Heat energy manifests itself as the random jostling motions of molecules in matter; as the temperature of a substance increases, its molecules vibrate and bounce with more energy and at faster speeds. At certain temperatures, vibrations overcome the forces that make molecules stick to one another, causing solids to melt into liquids, and liquids to boil into gases. Gases respond to heat with an increase in pressure as molecules collide against their container with greater force.
Arrhenius Equation
A mathematical formula called the Arrhenius equation links the speed of a chemical reaction to its temperature. At absolute zero, a theoretical temperature that cannot be reached in a real-life lab setting, heat is completely absent and chemical reactions are nonexistent. As temperature increases, reactions take place. Generally, higher temperatures mean faster reaction rates; as molecules move about more quickly, reactant molecules are more likely to interact, forming products.
Le Chatelier’s Principle and Heat
Some chemical reactions are reversible: Reactants combine to form products, and products rearrange themselves into reactants. One direction releases heat and the other consumes it. When a reaction can happen either way with equal likelihood, chemists say it is in equilibrium. Le Chatelier’s principle states that for reactions in equilibrium, adding more reactants to the mix makes the forward reaction more likely and the reverse less so. Conversely, adding more products makes the reverse reaction more probable. For an exothermic reaction, heat is a product; if you add heat to an exothermic reaction in equilibrium, you make the reverse reaction more likely.