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The law of conservation of energy basically states that you can't create energy out of nothing. You also can't destroy energy. Energy is a quantity that remains constant, in a closed system (one that has no contact with the outside world). The law of conservation of energy is also called the First Law of Thermodynamics.
You can, however, convert useful energy into useless (or unusable) energy - and this can no longer be converted back to useful energy - in other words, there are irreversible processes in nature. This is the Second Law of Thermodynamics.
The law of conservation of energy basically states that you can't create energy out of nothing. You also can't destroy energy. Energy is a quantity that remains constant, in a closed system (one that has no contact with the outside world). The law of conservation of energy is also called the First Law of Thermodynamics.
You can, however, convert useful energy into useless (or unusable) energy - and this can no longer be converted back to useful energy - in other words, there are irreversible processes in nature. This is the Second Law of Thermodynamics.
The law of conservation of energy basically states that you can't create energy out of nothing. You also can't destroy energy. Energy is a quantity that remains constant, in a closed system (one that has no contact with the outside world). The law of conservation of energy is also called the First Law of Thermodynamics.
You can, however, convert useful energy into useless (or unusable) energy - and this can no longer be converted back to useful energy - in other words, there are irreversible processes in nature. This is the Second Law of Thermodynamics.
The law of conservation of energy basically states that you can't create energy out of nothing. You also can't destroy energy. Energy is a quantity that remains constant, in a closed system (one that has no contact with the outside world). The law of conservation of energy is also called the First Law of Thermodynamics.
You can, however, convert useful energy into useless (or unusable) energy - and this can no longer be converted back to useful energy - in other words, there are irreversible processes in nature. This is the Second Law of Thermodynamics.
What else can I help you with?
Which of the two laws covered laws of conservation of momentum or law of conservation of energy is obeyed in this problem explain your reasoning?
The law of conservation of energy is obeyed in this problem. This law states that energy cannot be created or destroyed, only transferred or transformed. In contrast, the law of conservation of momentum states that the total momentum of a system remains constant if no external forces act on it, which may not necessarily apply in all situations.
How are the laws of conservation of mass and conservation of energy similar and how are they different?
The laws of conservation of mass and conservation of energy are similar in that both state that the total amount of mass or energy in a closed system remains constant over time. However, the conservation of mass applies specifically to mass, while the conservation of energy applies to energy in its various forms (kinetic, potential, etc.).
How is friction different from the laws of conservation of energy?
Friction is a force that resists relative motion between two surfaces, leading to energy loss in the form of heat. The laws of conservation of energy state that energy cannot be created or destroyed, only transferred or transformed from one form to another. Friction causes energy to be dissipated, leading to a loss of mechanical energy in a system.
Which of the conservation law does not apply to an inelastic collision?
Both conservation laws are applied. The conservation of momentum and conservation of energy. However, in an inelastic collision, kinetic energy is not conserved. But total energy IS CONSERVED and the principle of conservation of energy does hold.
How does using a computer converts to the laws of conservation?
The most relevant conservation law in this case is probably the Law of Conservation of Energy. The computer uses electrical energy, most of which is eventually converted into heat. A small part will go out as sound, and as low-frequency electromagnetic waves.
Explain the generation and recombination of electrons and holes in semiconductor?
Simply, the two fundamental laws are energy conservation and and momentum conservation.
How is the conservation of momentum important to astronomy?
There are several conservation laws in physics, and many of them tell an astronomer what is, and what isn't, possible. This can help explain how certain things happen, or even predict what will happen. Among the laws of conservation that are relevant in astronomy are: conservation of mass; conservation of energy; conservation of momentum; conservation of rotational momentum; conservation of charge.
What is the law of conservation in your own words?
There are many different laws of conservation, but they are essentially the same. For this example I will use energy. The laws of conservation of energy say that energy in = energy out. This is to say that energy cannot be destroyed or created.
Briefly list and explain the main provisions of the money laundering laws that apply in your country where you live.?
Briefly list and explain the main provisions of the money laundering laws that apply in your country where you live.
Year the law of conservation was discovered?
There are many laws of conservation. Some of the better-known ones are the law of conservation of energy, of momentum, and of rotational momentum.There are many laws of conservation. Some of the better-known ones are the law of conservation of energy, of momentum, and of rotational momentum.There are many laws of conservation. Some of the better-known ones are the law of conservation of energy, of momentum, and of rotational momentum.There are many laws of conservation. Some of the better-known ones are the law of conservation of energy, of momentum, and of rotational momentum.
Which of the two laws covered laws of conservation of momentum or law of conservation of energy is obeyed in this problem explain your reasoning?
The law of conservation of energy is obeyed in this problem. This law states that energy cannot be created or destroyed, only transferred or transformed. In contrast, the law of conservation of momentum states that the total momentum of a system remains constant if no external forces act on it, which may not necessarily apply in all situations.
What are the gas laws explain briefly?
Gas laws explain how the property of a gas changes in relation to other properties under varying conditions.
How are the laws of conservation of mass and conservation of energy similar and how are they different?
The laws of conservation of mass and conservation of energy are similar in that both state that the total amount of mass or energy in a closed system remains constant over time. However, the conservation of mass applies specifically to mass, while the conservation of energy applies to energy in its various forms (kinetic, potential, etc.).
Why cant energy be created nor destryed?
The "why" is somewhat tricky to answer; the law of conservation of energy was originally based on observation. Nowadays, if you read about the conservation of energy, it is derived from Noether's Theorem. This is some very advanced math, but briefly, it states that every conservation law is related to a symmetry in nature. In the case of conservation of energy, it is related to the fact that laws of physics don't change over time. In other words, according to this theorem, if energy were NOT conserved, then the laws of nature would change over time! However, the details are some very advanced math. You can read the Wikipedia article on Noether's Theorem if you think you can handle it - or if you just want a brief introduction.The "why" is somewhat tricky to answer; the law of conservation of energy was originally based on observation. Nowadays, if you read about the conservation of energy, it is derived from Noether's Theorem. This is some very advanced math, but briefly, it states that every conservation law is related to a symmetry in nature. In the case of conservation of energy, it is related to the fact that laws of physics don't change over time. In other words, according to this theorem, if energy were NOT conserved, then the laws of nature would change over time! However, the details are some very advanced math. You can read the Wikipedia article on Noether's Theorem if you think you can handle it - or if you just want a brief introduction.The "why" is somewhat tricky to answer; the law of conservation of energy was originally based on observation. Nowadays, if you read about the conservation of energy, it is derived from Noether's Theorem. This is some very advanced math, but briefly, it states that every conservation law is related to a symmetry in nature. In the case of conservation of energy, it is related to the fact that laws of physics don't change over time. In other words, according to this theorem, if energy were NOT conserved, then the laws of nature would change over time! However, the details are some very advanced math. You can read the Wikipedia article on Noether's Theorem if you think you can handle it - or if you just want a brief introduction.The "why" is somewhat tricky to answer; the law of conservation of energy was originally based on observation. Nowadays, if you read about the conservation of energy, it is derived from Noether's Theorem. This is some very advanced math, but briefly, it states that every conservation law is related to a symmetry in nature. In the case of conservation of energy, it is related to the fact that laws of physics don't change over time. In other words, according to this theorem, if energy were NOT conserved, then the laws of nature would change over time! However, the details are some very advanced math. You can read the Wikipedia article on Noether's Theorem if you think you can handle it - or if you just want a brief introduction.
Is the law of conservation of charge the law of conservation of energy?
No, those are two separate conservation laws. Charge is not energy. They are entirely different things.
How is friction different from the laws of conservation of energy?
Friction is a force that resists relative motion between two surfaces, leading to energy loss in the form of heat. The laws of conservation of energy state that energy cannot be created or destroyed, only transferred or transformed from one form to another. Friction causes energy to be dissipated, leading to a loss of mechanical energy in a system.
Which of the conservation law does not apply to an inelastic collision?
Both conservation laws are applied. The conservation of momentum and conservation of energy. However, in an inelastic collision, kinetic energy is not conserved. But total energy IS CONSERVED and the principle of conservation of energy does hold.
