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ENERGY KEY IDEAS 〉What is the relationship between energy and work? 〉Why is potential energy called energy of position? 〉What factors does kinetic energy depend on? 〉What is nonmechanical energy? ENERGY OVERVIEW Whenever work is done, energy is transformed or is transferred from one system to another system. Energy: the capacity to do work Energy is measured in joules (J). Energy Potential Energy Kinetic Energy Other Forms of Energy Mechanical Chemical Nuclear Electrical Light FORMS OF ENERGY 〉Potential energy (PE) is sometimes called energy of position because it results from the relative positions of objects in a system. Potential Energy: the energy that an object has because of the position, shape, or condition of the object FORMS OF ENERGY 〉Kinetic energy depends on both the mass and the speed of an object. Kinetic Energy: the energy of an object due to the object’s motion KE = ½ mass speed squared, or KE= ½mv 2 FORMS OF ENERGY Mechanical Energy: the amount of work an object can do because of the object’s kinetic and potential energies In most cases, nonmechanical forms of energy are just special forms of either kinetic or potential energy. FORMS OF ENERGY Chemical reactions involve potential energy. The amount of chemical energy associated with a substance depends in part on the relative positions of the atoms it contains. Living things get energy from the sun. Plants use photosynthesis to turn the energy in sunlight into chemical energy. The sun gets energy from nuclear reactions. The sun is fueled by nuclear fusion reactions in its core. FORMS OF ENERGY Energy can be stored in fields. Electrical energy results from the location of charged particles in an electric field. When electrons move from an area of higher electric potential to an area of lower electric potential, they gain energy. FORMS OF ENERGY Light can carry energy across empty space. Light energy travels from the sun to Earth across empty space in the form of electromagnetic waves. Electromagnetic waves are made of electric and magnetic fields, so light energy is another example of energy stored in a field. PRACTICE You should already have learned that energy is always conser ved. Instead of being created or destroyed, energy just changes from one form to another. For example, sunlight is the ultimate source of energy on Ear th. Look at the illustration below, and identify the types of energy involved. 1 . H ow do e s s un l ight prov i de t h e e n e rg y t h e g i rl n e e ds to s w i ng t h e ba t ? ( H in t: Wh a t do yo u n e e d to h ave e n e rg y ?) 2 . Wh e n t h e g i rl h i t s t h e ba l l , s h e exe r t s a fo rc e o n i t . D o e s s h e do wo rk o n t h e ba l l i n t h e s c i e nt ific s e n se o f t h e te rm ? E x pl a in yo ur a n s we r. 3 . Af te r t h e g i rl h i t s t h e ba l l, t h e ba l l m oves ve r y fa s t a n d h a s e n e rg y. W h e n t h e ba l l h i t s t h e fi e l der’ s g l ove, i t s to ps m ov ing. G i ven t h a t e n e rgy c a n n ever be de s t roye d but m e re ly c h a n ges fo rm , w h a t h a ppe n s to t h e e n e rg y t h e ba l l o n c e h a d ? ( H in t: If yo u a re t h e fi e l der, w h a t do yo u h e a r a n d fe e l a s yo u c a t c h t h e ba l l ?) DISCUSS WITH YOUR PARTNER 1 . When does the sled have the most potential energy? When does it have the least potential energy? 2. Where does the sled have the most kinetic energy and the least kinetic energy? 3. What happens to the relative amounts of potential and kinetic energy as the sled slides down the hill? What happens to the total energy? 4. Af ter the sled reaches the bottom of the hill, it coasts across level ground and eventually stops. What happened to the energy the sled had? CONSERVATION OF ENERGY KEY IDEAS 〉How does energy change? 〉What is the law of conservation of energy? 〉How much of the work done by a machine is actually useful work? LAW OF CONSERVATION OF ENERGY Energy cannot be created or destroyed. In other words, the total amount of energy in the universe never changes, although energy may change from one form to another. Energy does not appear or disappear. Whenever the total energy in a system increases, it must be due to energy that enters the system from an external source. ENERGY IN SYSTEMS Systems may be open, closed, or isolated. •open system: energy and matter are exchanged with the surroundings •closed system: energy but not matter is exchanged •isolated system: neither energy nor matter is exchanged Most real-world systems are open. EFFICIENCY OF MACHINES 〉How much of the work done by a machine is actually useful work? 〉Only a portion of the work done by any machine is useful work— that is, work that the machine is designed or intended to do . Not all of the work done by a machine is useful work. because of friction, work output < work input Efficiency is the ratio of useful work out to work in. PRACTICE State the Law of Conservation of Energy in your own words. Give an example of a situation you have encountered in which this law was demonstrated.