FTVR-004 1. The Principle of Conservation of* The principle of conservation of energy states that energy cannot be created or destroyed, but it can be transformed from one form to another. Energy is a property of matter and it is thought to be a measurement of the ability of a system to do work. It can be transferred from one form to another, but it cannot be created or destroyed. For example, a moving object has kinetic energy and when it comes to a stop it transfers its energy to the surrounding environment and when the object becomes stationary it has no more kinetic energy. The total energy at the start of the system is called the initial energy and when the total energy is equal at the start to the total energy at the end this is called conservation of energy. 2. The Principle of Conservation of Momentum** The principle of conservation of momentum states that in the absence of outside forces, the momentum of a system remains constant. Momentum is a vector quantity that is a measure of an object’s motion and it is measured in the units of kilograms per second squared (kg/s²). It is a proportional to the force exerted on the object and the time that the force is exerted. When a force is exerted on an object it changes the object’s speed and momentum. The law of conservation of momentum means that the total momentum of a system of objects will be the same unless it is acted upon by an outside force. This can be demonstrated by a group of objects colliding with one another, the collisions of these objects will cause the objects to exchange momentum, however the total momentum of the system remains the same. 3. The Principle of Conservation of Mass** The principle of conservation of mass states that in a chemical reaction the total mass of the reactants is always equal to the total mass of the products. This means that the quantity of matter in a chemical reaction is always preserved. This can be demonstrated by the conservation of mass in chemical reactions. For example, when a wire is burned in a reaction to produce water, the wire undergoes different chemical reactions and when the wire is burned it will turn into rust. The mass of the wire that is burned is equal to the mass of the rust that is formed this means that the mass of the wire is being conserved. 4. The Principle of Conservation of Charge** The principle of conservation of charge states that in a chemical reaction the total charge is always equal to the total charge of the reactants. This means that within a chemical reaction the positive and negative charges are always equal to the total charge of the products. This can be demonstrated by the conservation of charge in chemical reactions. For example, when a wire is burned in a reaction to produce water, the wire undergoes different chemical reactions and when the wire is burned it will turn into rust. The charge of the wire being burned is equal to the charge of the rust that is formed this means that the charge of the wire is being conserved. 5. The principle of conservation of energy conservation** The principle of conservation of energy conservation states that in a chemical reaction the total energy is always equal to the total energy of the reactants. This means that within a chemical reaction the energy is always preserved. This can be demonstrated by the conservation of energy in chemical reactions. For example, when a wire is burned in a reaction to produce water, the wire undergoes different chemical reactions and when the wire is burned it will turn into rust. The energy of the wire being burned is equal to the energy of the rust that is formed this means that the energy of the wire is being conserved. 6. The principle of Conservation of Energy** The principle of conservation of energy states that in a chemical reaction the total energy is always equal to the total energy of the reactants. This means that in a chemical reaction the energy is preserved and it is conserved. For example, when a wire is burned in a reaction to produce water, the wire undergoes different chemical reactions and when the wire is burned it will turn into rust. The energy of the wire being burned is equal to the energy of the rust that is formed this means that the energy of the wire is being conserved. *1. The Principle of conservation of Energy** What Individuals? What Arcs? - The principle of conservation of energy states that energy is never destroyed, but it can be transformed from one form to another. It also states that in a chemical reaction the total energy is always equal to the total energy of the reactants. This means that in a chemical reaction the energy is preserved and it is conserved. For example, when a wire is burned in a reaction to produce water, the wire undergoes different chemical reactions and when the wire is burned it will turn into rust. The energy of the wire being burned is equal to the energy of the rust that is formed this means that the energy of the wire is being conserved. *2. The Principle of conservation of Momentum** The principle of conservation of momentum states that in the absence of outside forces, the momentum of a system remains constant. Momentum is a vector quantity that is a measure of an object’s motion and it is measured in the units of kilograms per second squared (kg/s²). It is a proportional to the force exerted on the object and the time that the force is exerted. When a force is exerted on an object it changes the object’s speed and momentum. The law of conservation of momentum means that the total momentum of a system of objects will be the same unless it is acted upon by an outside force. This can be demonstrated by a group of objects colliding with one another, the collisions of these objects will cause the objects to exchange momentum, however the total momentum of the system remains the same. 3. The Principle of conservation of mass** The principle of conservation of mass states that in a chemical reaction the total mass of the reactants is always equal to the total mass of the products. This means that the quantity of matter in a chemical reaction is always preserved. This can be demonstrated by the conservation of mass in chemical reactions. For example, when a wire is burned in a reaction to produce water, the wire undergoes different chemical reactions and when the wire is burned it will turn into rust. The mass of the wire that is burned is equal to the mass of the rust that is formed this means that the mass of the wire is being conserved. 4. The principle of conservation of charge** The principle of conservation of charge states that in a chemical reaction the total charge is always equal to the total charge of the reactants. This means that within a chemical reaction the positive and negative charges are always equal to the total charge of the products. This can be demonstrated by the conservation of charge in chemical reactions. For example, when a wire is burned in a reaction to produce water, the wire undergoes different chemical reactions and when the wire is burned it will turn into rust. The charge of the wire being burned is equal to the charge of the rust that is formed this means that the charge of the wire is being conserved. 5. The principle of conservation of energy conservation** The principle of conservation of energy conservation states that in a chemical reaction the total energy is always equal to the total energy of the reactants. This means that within a chemical reaction the energy is always preserved. This can be demonstrated by the conservation of energy in chemical reactions. For example, when a wire is burned in a reaction to produce water, the wire undergoes different chemical reactions and when the wire is burned it will turn into rust. The energy of the wire being burned is equal to the energy of the rust that is formed this means that the energy of the wire is being conserved. 6. The Principle of Conservation of Energy** The principle of conservation of energy states that in a chemical reaction the total energy is always equal to the total energy of the reactants. This means that in a chemical reaction the energy is preserved and it is conserved. For example, when a wire is burned in a reaction to produce water, the wire undergoes different chemical reactions and when the wire is burned it will turn into rust. The energy of the wire being burned is equal to the energy of the rust that is formed this means that the energy of the wire is being conserved. *1. The Principle of conservation of Energy** What Individuals? What Arcs? - The principle of conservation of energy states that energy is never destroyed, but it can be transformed from one form to another. It also states that in a chemical reaction the total energy is always equal to the total energy of the reactants. This means that in a chemical reaction the energy is preserved and it is conserved. For example, when a wire is burned in a reaction to produce water, the wire undergoes different chemical reactions and when the wire is burned it will turn into rust. The energy of the wire being burned is equal to the energy of the rust that is formed this means that the energy of the wire is being conserved. *2. The Principle of conservation of momentum** The principle of conservation of momentum states that in the absence of outside forces, the momentum of a system remains constant. Momentum is a vector quantity that is a measure of an object’s motion and it is measured in the units of kilograms per second squared (kg/s²). It is a proportional to the force exerted on the object and the time that the force is exerted. When a force is exerted on an object it changes the object’s speed and momentum. The law of conservation of momentum means that the total momentum of system is always equal to the total of the initial momentum of the system. This means that within a system of objects the objects are exchanging momentum without the force of an outside force. The conservation of momentum can be demonstrated by a group of objects colliding with one another and when the group collides these objects will exchange momentum however the total momentum of the system remains the same. 3. The Principle of conservation of mass** The principle of conservation of mass states that in a chemical reaction the total mass of the reactants is always equal to the total mass of the products. This means that the quantity of matter in a chemical reaction is always preserved. This can be demonstrated by the conservation of mass in chemical reactions. For example, when a wire is burned in a reaction to produce water, the wire undergoes different chemical reactions and when the wire is burned it will turn into rust. The mass of the wire that is burned is equal to the mass of the rust that is formed this means that the mass of the wire is being conserved. 4. The principle of conservation of charge** The principle of conservation of charge states that in a chemical reaction the total charge is always equal to the total charge of the reactants. This means that within a chemical reaction the positive and negative charges are always equal to the total charge of the products. This can be demonstrated by the conservation of charge in chemical reactions. For example, when a wire is burned in a reaction to produce water, the wire undergoes different chemical reactions and when the wire is burned it will turn into rust. The charge of the wire being burned is equal to the charge of the rust that is formed this means that the charge of wire is being conserved. 5. The principle of conservation of energy conservation** The principle of conservation of energy conservation states that in a chemical reaction the total energy is always equal to the total energy of the reactants. This means that within a chemical reaction the energy is always preserved. This can be demonstrated by the conservation of energy in chemical reactions. For example, when a wire is burned in a reaction to produce water, the wire undergoes different chemical reactions and when the wire is burned it will turn into rust. The energy of the wire being burned is equal to the energy of the rust that Is formed this means that the energy of the wire is being conserved. 6. The principle of conservation of energy** The principle of conservation of energy states that in a chemical reaction the total energy is always equal to the total energy of the reactants. This means that in a chemical reaction the energy is preserved and it is conserved. For example, when a wire is burned in a reaction to produce water, the wire undergoes different chemical reactions and when the wire is burned it will turn into rust. The energy of the wire being burned is equal to the energy of the rust that is formed this means that the energy of the wire is being conserved. *1. The Principle of conservation of Energy** What Individuals? What Arcs? - The principle of conservation of energy states that energy is never destroyed, but it can be transformed from one form to another. It also states that in a chemical reaction the total energy is always equal to the total energy of the reactants. This means that in a chemical reaction the energy is preserved and it is conserved. For example, when a wire is burned in a reaction to produce water, the wire undergoes different chemical reactions and when the wire is burned it will turn into rust. The energy of the wire being burned is equal to the energy of the rust that is formed this means that the energy of the wire is being conserved. *2. The Principle of conservation of momentum** The principle of conservation of momentum states that in the absence of outside forces, the momentum of a system remains constant. Momentum is a vector quantity that is a measure of an object’s motion and it is measured in the units of kilograms per second squared (kg/s²). It is a proportional to the force exerted on the object and the time that the force is exerted. When a force is exerted on an object it changes the object’s speed and momentum. The law of conservation of momentum means that the total momentum of system is always equal to the total of the initial momentum of the system. This means that within a system of objects the objects are exchanging momentum without the force of an outside force. The conservation of momentum is demonstrated by a group of objects colliding with one another and when the group collides these objects will exchange momentum however the total momentum of the system remains the same. 3. The Principle of conservation of mass** The principle of conservation of mass states that in a chemical reaction the total mass of the reactants is always equal to the total mass of the products. This means that the quantity of matter in a chemical reaction is always preserved. This can be demonstrated by the conservation of mass in chemical reactions. For example, when a wire is burned in a reaction to produce water, the wire undergoes different chemical reactions and when the wire is burned it will turn into rust. The mass of the wire that is burned is equal to the mass of the rust that is formed this means that the mass of the wire is being conserved. 4. The principle of conservation of charge** The principle of conservation of charge states that in a chemical reaction the total charge is always equal to the total charge of the reactants. This means that within a chemical reaction the positive and negative charges are always equal to the total charge of the products. This can be demonstrated by the conservation of charge in chemical reactions. For example, when a wire is burned in a reaction to produce water, the wire undergoes different chemical reactions and when the wire is burned it will turn into rust. The charge of the wire being burned is equal to the charge of the rust that is formed this means that the charge of wire is being conserved. 5. The principle of conservation of energy conservation** The principle of conservation of energy conservation states that in a chemical reaction the total energy is always equal to the total energy of the reactants. This means恰好 to the principles of physics were used by anthropologists to create fire. Them for years many people walked or past the fire and used it for survival. An important part of our survival revolves around fire. Below is a list of steps in which fire was used by anthropologists to create fire. The seven steps were created by anthropologists. humans beings were able to create fire when they used a few tools. Under sun sunlight was used to create fire. The steps were the following: first, the rocks were rubbed to produce spark. The sparks were used to produce fire. Whichever was the first step was known to using rocks rub to see fire. Then, a bundle of sticks was rubbed against the fire to see which was going to be the final step. Then, the animals were used to produce fire. Before birth, the animals were used to create fire. Next, they were used to produce fire. The humans were used to create fire. In the following is a list of the steps in which the ancient humans used to achieve the creation of fire: first was a process of using sticks to get sticks. This was used by anthropologists to create fire. The process was recorded by anthropologists as a process. The first way was to create fire was to produce fire. The second way was to create fire was to produce fire. The third way was to create fire was to produce fire. The fourth way was to create fire was to produce fire. The fifth way was to create fire was to produce fire. The sixth way was to create fire was to produce fire. The seventh way was to create fire was to produce fire. The eighth way was to create fire was to produce fire. The ninth way was to create fire was to produce fire. the tenth way was to create fire was to produce fire. Was the list of the steps in which the ancient humans used to achieve the creation of fire. The first process was a process of creating fire by rubbing sticks or a few sticks in the sunlight. It was recorded by anthropologists as a process. The first thing was using simple mathematics first and that was to find again. Flames were then formed naturally. the first fire ignited was fire. The ninth way was the way to create fire was to produce fire. the four ways were used to create fire. The first factor was the first factor was the first flame was fire. The tenth way was the way to create fire was to produce fire. The second factor was sticks were was made. the animal was used to produce fire. The sixth way was the way to create fire was to produce fire. The third factor was the animals were created again placed off. The process of creation was simple in the first time. the animals were placed off the animal made people to create fire. The fourth factor was the moving animals were used to produce three fires. The nine ways of ways the ancient humans used to achieve the creation of fire were a list of the things to create fire was to make fire.
21 Jan 2021
English Subtitles
中文字幕
日本語字幕
Subtitle Indonesia
Deutsche Untertitel
Sous-titres Français
