STOICHIOMETRY

A. UNDERSTANDING STOICHIOMETRY

          Stoichiometry comes from two Greek syllables Stoicheion meaning "element" and Metron which means "measurement". Stoichiometry is a subject in chemistry involving the linkage of reactants and products in a chemical reaction to determine the quantity of each reacting agent.

B. DEFINITION CONCEPT MOL

            

One mole of each element: carbon (black powder of charcoal), Sulfur (yellow powder), iron (nails), copper wire, and mercury (metal in liquid form)

   To simplify the number of these extraordinarily small particles, the concept of moles is used. Mol represents the unit of quantity of matter. Unit amount of this substance as well as the simplification of the amount of a good. For example, 1 dozen is used to simplify 12 pieces of glassware and 1 ream to declare 500 sheets of paper. This simplification needs to be done because the chemical processes that take place in everyday life involve a very small collection of very small particles. The units of the particles are too difficult to observe.

1 mol = L particles

L = Avogadro Number = 6.02 x 1023

 Thus, the concept of moles is the unit of quantity of matter that expresses the number of particles of matter.

FORM CONCEPT MOL

Thus, 1 mol of the substance contains 6.02 x 1023 particles. The relationship between the number of moles and the number of particles can be formulated as follows:

Number of moles of X (n) = number of particles X / L

 Or

Number of particles X = n x L

 The Avogadro (L) number was discovered by Johann Loschmidt in 1865. The name Avogadro was chosen as a tribute to Avogadro because he was the first to propose the need for a unit of particle count. The name Loschmidt is immortalized as a symbol of that number, L. The value of the Avogadro number is L = 6.02 x 1023. Can you imagine the magnitude of that number? Had it collected 6.02 x 1023 rice grains, the rice could be dumped on the surface of the Australian continent with a height of one kilometer! Or, if an atom is the size of a marble and spread on the surface of the earth, the entire surface of the earth will be covered with marbles with a layer thickness of 80 km! This enormous number is chosen to express the number of atoms because of their practicality and precision. Imagine, it would be complicated if the number of atoms expressed in units of grains, dozen, gross, kodi, or other units.

1. MASS MOLAR

                    The molar mass is the mass of a substance equal to the atomic mass or the mass of the formula of the substance expressed in grams. This molar mass is equal to the mass possessed by a mole of substance equal to the relative atomic mass (Ar) or relative molecular mass (M).

2. Volume of gas molar

        The molar volume of the gas (Vm) is the volume occupied by 1 mole of gas at a temperature (T) and a certain pressure (P). Because the laws of gas do not depend on the  identity of the gas. In other words, any gas, at a certain temperature and pressure will be the same volume. This implies that, one mole per gas contains the same number of molecules as the avogadro constant (L = 6.02 x 1023 molecules). According to Avogadro's law, the gases must fill the same volume at a certain temperature and pressure. The volume of one mole of this gas is known as the molar volume of the gas. At standard pressure (0 oC and 1 atm), the volume of one mole of gas was found to be 22.4 Liters. (Remember yes only at 0 oC and 1 atm, if not in these conditions then the volume of the molars will not be 22.4 L).
If there is one mole of ideal gas at 0 ° C and 1 atm pressure, then from the ideal gas law, the gas volume in that state is

 This 22.4 liter volume is called the ideal gas molar volume.

3. Molarity

             In chemistry, molarity (M) is a measure of the concentration of the solution. The molarity of a solution expresses the number of moles of a substance per liter of solution. For example 1.0 liter of solution contains 0.5 mol of X compound, then this solution is called 0.5 molar solution (0.5 M). Generally the concentration of aqueous aqueous solution is expressed in molar units. The advantage of using molar units is the ease of calculation in stoichiometry, since concentrations are expressed in number of moles (proportional to the number of actual particles).

 

4. substance levels

            Substance levels are generally expressed in percent mass (% mass). To get a percent mass can use the formula:

5. Determining the Empirical Formula and the Compound Molecular Formula

            In chemistry lessons are known 2 types of chemical formulas, namely Empirical Formulas and Molecular Formulas. The empirical formula is the formula which expresses the smallest comparison of atoms from the constituent elements of the compound. While the molecular formula is a formula that shows the number of atomic elements that make up a compound. This molecular formula is a multiple of the empirical formula.

(Empirical Formula) _ {n} = Molecular Formulas

The value of n above corresponds to the relative molecular mass (Mr) of the two chemical formulas. If Mr. of the empirical formula is multiplied by n, then yields Mr. molecular formula. This principle is used as the basis for finding the molecular formula of the compound.

 How to Determine Empirical Formulas and Molecular Formulas :

1. Find the mass comparisons of the constituent elements.

2. Find the mole ratio by dividing the elemental mass by its relative atomic mass (Ar).

3. From the comparison of the simplest mole obtained Empirical Formula.

4. Determine the Molecular Formula by looking for the multiplier n factor. The formula used       is (Mr. RE) n = Mr.

C. CHEMICAL CALCULATIONS

        Stoichiometry is closely related to chemical calculations. To solve the problem of chemical calculation, the stoichiometric principles are used, they are chemical equation and mole concept. In this lesson we will learn first about the principles of stoichiometry, then after that we will study stoichiometry application on chemical calculation and sample problem and how to solve it.

1. Example of the Law of Conservation of Mass in Chemical Reactions:     Copper wire is burned in a bunsen burner to form copper oxide (CuO).

2Cu (s) + O2 (g) → 2CuO (s)

 If the weight of Cu is initially 32 g and CuO is formed 40 g, how much weight of O2 reacts? Resolution:

 According to the Law of Conservation of Mass, in chemical reactions there is no mass change. Therefore, the weight of O2 reacting is 40 g - 32 g = 8 g 32 g

Cu (s) + 8 g O2 (g) → 40 g CuO (s)