What happens with the energy released from the water molecule?

The process of dissolving is exothermic when more energy is released when water molecules “bond” to the solute than is used to pull the solute apart. Because more energy is released than is used, the molecules of the solution move faster, making the temperature increase.

Why does producing water by the reaction of hydrogen and oxygen release energy?

Hydrogen molecules violently react with oxygen when the existing molecular bonds break and new bonds are formed between oxygen and hydrogen atoms. As the products of the reaction are at a lower energy level than the reactants, the result is an explosive release of energy and the production of water.

What happens to the energy release of an exothermic reaction?

Chemical reactions that release energy are called exothermic. In exothermic reactions, more energy is released when the bonds are formed in the products than is used to break the bonds in the reactants. Exothermic reactions are accompanied by an increase in temperature of the reaction mixture.

When water changes to hydrogen and oxygen what is needed?

Hydrogen and oxygen both exist as diatomic gases. A reaction between them requires energy to break the bonds between the atoms so they can form a new product. Once the bonds break, each hydrogen atom has a +1 positive charge, while each oxygen atom has a -2 negative charge.

Why do combustion reactions release energy?

Overall, combustion is an exothermic reaction given off or exiting , which means that energy is released. Usually, heat and light are released during a combustion reaction. During exothermic reactions (like combustion), bonds are broken, which allows the energy trapped in the bonds to be released and do work.

Why do reactions release energy?

All chemical reactions involve energy. Energy is used to break bonds in reactants, and energy is released when new bonds form in products. In other chemical reactions, it takes more energy to break bonds in reactants than is released when bonds form in products.