Reactants Products • A rise in temperature of the surrounding indicates that the reaction has occurred with a release of heat.This is an exothermic reaction. A+B C + D + heat • A decrease in the temperature of the surrounding indicates that the reaction has occurred with heat consumption (needs heat). This is an endothermic reaction. A+B+heat C+D A+B C+D Matter is neither created nor destroyed during a chemical change only there is transformation How to Balance Chemical Reactions in Equations • This is achieved by changing the coefficients of the compounds .The subscripts are never changed. Changing the subscripts would alter the chemical identity of the compound. • Simple chemical equations can be balanced by inspection, that is, by trial and error. Generally, it is best to balance the most complicated molecule first. Hydrogen and oxygen are usually balanced last. balancing • TiCl4 + H2O TiO2 + HCl Complete Reaction: Some reactions occur in one direction and are characterized by complete consumption of the rxn. C+O2 CO2 • Incomplete rxn: It occurs in both directions and characterized by partial consumption of the reactants. C2H5OH+C2H6O C4HO2 +H2O Factors influencing the rate of a chemical reaction • 1)Temperature: increasing the temp.of the medium increases the rate and vice versa. • 2)Pressure: Liquid and solid compounds are not affected by pressure. Pressure only affect chemical rxns containing gaseous reactants and products. • Catalysts: It is a substance that speed up the chemical rxn without being a part of the rxn. Reactants in Stoichiometric Mixture • A reactant is termed stoichiometric when the quantities (in mol)of the reactant are proportional to their stoichiometric coefficients. aA + bB cC + dD where a,b,c,d are called coefficient According to st.ratio : n(A) /a = n(B)/b = n(C)/c = n(D) /d Stoichiometric mixture in which both reactants are consumed totally Non-Stoichiometric Mixture in which one of the reactants is limiting and the other is in excess. Stoichiometric Ratio: is a relation between number of moles of reactants reacted and number of moles of products formed depending on st . coefficient • • • • aA + bB cC+dD R(A)= n(A)/a R(B)=n(B)/b If R(A)=R(B) then it is a st.mixture if both are not equal we call it non st.mixture. • In this case if R(A) οΎR(B) B is the limiting and A is in excess. • If R(A) οΌR(B) A is the limiting and B is in excess. • Definition : The limiting reactant is the reactant that is completely consumed When the reaction ceased.It determines the quantity of products formed and the quantities reacted of the other reactants. It corresponds to the lowest ratio. Application: Nitrogen gas reacts with Hydrogen gas to produce ammonia gas. 1)Write and balance the equation taking place N2(g) + 3 H2(g) 2 NH3(g) 2)Indicate the stoichiometric coefficients 1 of N2 ,3 of H2 and 2 of NH3 3)Express the Stochiometry of this reaction in mol. 1 molecule of N2 +3molecules of H2 2 molecules of NH3 • Relate the number of moles consumes to the products formed. According to st.ratio : nN2 /1 = nH2/3 =nNH3/2 Suppose this mixture have 4 moles of N2 and 12 moles of H2(g). a)Verify if the mixture is stochiometric or not. R(N2)= n(N2)/1 = 4/1 =4 R(H2) = n(H2)/3 = 12/3=4 R(N2)=R(H2)=4 so mixture is stochiometric. Molar volume: The molar volume of gas is the volume occupied by one mole of this gas. This volume depends on the temperature and pressure of the gas. At T=0 0C and P= 1.013 bar ,Vm=22.4 L.mol-1 • Exercise 1: • Given: molar masses in g.mol-1 : M(Zn)= 65 Vm= 24 L/mol M(S)= 32 M( O)= 16 9.8 g of sulfuric acid (H2SO4 ) is added into a test tube containing exact amount of zinc granules (Zn). Effervescence is observed due to the release of hydrogen gas(H2). The other product in the reaction is zinc sulfate . (ZnSO4). Note:the mixture is initially stoichiometric 1. Write the evidence that a chemical reaction occurred. 2 . Write the chemical equation of the reaction . 3.Show that the mass of zinc sulfate formed is 16.1 g . 4.Determine the volume of hydrogen gas released. 1)Evidence of the reaction : release of the gas 2)Zn + H2 SO4 β‘οΈ ZnSO4 + H2 π π»2ππ4 π ππππ4 3)Using S.T. Ratio: = 1 1 n(ZnSO4)= 0.1 mol π π ππππ4 = , π ππππ4 = 65 + 32 + 16 4 = π π 161 m= n* M= 0.1* 161= 16.1 g πππ 4)M ( H2 SO4 ) = 2 + 32 + 16(4) = 98 g/ mol n( H2 SO4 ) = π π = 9.8 98 = 0.1 πππ Using S.T. Ratio: π π»2ππ4 1 π π»2 = = π ππ π π»2 1 πβππ π π»2 = 0.1 πππ β‘οΈ π π»2 = π ∗ ππ = 0.1 ∗ 24 = 2.4 πΏ • Exercise 2 : • Given: molar masses in g.mol-1 : • M(H)= 1, M( Na)= 23 , M(O)= 16 , M(S)= 32 • sodium hydroxide(NaOH) is added to 0.6 mol of sulfuric acid (H2SO4)leads to the formation of sodium sulfate (Na2SO4)and water(H2O). At end of reaction 0.2 mol of sulfuric acid is left . • 1)Write the chemical equation of the reaction. • 2)Identify without calculation the limiting reactant. • 3)Determine the mass of sodium sulfate and water formed . 4.Deduce the quantity of matter in mol of sodium hydroxide initially added. • • Exercise 2: 1)2 NaOH + H2 SO4 β‘οΈ Na2 SO4 + 2 H2 O 2)0.2 moles of acid left β‘οΈ H2 SO4 is in excess, NaOH is the limiting reactant 3)Using S.t. Ratio: π ππππ» 2 π π»2ππ4 π ππ2ππ4 π π»2π 2 = = = 1 1 n(H2SO4 )r = n initial-nleft=0.6-0.2=0.4mols n( Na2 SO4 ) = 0.4 mol n( H2 O )= 0.8 mol M( Na2 SO4 ) = 23 (2) + 32+ 16(4) = 142 g/mol M( H2 O ) = 2 + 16 = 18 g/mol π π ππ2ππ4 = β‘οΈ π ππ2ππ4 = π ∗ π = 0.4 ∗ 142 = 56.8 π 4) π π»2π = π π π β‘οΈ π π»2π = π ∗ π = 0.8 ∗ 18 = 14. π π ππππ» ππ»2π = = 0.8 ππππ 1 2 • Exercise 3: Given: molar masses in g.mol-1 : M(C)= 12 , M(H)=1 , M( O)= 16 Vm= 24 L/ mol 8.8 g of propane(C3H8) undergoes combustion with 12 L of oxygen gas(O2). 1. Write the chemical equation of the complete combustion of propane. 2. Verify if the above mixture is stoichiometric . If not , identify the limiting reagent 3. Determine the mass of water vapor formed 4. Calculate the volume of CO2 gas released. • • • Exercise 3: • • 2-π πΆ3π»8 = 1-C3 H8 + 5 O2 β‘οΈ 3CO2 + 4 H2 O π π 8.8 44 = π = 0.2 πππ 12 • π π2 = = = 0.5 πππ ππ 24 R( C3H8) > R(O2) The mixture isn’t stoichiometric O2 is the limiting reactant π πΆ3π»8 = 0.2 1 = 0.2 π π2 = 0.5 5 = 0.1 3-Using s.t ratio: π π2 5 = π π»2π 4 π π»2π 1 = π π2 5 = π π 0.5 5 β‘οΈ = π π»2π 4 , π‘βππ β‘οΈ π = π ∗ π = 0.4 ∗ 18 = 7.2 π • Note: M( H2 O ) = 2 + 16 = 18 g/mol • 4-Using st. Ratio: π πΆπ2 3 , 0.5 5 = π πΆπ2 3 So, n( CO2 ) = 0.5 * 3/5 = 0.3 mol π πΆπ2 = π ππ ππ, π = π ∗ ππ = 0.3 ∗ 24 = 7.2 πΏ • An actual yield is the mass of a product actually obtained from the reaction. It is usually less than the theoretical yield. • Theoretical yield eht si quantity tcudorp a fo eht fo noisrevnoc etelpmoc eht morf deniatbo si tI .noticaer lacimehc a ni tnatcaer gntiimil ehtamount a morf gntiluser tcudorp fo ( tcefreptheoreticaloticaer lacimehc )n. Percent purity • We can define percent purity as. mass of pure compound in the impure sample. • %purity= (m(pure)of a reactant/m(total)of a reactant) x 100 Tests for Some gases: • 1) Test for Hydrogen gas If we approach a flame to a tube containing hydrogen gas,it will give a pop sound.
