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“Energy”
Task 1 Read the words and word combinations:
Quantity – количество; ability – способность; since – поскольку; path – путь; to contain –содержать; matter – материя; to change – менять; customary –привычный; to transfer – передавать; to emit – испускать; to impact – ударять; kinetic energy – кинетическая энергия; to appear – появляться; thermal energy –тепловая энергия; to occur – встречаться; to store – хранить; particle – частица; potential energy – потенциальная энергия; to lift – поднимать; gravity field – гравитационное поле; to compress – сжимать; efficiency – эффективность; to result in – приводить к; value – значение; relative to – относительный.
Task 2 Read the text:
Energy
In physics, energy is a quantity that is often understood as the ability a physical system has to do work on other physical systems. Since work is defined as a force acting through a distance (a length of space), energy is always equivalent to the ability to exert pulls or pushes against the basic forces of nature, along a path of a certain length. The total energy contained in an object is identified with its mass, and energy (like mass), cannot be created or destroyed. When matter (ordinary material particles) is changed into energy (such as energy of motion, or into radiation), the mass of the system does not change through the transformation process. However, there may be mechanistic limits as to how much of the matter in an object may be changed into other types of energy and thus into work, on other systems. Energy, like mass, is a scalar physical quantity. In the International System of Units (SI), energy is measured in joules, but in many fields other units, such as kilowatt-hours and kilocalories, are customary. All of these units translate to units of work, which is always defined in terms of forces and the distances that the forces act through. A system can transfer energy to another system by simply transferring matter to it (since matter is equivalent to energy, in accordance with its mass). However, when energy is transferred by means other than matter-transfer, the transfer produces changes in the second system, as a result of work done on it. This work manifests itself as the effect of force(s) applied through distances within the target system. For example, a system can emit energy to another by transferring (radiating) electromagnetic energy, but this creates forces upon the particles that absorb the radiation. Similarly, a system may transfer energy to another by physically impacting it, but that case the energy of motion in an object, called kinetic energy, results in forces acting over distances (new energy) to appear in another object that is struck. Transfer of thermal energy by heat occurs by both of these mechanisms: heat can be transferred by electromagnetic radiation, or by physical contact in which direct particle-particle impacts transfer kinetic energy.
Energy may be stored in systems without being present as matter, or as kinetic or electromagnetic energy. Each of the basic forces of nature is associated with a different type of potential energy, and all types of potential energy (like all other types of energy) appears as system mass, whenever present. For example, a compressed spring will be slightly more massive than before it was compressed. Likewise, whenever energy is transferred between systems by any mechanism, an associated mass is transferred with it. Any form of energy may be transformed into another form. For example, all types of potential energy are converted into kinetic energy when the objects are given freedom to move to different position. When energy is in a form other than thermal energy, it may be transformed with good or even perfect efficiency, to any other type of energy, including electricity or production of new particles of matter. With thermal energy, however, there are often limits to the efficiency of the conversion to other forms of energy, as described by the second law of thermodynamics. In all such energy transformation processes, the total energy remains the same, and a transfer of energy from one system to another, results in a loss to compensate for any gain. This principle, the conservation of energy, was first postulated in the early 19th century, and applies to any isolated system. Although the total energy of a system does not change with time, its value may depend on the frame of reference. For example, a seated passenger in a moving airplane has zero kinetic energy relative to the airplane, but non-zero kinetic energy relative to the Earth.
Task 3 Answer the questions:
1. What is energy?
2. What kinds of energy are there?
3. What contains the energy?
4. How can the energy be transferred?
5. What does the second law of thermodynamics describe?
Task 4 Remake the sentences from Active Voice to Passive and vice versa:
1. Energy is understood as the ability a physical system.
2. A system can transfer energy to another system.
3. Energy is measured in joules.
4. Work is defined as a force, acting through a distance.
5. A system can emit energy to another.
6. Energy may be stored in systems without being present as matter.
7. Each of the basic forces of nature is associated with a different type of potential energy.
8. It was described by the second law of thermodynamics.
9. The conservation of energy was first postulated in the early 19th century.
10. They can apply this law to any isolated system.
Task 5 Ask Disjunctive, General and Special types of questions to the given sentences:
1. The total energy contained in an object is identified with its mass.
2. The mass of the system does not change through the transformation process.
3. Energy is a scalar physical quantity.
4. A system can emit energy to another by transferring electromagnetic energy.
5. Energy may be stored in systems without being present as matter.
6. A compressed spring will be slightly more massive than before it was compressed.
7. Any form of energy may be transformed into another form.
8. All types of potential energy are converted into kinetic energy.
9. The conservation of energy was first postulated in the early 19th century.
10. The energy value depends on the frame of reference.
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