Fusion occurs when the nuclei of atoms join together. Occurs in the sun.

ELECTROMAGNETIC ENERGY • Example: Sunlight • Travel in waves • Have properties of both

ELECTROMAGNETIC ENERGY • Example: Sunlight • Travel in waves • Have properties of both electrical properties and magnetic properties.

ENERGY TRANSFORMATION and CONSERVATION

ENERGY TRANSFORMATION and CONSERVATION

ENERGY TRANSFORMATION • A change from one form of energy to another. • Most

ENERGY TRANSFORMATION • A change from one form of energy to another. • Most forms of energy can be transformed into other forms.

SINGLE TRANFORMATION • Changing one form of energy to another. • Toaster takes electrical

SINGLE TRANFORMATION • Changing one form of energy to another. • Toaster takes electrical energy and transfers it to thermal energy. • As we eat food, chemical energy from the food is transferred to mechanical energy for us to do work. • Electrical energy from the batteries inside our cell phones is transferred to electromagnetic energy for communication

MULTIPLE TRANSFORMATION

MULTIPLE TRANSFORMATION

MECANICAL ENERGY TO THERMAL ENERGY

MECANICAL ENERGY TO THERMAL ENERGY

THERMAL ENERGY CAUSES A THE PARTICLES IN THE MATCH TO RELEASE THE STORED CHEMICAL

THERMAL ENERGY CAUSES A THE PARTICLES IN THE MATCH TO RELEASE THE STORED CHEMICAL ENERGY (phosphorous and a chlorate mix)

Chemical energy is turned into Electromagnetic energy (light)

Chemical energy is turned into Electromagnetic energy (light)

TRANSFORMATIONS BETWEEN POTENTIAL AND KINETIC ENERGY

TRANSFORMATIONS BETWEEN POTENTIAL AND KINETIC ENERGY

Highest potential Energy, no kinetic Energy Potential Energy increases, Kinetic Energy decreases Kinetic Energy

Highest potential Energy, no kinetic Energy Potential Energy increases, Kinetic Energy decreases Kinetic Energy increases, no potential energy

GREATEST POTENTIAL ENERGY Greatest Kinetic Energy, No Potential Energy

GREATEST POTENTIAL ENERGY Greatest Kinetic Energy, No Potential Energy

KINETIC ENERGY

KINETIC ENERGY

KINETIC ENERGY to ELASTIC ENERGY

KINETIC ENERGY to ELASTIC ENERGY

ELASTIC ENERGY TO POTENTIAL ENERGY

ELASTIC ENERGY TO POTENTIAL ENERGY

POTENTIAL ENERGY TO KINETIC ENERGY

POTENTIAL ENERGY TO KINETIC ENERGY

LAW of CONSERVATION of ENERGY Energy cannot be created nor destroyed

LAW of CONSERVATION of ENERGY Energy cannot be created nor destroyed

ENERGY AND FRICTION • Friction transfers mechanical energy to thermal energy • No machine

ENERGY AND FRICTION • Friction transfers mechanical energy to thermal energy • No machine is 100% effective because some of its energy is transferred into thermal energy.

ENERGY AND MATTER • Albert Einstein's theory of relativity states that energy can sometimes

ENERGY AND MATTER • Albert Einstein's theory of relativity states that energy can sometimes be created by destroying matter. • By destroying just a small amount of matter releases huge amounts of energy.

THE TRANSFER OF HEAT

THE TRANSFER OF HEAT

THERMAL ENERGY • The total energy of all particles in an object • The

THERMAL ENERGY • The total energy of all particles in an object • The more particles an object has at a given temperature the more thermal energy it has. • The higher the temperature, the higher thermal energy it has.

HEAT • The transfer of thermal energy from matter at higher temperatures to matter

HEAT • The transfer of thermal energy from matter at higher temperatures to matter at a lower temperature.

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http: //www. learn 360. com/Show. Video. aspx ? Tag. Name=conduction&ID=34162

Three ways heat can move • Conduction • Radiation • Convection

Three ways heat can move • Conduction • Radiation • Convection

CONDUCTION • Transfer of heat from one particle of matter to another part without

CONDUCTION • Transfer of heat from one particle of matter to another part without the movement of matter.

CONVECTION • Transfer of heat through a current within a fluid. • Convection currents

CONVECTION • Transfer of heat through a current within a fluid. • Convection currents are when warm air rises and the cool air flows into its place.

RADIATION • Transfer of energy by electromagnet waves. • Does not need matter to

RADIATION • Transfer of energy by electromagnet waves. • Does not need matter to transfer heat.

HEAT FLOW • Heat flows from a warm object to a cooler object •

HEAT FLOW • Heat flows from a warm object to a cooler object • When heat flows into matter, thermal energy and the temperature of the matter increases. • At the same time, the temperature of the matter loosing the heat decreases.

HOW DOES ICE CREAM GETS COLD? 1) The ingredients in the ice cream (milk

HOW DOES ICE CREAM GETS COLD? 1) The ingredients in the ice cream (milk and sugar) is not as cold as the ice cream itself. 2) Within the ice cream maker, a metal can packed with ice is used. 3) Ingredients turn colder because its thermal energy transfers to the colder ice filled can.

CONDUCTORS • Materials that transfer energy well • Depends of the density and how

CONDUCTORS • Materials that transfer energy well • Depends of the density and how the particles are arranged. INSULATORS • Materials that do not conduct heat well • Examples: Wood, straw, wool and gasses. • Clothes are not good conductors because they prevent the transfer of thermal energy.

ENERGY and FOSSIL FUELS

ENERGY and FOSSIL FUELS

FORMATION of FOSSIL FUELS • Fuel is a material that contains potential energy •

FORMATION of FOSSIL FUELS • Fuel is a material that contains potential energy • Some fuels used today are made from materials that formed hundreds of million years ago. • Coal, petrolium and natural gasses are known as fossil fuels

FORMATION OF COAL • Over time, plants and animals died • Remains piled up

FORMATION OF COAL • Over time, plants and animals died • Remains piled up in thick swamps and marshes • Clay and sand covered them causing great pressures and temperatures • Coal is formed

ENERGY FROM THE SUN • Fuels do not create energy • Fossil Fuels contain

ENERGY FROM THE SUN • Fuels do not create energy • Fossil Fuels contain energy that came from the Sun. • Suns electromagnetic energy transforms living things into chemical energy. • As these animals and plants died their, chemical energy was trapped in the coal.

Use of Fossil Fuels • Fossil fuels can be burned to release the chemical

Use of Fossil Fuels • Fossil fuels can be burned to release the chemical energy. • The process of burning fuels is known as combustion • Combustion is the transfer of energy from chemical energy to thermal energy.

USING FOSSIL FUELS Sun transforms nuclear energy to electromagnet energy

USING FOSSIL FUELS Sun transforms nuclear energy to electromagnet energy

Ancient plants and animals transform electromagnet energy from the sun to stored energy. Their

Ancient plants and animals transform electromagnet energy from the sun to stored energy. Their remains are coal.

Coal is burned to make steam, transforming stored chemical energy to thermal energy

Coal is burned to make steam, transforming stored chemical energy to thermal energy

The steam turns turbines, transforming thermal energy to mechanical energy.

The steam turns turbines, transforming thermal energy to mechanical energy.

The turbines spin electric generators, transforming mechanical energy to electrical energy

The turbines spin electric generators, transforming mechanical energy to electrical energy

Your hair dryer transforms electrical energy to thermal energy

Your hair dryer transforms electrical energy to thermal energy

GRADE TIME (due today): Take EVERYTHING out of your notebooks Look for: – –

GRADE TIME (due today): Take EVERYTHING out of your notebooks Look for: – – – NOTES: What is Energy? (pg 442 – 446) Section 1 Assessment page 446 NOTES: Forms of Energy (pg 447 – 451) Section 2 Assessment page 451 NOTES: Energy Transformation Conservation (454 – 459) Section 3 Assessment NOTES: Transfer of Heat ( pg 479 – 483) Section 4 Assessment page 495 NOTES: Energy and Fossil Fuels (pg 462 – 465) Section 4 Assessment page 465 Workbook pages 265 - 278