If a reaction requires a constant input of energy, the products are higher in energy than the reactants. This type of reaction is known as endothermic, since it involves an increase in energy of the system. Conversely, reactions that release energy are known as exothermic.
An endothermic reaction requires a continuous input of energy to continue. This energy is needed to break bonds in the reactants and drive the reaction forward by absorbing heat from the surroundings. Without this constant energy supply, the reaction will slow down or stop.
Light is essential for photosynthesis, the process by which plants and some other organisms convert light energy into chemical energy to make food. Without a constant supply of light, photosynthesis cannot occur and the organism will not be able to produce the energy it needs to survive.
Chemical bonds are broken to supply us with energy. Without bonds, and our ability to break them, the food we eat would not supply us with energy.
Yes, ATP can supply energy to enzymes in a cell to facilitate chemical reactions. When ATP is hydrolyzed to ADP and inorganic phosphate (Pi), it releases energy that can be harnessed by enzymes to overcome activation energy barriers. This energy transfer is crucial for driving various biochemical reactions necessary for cellular functions.
A non-spontaneous reaction occurs in an electrolytic cell where an external voltage is applied to drive a chemical reaction that would not occur naturally. In this setup, electrical energy is converted into chemical energy, facilitating processes like electrolysis. For example, the decomposition of water into hydrogen and oxygen gases requires an electrolytic cell to supply the necessary energy to overcome the activation barrier. Overall, electrolytic cells are crucial in various applications, including metal plating and the production of chemical compounds.
For most chemical reactions, energy is required to supply an "activation energy" required before reaction.
An endothermic reaction requires a continuous input of energy to continue. This energy is needed to break bonds in the reactants and drive the reaction forward by absorbing heat from the surroundings. Without this constant energy supply, the reaction will slow down or stop.
An organism needs energy and constant supply of materials to grow and develop.
Almost certainly the ones on the left side of the arrow (or on the bottom of the equilibrium constant expression). However, since you neglected to supply "this chemical reaction", we can't give you a better answer than that.
It's hard to know precisely what is meant by this question. You may be thinking of activation energy, the minimum energy needed to start the reaction, which explains why one reaction may go at a different speed from another. On the other hand, if you are thinking of just one reaction going faster and slower depending on the energy supply, then that's most often thermal energy.
First of all the fire that you see is just the light emitted by a chemical reaction called oxidation. This reaction consumes energy, in the form of oxygen and a flammable material such as wood. If either one runs out the fire dies. So in short, fire requires a constant supply of energy and that runs out so fire 'burns up'.
Light is essential for photosynthesis, the process by which plants and some other organisms convert light energy into chemical energy to make food. Without a constant supply of light, photosynthesis cannot occur and the organism will not be able to produce the energy it needs to survive.
chemical energy
An organism needs energy and constant supply of materials to grow and develop.
Chemical bonds are broken to supply us with energy. Without bonds, and our ability to break them, the food we eat would not supply us with energy.
No they do not supply energy to start a chemical reaction, however energy has something to do with it. Enzymes actually lower energy barriers, in other words it reduces the activation energy needed which is the energy absorbed before the chemical reaction can start.
Yes, ATP can supply energy to enzymes in a cell to facilitate chemical reactions. When ATP is hydrolyzed to ADP and inorganic phosphate (Pi), it releases energy that can be harnessed by enzymes to overcome activation energy barriers. This energy transfer is crucial for driving various biochemical reactions necessary for cellular functions.