Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples:...

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Six Forms of Energy

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Transcript of Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples:...

Page 1: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Six Forms of Energy

Page 2: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

1. Mechanical Energy: energy due to an object’s motion or position.

Examples: moving object, stationary (still) object

Page 3: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

2. Thermal Energy: the total energy of atoms in an object.

Examples: relates to temperature of an object

Absolute Zero (0 Kelvin = -459.6° F) is the coldest temperature (atoms stop moving)!

Page 4: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

3. Chemical Energy: the potential energy stored in chemical bonds that hold atoms together.

Examples: food, matches, cells

Page 5: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

4. Electrical Energy: the energy produced by moving electric charges.

Examples: electricity (batteries, power lines)

Page 6: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

5. Electromagnetic Energy: the energy that travels in waves.

Examples: visible light, UV radiation, microwaves

Page 7: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

6. Nuclear Energy: the energy stored in the nucleus of an atom.

Examples: fusion (the Sun), fission (nuclear power plants)

Page 8: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

What form of energy is the human using to jump?

Page 9: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Energy conservation- a change from one form of energy to another.

Law of conservation of energy- when one form of energy is converted to another, no energy is destroyed in the process

Page 10: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Chemical- Electrical

Mechanical

Page 11: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Nuclear- Electromagnetic

Chemical

Mechanical

Page 12: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Nuclear

Electrical

Thermal

Page 13: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Power Lines Nuclear Energy Lamp Air Conditioner

ElectricalEnergy

NuclearEnergy

ElectromagneticEnergy

ThermalEnergy

Path A:

1. Nuclear energy converted to…

2. Electrical energy converted to…

3. Electromagnetic energy

Path B:

1. Nuclear energy converted to…

2. Electrical energy converted to…

3. Thermal energy

Page 14: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Balanced Rock

Page 15: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Pizza Slice

Page 16: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Iceberg

Page 17: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

X-Ray

Page 18: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Fire

Page 19: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Batteries

Page 20: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Remote Controlled Car

Page 21: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Corn Crop

Page 22: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

The Sun

Page 23: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Power Lines

Page 24: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Maple Tree

Page 25: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Nuclear Power Plant

Page 26: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Space Heater

Page 27: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Dolphins Jumping

Page 28: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Waterfall

Page 29: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Lightning

Page 30: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Fireworks

Page 31: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Light

Page 32: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Archery

Page 33: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Jumping

Page 34: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Candy

Page 35: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Heating Pad

Page 36: Six Forms of Energy. 1.Mechanical Energy: energy due to an object’s motion or position. Examples: moving object, stationary (still) object.

Encapsulation in C++ - Syracuse University · C++ Class Encapsulation Problem •The C++ object model has the source text of a user of an object responsible for carrying the object’s

Encapsulation in C++ - Syracuse University · C++ Class Encapsulation Problem •The C++ object model has the source text of a user of an object responsible for carrying the object’s

At General Motors’ Milford Proving a 4.pdfmotion of an object. Interpret and construct free-body diagrams. force an action exerted on an object that may change the object’s state

At General Motors’ Milford Proving a 4.pdfmotion of an object. Interpret and construct free-body diagrams. force an action exerted on an object that may change the object’s state

Energy and Its Conservation Learn that energy is a property of an object that can change the object’s position, motion, or its environment. Learn that.

Energy and Its Conservation Learn that energy is a property of an object that can change the object’s position, motion, or its environment. Learn that.

The Python Data Model - University of Washington...Python’s Data Model • Everything is an object • Each object has an identy, a type, and a value – id(obj) returns the object’s

The Python Data Model - University of Washington...Python’s Data Model • Everything is an object • Each object has an identy, a type, and a value – id(obj) returns the object’s

Chapter 12. Page 356-362 Can cause a resting object to move. It can accelerate a moving object by changing the object’s speed or direction. SI.

Chapter 12. Page 356-362 Can cause a resting object to move. It can accelerate a moving object by changing the object’s speed or direction. SI.

Introduction to Energy!€¦ · 6. Thermal energy - kinetic energy of an object’s particles. • faster the molecules move = more ... Unit 2 Lesson 1 Introduction to Energy •Energy

Introduction to Energy!€¦ · 6. Thermal energy - kinetic energy of an object’s particles. • faster the molecules move = more ... Unit 2 Lesson 1 Introduction to Energy •Energy

Acceleration. Review Distance (d) – the total ground covered by a moving object. Displacement ( x) – the difference between an object’s starting position.

Acceleration. Review Distance (d) – the total ground covered by a moving object. Displacement ( x) – the difference between an object’s starting position.

BioMed Tech Exam Review Chapter 4. The behavior of an object is defined by the object’s A.instance data B.constructor C.visibility modifiers D.methods.

BioMed Tech Exam Review Chapter 4. The behavior of an object is defined by the object’s A.instance data B.constructor C.visibility modifiers D.methods.

The Mole Concept. Relative Mass The relative mass of an object is the mass of that object as a multiple of some other object’s mass. In the example, the.

The Mole Concept. Relative Mass The relative mass of an object is the mass of that object as a multiple of some other object’s mass. In the example, the.

Python Essential Reference - pearsoncmg.comptgmedia.pearsoncmg.com/images/9780672329784/... · The type of an object,also known as the object’s class,describes the internal repre-sentation

Python Essential Reference - pearsoncmg.comptgmedia.pearsoncmg.com/images/9780672329784/... · The type of an object,also known as the object’s class,describes the internal repre-sentation

Introduction to VBA Programming. Many Types of Statements VBA statements Access object model’s methods and properties Data Access Object’s methods and.

Introduction to VBA Programming. Many Types of Statements VBA statements Access object model’s methods and properties Data Access Object’s methods and.

Object 1418-18 · object’s technical drawings have been verified and the condition of the object after the tests is assessed and recorded. The report is applicable to the object

Object 1418-18 · object’s technical drawings have been verified and the condition of the object after the tests is assessed and recorded. The report is applicable to the object

KEY CONCEPT An object in motion changes position.€¦ · •An object’s position can change NOW, you will learn • How to describe an object’s position • How to describe an

KEY CONCEPT An object in motion changes position.€¦ · •An object’s position can change NOW, you will learn • How to describe an object’s position • How to describe an

FORCES. What do we mean when we say force? A force = a push or pull upon an object resulting from the object’s interaction with another object. All forces.

FORCES. What do we mean when we say force? A force = a push or pull upon an object resulting from the object’s interaction with another object. All forces.

Kinetic and Potential Energy. Kinetic Energy Kinetic energy is the energy of movement or motion To calculate kinetic energy you need to know an object’s.

Kinetic and Potential Energy. Kinetic Energy Kinetic energy is the energy of movement or motion To calculate kinetic energy you need to know an object’s.

Types of Forces. Terms, Symbols, and Definitions Force - a push or pull upon an object resulting from the object’s interaction with another object. Forces.

Types of Forces. Terms, Symbols, and Definitions Force - a push or pull upon an object resulting from the object’s interaction with another object. Forces.

Kinetic and Potential Energy - WeeblyExplaining Kinetic and Potential Energy Every object has energy associated with it. That energy can be due to the position of the object, the object’s

Kinetic and Potential Energy - WeeblyExplaining Kinetic and Potential Energy Every object has energy associated with it. That energy can be due to the position of the object, the object’s

Object Classes In UML. Object Concepts What is an object? How do objects communicate? How is an object’s interface defined? What have objects to do with.

Object Classes In UML. Object Concepts What is an object? How do objects communicate? How is an object’s interface defined? What have objects to do with.

Lecture Presentation - Physics & AstronomySlide 2-9 Reading Question 2.3 The area under a velocity-versus-time graph of an object is A. The object’s speed at that point. B. The object’s

Lecture Presentation - Physics & AstronomySlide 2-9 Reading Question 2.3 The area under a velocity-versus-time graph of an object is A. The object’s speed at that point. B. The object’s

PERCIEVING OBJECTSmajumder/docs/chap4presentation.pdf · Slide 23 ICS 280: Visual Perception Marr’s Theory of Object Construction Computational Approach Object’s image on the

PERCIEVING OBJECTSmajumder/docs/chap4presentation.pdf · Slide 23 ICS 280: Visual Perception Marr’s Theory of Object Construction Computational Approach Object’s image on the