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CHEM 1203 Chapter three Chapter Three Stoichiometry 1 PDF created with pdfFactory trial version www.pdffactory.com Dr. Ramy Y. Morjan Chapter three CHEM 1203 Dr. Ramy Y. Morjan Atomic Mass (weight) It is important to know the mass of the atoms especially for the lab work. However; atoms are very very small particles and we can not count it or weight it easily that because it contains huge number of atoms. For example the smallest thing we can see by our nicked eyes contains about 1016 atom, it is huge number is not?!!!! It is clear that we can not weight a single atom, but as we said it is important to know the weight of the atom so how we can do that? The answer to this question is that we can determine the mass of one atom relative to another atom experimentally. To do that we need to assign ( )ﻧﺤﺪدa value to the mass of one atom of a given element so we can use it as standard. By international agreement, an atom of the carbon isotope 12C that has six protons and six neutrons has a mass of exactly 12 atomic mass unit (amu). One atomic mass unit is defined as a mass exactly equal to 1/12 the mass of one 12C atom. i.e. mass of one 12C atom = 12 amu 1 amu = mass of one 12C atom /12 The units in which the mass of an atom are expressed are atomic mass units amu. At one time, the lightest atom was assigned a mass of 1 amu and the mass of any other atom was expressed in terms of this standard. Today atomic mass units are defined in terms of the 12C isotope, which is assigned a mass of exactly 12.000 amu. Average Atomic Weight (average atomic weight) The atomic weight of an element is the average weight of the atomic masses of the different isotopes of that element. Naturally occurring carbon, for example, is a mixture of two isotopes, 12 C (98.89%) and 13 C (1.11 %). Individual carbon atoms therefore have a mass of either 12.000 or 13.03354 amu. But the average mass of the different isotopes of carbon is 12.011 amu. Please note that (98.89%) is the natural abundance of 12C and (1.11 %) is the natural abundance of 13C, and in order to be able to make an accurate calculation we need to convert the percentage to fraction as you have seen in the above example. 2 PDF created with pdfFactory trial version www.pdffactory.com CHEM 1203 Chapter three Dr. Ramy Y. Morjan N.P. There are other isotopes for carbon like C14, but these isotopes are not stable and its natural abundance is very little. Molecular Weight The molecular weight of a compound is the sum of the atomic weights of the atoms in the molecules that form these compounds. Example: The molecular weight of the sugar molecule found in cane sugar is the sum of the atomic weights of the 12 carbon atoms, 22 hydrogen atoms, and 11 oxygen atoms in a C12H22O11 molecule. 12 C atoms = 12(12.011) amu = 144.132 amu 22 H atoms = 22(1.0079) amu = 22.174 amu 11 O atoms = 11(15.9994) amu = 175.993 amu 342.299 amu C12H22O11 has a molecular weight of 342.299 amu. A mole of C12H22O11 would have a mass of 342.299 grams. This quantity is known as the molar mass, a term that is often used in place of the terms atomic weight or molecular weight. The Mole The term mole literally means a small mass. It is used as the bridge between chemistry on the atomic and macroscopic scale. If the mass of a single 12 C atom is 12.000 amu, then one mole of these atoms would have a mass of 12.000 grams. By definition, a mole of any substance contains the same number of elementary particles as there are atoms in exactly 12 grams of the 12C isotope of carbon. Example: A single 12C atom has a mass of 12 amu, and a mole of these atoms would have a mass of 12 grams. A mole of any atoms has a mass in grams equal to the atomic weight of the element. The term mole can be applied to any particle: atoms, a mole of atoms, a mole of ions, a mole of electrons, or a mole of molecules. Each time we use the term, we refer to a number of particles equal to the number of atoms in exactly 12 grams of the 12C isotope of carbon. 3 PDF created with pdfFactory trial version www.pdffactory.com CHEM 1203 Chapter three Dr. Ramy Y. Morjan Molecular Mass What is molecular mass? Molecular mass or formula mass or molecular weight of any compound is the summation of the atomic masses of each element in the compound. Example1 What is the molecular mass of NaOH ? Answer As you know from the structure that NaOH consist of three elements which are 23Na and 16O and 1H. From the definition of the molecular mass of any compound we now know that the molecular mass of any compound is the summation of the atomic mass of each element in the compound. That mean Molecular mass of NaOH = (1 x 23) + (1x 16) + (1x 1) = 40 Example 2 What is the molecular mass of ascorbic acid C6H8 O6? Answer: Molecular mass of C6H8O8 = (6 x 12) + (8 x 1) + (6 x 16) = 176 Example 3 What is the molecular mass of Ca3(PO4)2? Molecular mass of Ca3(PO4)2 = (3 x 40) + (2 x 31) + (8 x 16) = 310 Percentage Composition We always need to know what the percentage of each element is in a given compound. This is very important to understand the exact composition of for example drugs, food, and many other things. The Percentage Composition of a compound can be calculated from the relative atomic masses of each element present in that compound. Let us see how we calculate the Percentage Composition of any compound. 1) Calculate the percentage composition of Na2CO3 Answer: 4 PDF created with pdfFactory trial version www.pdffactory.com Chapter three CHEM 1203 Dr. Ramy Y. Morjan There are three steeps to answer this question 1) First of all you must calculate the molecular mass of the compound as you learned in the previous section. Molecular mass of Na2CO3 = (2 x 23) + (1 x 12) + (3 x 16) = 106 2) Now to calculate the Percentage Composition of each element in Na2CO3 you need to calculate the mass of each element in Na2CO3. Mass of Na in Na2CO3 = (2 x 23) = 46 Mass of C in Na2CO3 = (1 x 12) = 12 Mass of O in Na2CO3 = (3 x 16) = 48 3) Now the percentage composition of Na2CO3 can be calculated by applying the Following %Na = Mass of Na in Na2CO3 X 100 Molecular mass of Na2CO3 %Na = 46/106 x 100 = 43% %C = Mass of C in Na2CO3 X 100 Molecular mass of Na2CO3 %C = 12/106 x 100 = 11% %O = Mass of O in Na2CO3 X 100 Molecular mass of Na2CO3 %O = 48/106 x 100 = 45% Please note that the summation of the percentage of Na + C + O SOULD BE equal 100. But some times it is not exactly 100 because of the rounding off when we write the numbers. 5 PDF created with pdfFactory trial version www.pdffactory.com Chapter three CHEM 1203 Dr. Ramy Y. Morjan Exercises 1) What is the percentage composition of C6H8O6 2) What is the percentage composition of Ca3(PO4)2 The Mole (mol) A mole (also known as Avogadro's number) is the number that is used in making calculations involving atoms and molecules. it is difficult to calculate amounts in terms of numbers of atoms. So, we use the mole. A mole, (mol for short) is equal to 6.022 x 1023 atoms or molecules One mol of any thing- molecule, atoms, ions, electrons always contains the same number of partials which is equal to 6.022 x 1023 Avogadro's Number. One mol of any substance has a mass in gram equal to its molecular weight (if it is compound) or atomic mass if it is element. Examples a) 1 mol of water H2O contains 6.022 x 1023 molecules and has a mass of 18g (1x2) + (1x16) = 18 b) 1 mol of carbon C contains 6.022 x 1023 atoms and has a mass of 12g c) 1 mol of glucose C6H12O6 contains 6.022 x 1023 molecules and has a mass of 180g Mol = Mass per gram / Molecular mass per gram Example: What is the mass of 1mol of Ammonia NH3 ? How many molecules are present in one mole of Ammonia NH3? Answer Mol = Mass per gram / Molecular mass per gram 1 = mass per g / (1x14) + (3 x 1) mass per gram = 17g By definition; any mol of any substance contain a constant number of atoms equal to 6.022 x 1023 Avogadro's number. 6 PDF created with pdfFactory trial version www.pdffactory.com Chapter three CHEM 1203 Dr. Ramy Y. Morjan Molecular Formula and Empirical Formula There are two kinds of chemical formulas which are Empirical formulas & Molecular formula. Empirical Formula Empirical formulas give the lowest whole number ratio of the atoms in a compound Molecular Formula The molecular formula gives the exact composition of atoms in a compound. How we can create the empirical and molecular formulas from an experimental data? Empirical formulas can be calculated using experimental data. (see your book to see the expermental method to find the EF and MF) To understand how we can do that let us look at this example. Example 1 A compound contains 69.58% Ba, 6.09% C and 24.32% O, calculate the empirical formula of this compound? Solution First step: Assume that you have 100g of the compound. That mean you have 69.58 g (69.58 %) Ba, and 6.09 g C (6.09 %C), and 24.32g O (24.32% O). Second step: Now convert all of the grams to mol.(i.e. for each element) Mol of Ba = weight of Ba/atomic mass of Ba → mol of Ba = 69.58/137.33 = 0.5067 mol of Ba Mol of C = weight of C/atomic mass of C → mol of C = 6.09/12 = 0.5071 mol of C Mol of O = weight of O/atomic mass of O → mol of O = 24.32/16 = 1.520 mol of O Final step: Now to find the empirical formula you need to divide each of the above numbers by the smaller number i.e. 0.5071 so For Ba = 0.5067/0.5067 = 1 For C = 0.5071/0.5067 ≈ 1 7 PDF created with pdfFactory trial version www.pdffactory.com Chapter three CHEM 1203 Dr. Ramy Y. Morjan For O = 1.520/0.5067 = 2.9998 ≈3 That mean we have one atom of Ba and one atom of C and 3 atoms of O. so the empirical formula is BaCO3 Please ask me if you did not understand the above example. Now how we can create the molecular formula? Well let us see another example. Example 2 A compound of molar mass 56 contains 85.6 % C, and 14.4% H. What is its empirical formula? And what is its molecular formula? Solution 1) Assume that you have 100g of the compound. That means you have 85.6g C (85.6 %) and 14.4 g H (14.4 %H). 2) Convert weight to mol mol C = 85.6/12 = 7.1 mol of C mol H = 14.4/1= 14.4 mol H 3) Divide each of the above numbers by the smallest number which is 7.1 For C = 7.1/7.1 = 1 For H = 14.4/7.1 = 2 Now the empirical formula is CH2 4) Now to know the molecular formula all what you need to do is to calculate the Molecular mass of the compound CH2 in this example, and then to divide it by the given molar mass which is 56 in this example. molecular mass of CH2 = (1 X 12) + (2 X 1) = 14 56/14 = 4 so the empirical formula is 4 x CH2 which is C4H8 The empirical formula is CH2 The molecular formula is C4H8 Home work 1) A compound contains 11.2 % H, 88.8 % O, what is the empirical formula? and if the molecular mass is 18 what is the molecular formula? 2) A compound of molar mass 270 contains 17.0% Na, 47.4 % S, and 35.6% O. what is the empirical and molecular formula of this compound? 8 PDF created with pdfFactory trial version www.pdffactory.com Chapter three CHEM 1203 Dr. Ramy Y. Morjan Chemical Reaction & Chemical Equations Chemical Reaction A chemical reaction is the process by which one or more substances (reactants) are transformed into one or more new substances (products). Energy is released or is absorbed, but no loss in total molecular weight occurs. To be understandable internationally; chemists are representing any chemical reaction by using chemical symbols. The general form of a chemical reaction takes the following form A+B→C+D In which A and be are the reactants. The singe + means react. That means A reacts with B. The sign → means to produce C and D (products). Remember that all substance before the → are reactants (starting materials) and the substances after the → are the products. In all chemical reactions some number may occurs in front of the reactant and the products (if the number is 1 we ignore it as it its understandable without being written), these numbers indicates the number of molecules (mol) that reacted or produced. These numbers are very important to satisfy the law of mass conservation. Other important figures that may appear in a chemical equation are the reaction conditions i.e. the conditions under which the chemical reaction was carried out for example, temperature, catalysts, etc. The reaction conditions are normally written on the → singe. In many cases the physical states (gas, solid liquid) of the reactant and products are indicated in the chemical equation. Normally abbreviations are used (gas = g, solid = s, liquids = l) The chemical equation can be written as the following example. CH4(g) + 2O2 (g) → CO2(g) + 2H2O(g) We read equation 2 as the following. One molecule (or one mol) of methane gas has reacted with 2 moles of oxygen gas to produce 1 mol of carbon dioxide gas and two moles of water gas (steam). Please go back to your text book to see other examples. 9 PDF created with pdfFactory trial version www.pdffactory.com Chapter three CHEM 1203 Dr. Ramy Y. Morjan Balancing Chemical Equations Balancing chemical equations is absolutely essential if you want to determine quantities of reactants or products. An unbalanced Chemical Equation gives only the identify of the beginning reactants and the final products using the appropriate formulas as well as the conditions of temperature, physical state, and pressure conditions under which the reaction is to operate under. However an unbalanced equation can say nothing about the quantities involved until the equation has been balanced. A balanced equation assures that the Conservation Law of matter is obeyed. The total mass of reactants must equal the total mass of products. The following principles should be employed when balancing a Chemical Equation by inspection: 1) Never touch subscripts when balancing equations since that will change the composition and therefore the substance itself. For example (3 CO2 never touch the 2 you only can play with the number 3 to balance the equation) 2) Check to be sure that you have included all sources of a particular element that you are balancing on a particular side since there may be two or more compounds that contain the same element on a given side of an equation. 3) I would suggest that you adjust the coefficient of mono atomic elements near the end of the balancing act since any change in their coefficient will not affect the balance of other elements 4) When there are a group of atoms that are acting as a unit such as a polyatomic ion and they appear intact on both sides of the equation, it is best to balance them as a self contaned group. For example, if there are Phosphate groups, PO4-3, that appear on both sides, balance the phosphates as a group instead of separating the Phosphorus and Oxygens. It can be done either way, but there is less likely of a mistake if they are balanced as Phosphate groups. Example 1: (NH4)2CO3 → NH3 + CO2 + H2O The first thing to do is choose a starting point. If we choose the carbon as the starting point, we go nowhere, since there is already one carbon on each side. Choosing oxygen is not good, because the oxygen is divided between two species on the right side. The interesting part is in the ammonium (NH4) ion. If we start with the nitrogen 10 PDF created with pdfFactory trial version www.pdffactory.com Chapter three CHEM 1203 Dr. Ramy Y. Morjan on the left (in the ammonium ion), we see that there are two nitrogens and therefore we must put at "2" in front of the ammonia on the right side. So the equation at this stage becomes like (NH4)2CO3 → 2 NH3 + CO2 + H2O Since we are already working with the ammonia, now consider the hydrogens that make up the rest of the molecule: the six hydrogens in the ammonia plus the two hydrogens in the water make eight hydrogens. Bouncing back across to the left side, we count eight hydrogens; since no other atomic species have been changed, we can count up everything and see that the reaction is now balanced: 2 N, 8 H, 1 C, and 3 O on each side Notice how the reaction itself led us through the steps of the balancing process. A more complex reaction would have involved more steps, but the process would have been the same. Example 2: Fe2(SO4)3 + K(SCN) → K3Fe(SCN)6 + K2SO4 Look at K3Fe(SCN)6 it is pretty complicated. Now look at it and see what ions are in it that are not shared on the same side of the reaction. These are SCN and Fe. We start to balance these Fe2(SO4)3 + 6 K(SCN) → K3Fe(SCN)6 + K2SO4 Now we go left to right. The irons are messed up, two on the Left, and one on the right. We adjust Fe2(SO4)3 + 6 K(SCN) → 2 K3Fe(SCN)6 + K2SO4 Now this messes up the SCN, we adjust. Fe2(SO4)3 + 12 K(SCN) → 2 K3Fe(SCN)6 + K2SO4 Now we go back to the left and work right. The irons are OK, the sulfates are not. Three on the left, one on the right. We adjust Fe2(SO4)3 + 12 K(SCN) → 2 K3Fe(SCN)6 + 3 K2SO4 Now we go back left to right. Fe is ok, SO4 is OK, K is ok, and so forth, this is the final balanced equation. Exercises Balance the following reaction 1) Cu + O2 → Cu2O 11 PDF created with pdfFactory trial version www.pdffactory.com Chapter three CHEM 1203 Dr. Ramy Y. Morjan 2) CaCl2 + AgNO3 → AgCl + Ca(NO3)2 3) Mg + P4 → Mg3P2 4) H2SO4 + NaOH → H2O + Na2SO4 ***************************************************************************************************** Amounts of reactants and products Please read this section form your text book. It is better to understand this section by solving problem Limiting Reactant In a chemical reaction where some amounts of reactants are mixed and allowed to react, the one that is used up first is the limiting reactant. A portion of the other reactants remains. In other words the limiting reactant is the substances that present in a lees amount with respect to other reactants. There is a systematic procedure for finding the limiting reagent based on the reactant ratio (RR) defined as the ratio of the number of moles of a reactant to its coefficient in a balanced chemical equation. The reagent with the smallest reactant ratio (RR) is the limiting reactant. For a Reaction of the Form: aA + bB → cC + dD If compounds A and B are present in the mole amounts called for in the balanced reaction, then the following equation is valid: RR A = starting moles A , a RRB = starting moles B b or moles of A moles of B = = RR a b v If reactant ratios (RR) of all reactants are equal, then there is no limiting reactant, and all reactants will be consumed. v If all reactant ratios are not equal, then the reactant with the smallest reactant ratio is the limiting reactant. 12 PDF created with pdfFactory trial version www.pdffactory.com Chapter three CHEM 1203 Dr. Ramy Y. Morjan To proceed, first calculate the reactant ratios for all of the reactants: RR A = starting moles A , a RRB = starting moles B , b From among these, choose (RR)min, the smallest reactant ratio. This identifies the limiting reactant. Once (RR)min is identified, it can be used to calculate the actual moles of other reactants and products actually consumed, e.g. Actual moles of B consumed = (RR)min b Actual moles of C produced = (RR)min c Example Consider the following reaction 2Al(s) + 6HCl(g) → 2AlCl3(s) + 3H2(g) If we react 30.0 g Al and 20.0 g HCl, which of the reactant is the limiting reactant? how many moles of aluminum chloride will be formed? Solution Well, from the definition of the limiting reactant we know that the substance which present in a little amount (less number of mols) is the limiting reactant. So let us calculate the mols of each reactant to figure out the limiting reactant. For Al starting mol mol of Al = weight of Al used atomic weight of Al mol of Al = 30 = 1.11 mol 26.98 equivalents Al = 1.11 mol Al 2 This coffecient comes from the balanced chemical equation 0.555 equivalents Al starting mol for HCl mol of HCl = weight of HCl used Molecular weight HCl 13 PDF created with pdfFactory trial version www.pdffactory.com Chapter three CHEM 1203 Dr. Ramy Y. Morjan mol of HCl = 20 = 0.548 mol 36.5 equivalents HCl = 0.548 mol 6 This coffecient comes from the balanced chemical equation 0.0913 equivalents HCl HCl is smaller therefore the Limiting reactant! • Since 6 moles of HCl 0.548 mol HCl 2 moles of AlCl3 ? moles of AlCl3 ? moles of AlCl3 = 0.548 mol HCl x 2 moles of AlCl3 6 moles of HCl moles of AlCl3 = 1.096 = 0.183 mol 6 Theoretical, Actual, and Percent Yields Theoretical yield: The amount of product indicated by the stoichiometrically equivalent molar ratio in the balanced equation. Side Reactions: These form different products that take away from the theoretical yield of the main product. Actual yield: The amount of product that is actually obtained. 14 PDF created with pdfFactory trial version www.pdffactory.com Chapter three CHEM 1203 % Yield = Dr. Ramy Y. Morjan Actual Yield (mass or moles) x 100% Theoretical Yield (mass or moles) Actual yield = Theoretical yield x (% Yield / 100%) or Problem: Given the chemical reaction between Iron and water to form the iron oxide, Fe3O4 and hydrogen gas as in the following equation Fe(s) + H2O(l) → Fe3O4 (s) + H2 (g) If 4.55 g of iron is reacted with sufficient water to react all of the iron to form rust, what is the percent yield if only 6.02 g of the oxide are formed? Solution First balance the equation 3Fe(s) + 4 H2O(l) → Fe3O4 (s) + 4 H2 (g) calculate the number of mol of Fe mol of Fe = 4.55g = 0.081 mol 55.85 1 mol Fe3O4 3 mol Fe ? mol Fe3O4 0.081mol Fe ? mol Fe3O4 = 0.081mol Fe x 1 mol Fe3O4 3 mol Fe mol Fe3O4 = 0.027 mol Convert the mol Fe3O4 to weight mol Fe3O4 = wt 0.027 mol 232 wt Fe3O4 = 6.264g 15 PDF created with pdfFactory trial version www.pdffactory.com Chapter three CHEM 1203 Dr. Ramy Y. Morjan % Fe3O4 = actual yield x 100% theoritical yield 6.02 x 100 6.264 % yield = 96.1% % yield = Problem : Given the following chemical reaction between aluminium sulfide and water, if we are given 65.80 g of Al2S3: a) How many moles of water are required for the reaction? b) What mass of H2S & Al(OH)3 would be formed? Solution A Step 1: The first step is to write the balanced chemical equation as the following Al2S3(s) + 6 H2O(l) → 2 Al(OH)3 (s) + 3 H2S (g) Step 2: Calculate the molar mass (molecular weight or formula weight) for all the reactants and the products formed in the given chemical equation. Al2S3: (2 x 26.98) + (3 x 32.06) = 150.14 g H2O: (2 x 1.01) + (1 x 15.99) = 18.01 g Al(OH)3 : (1 x 26.98) + ( 3 x 15.99) + (3 x 1.01) = 77.98g H2S: (2 x 1.01) + (1 x 32.06) = 25.06g Step 3: To calculate the moles of water are required for the reaction, we know form the given balanced equation that;1 mol of Al2S3 reacts with 6 mol of H2O, but we do not have just one mole of Al2S3 , we have (65.08 g), so we need to calculate how many mole are they equal? Mol AL2S3 = w/Mw → 65.08g/ 150.14g = 0.433 [150.14 from step 1 and 65.08g from the dated given in the problem] Now 16 PDF created with pdfFactory trial version www.pdffactory.com Chapter three CHEM 1203 1 mol Al2S3 Dr. Ramy Y. Morjan 6 mol H2O 0.433 mol Al2S3 ? mol H2O Then ? mol H2O = 0.433 mol Al2S3 x 6 mol H2O 1 mol Al2S3 ? mol H2O = 2.598 mol That means: 2.598 mol of H2O (46.79g) needed to reacts with 0.433mol of Al2S3 (65.08) in the given reaction. Solution B To calculate the mass of Al(OH)3 & H2S produced from the reaction of 65.08 g of Al2S3 with 46.79g H2O, we know from the balanced chemical equation that 1 mol of Al2S3 produce 2 mol of Al2(OH)3, so how many mol of Al2(OH)3 will be produced when 0.433 mol Al2S3 reacts with 2.598 mol of H2O? then 1 mol Al2S3 2 Al2(OH)3 ? mol Al2(OH)3 0.433 mol Al2S3 ? mol Al2(OH)3 = 0.433 mol Al2S3 x 2 Al2(OH)3 1 mol Al2S3 ? mol Al2(OH)3= 0.866 mol Convert the mols of Al2(OH)3 into weight 0.866 Al2(OH)3 = wAl2(OH)3 77.98Al2(OH)3 wAl2(OH)3 = 0.866 x 77.98 = 67.53g 17 PDF created with pdfFactory trial version www.pdffactory.com Chapter three CHEM 1203 Dr. Ramy Y. Morjan The mass of H2S 1 mol Al2S3 3 mol of H2S 0.433 mol Al2S3 ? mol H2S Then ? mol H2S = 0.433 mol Al2S3 x 3 mol of H2S 1 mol Al2S3 ? mol H2S = 1.33 mol Convert the mols of H2S into weight 1.33 H2S = wH2S 25.06H2S wH2S = 1.33 x 25.06 = 33.33g Please do not hesitate to ask if you have not understood any step in the above example 18 PDF created with pdfFactory trial version www.pdffactory.com