If a business uses excess amounts of chemical X and Chemical Y to create chemical X2Y, it would be costly and wasteful. Using exactly 2 moles of X and one mole of Y will make the process much more efficient. And how does one figure all this out? Stoichiometry!
Stoichiometry is the calculation of the various products and reactants in chemical reactions. The two types are reaction stoichiometry and composition stoichiometry.
When a problem has a label "stoichiometry" on top of it.
An example of stoichiometry is any chemical reaction. HCl+NaOH->NaCl+H2O may be an example of stoichiometry.
Stoichiometry is not a method of measurement, it is a concept for the ratios of reactants and products.
The heart of stoichiometry is the mole ratio given by the coefficients of the balanced equation
Stoichiometry is important to chemistry because it is how you find important things in chemistry like particles, grams, moles and liters.
Stoichiometry is the calculation of the various products and reactants in chemical reactions. The two types are reaction stoichiometry and composition stoichiometry.
When a problem has a label "stoichiometry" on top of it.
An example of stoichiometry is any chemical reaction. HCl+NaOH->NaCl+H2O may be an example of stoichiometry.
Stoichiometry is not a method of measurement, it is a concept for the ratios of reactants and products.
The heart of stoichiometry is the mole ratio given by the coefficients of the balanced equation
stoichiometry is very important in chemical equations because it tells you the relationship between substances in the same chemical equation. If you know the properties and relationship of one substance in the equation, you can calculate the relationships between all the substances in the equation.
You think to chemical compostion or to stoichiometry.
Chemists do.
stoichiometry
No
Stoichiometry