UTSAV 2023 SGS Chemistry Past Paper PDF

Summary

The document includes topics in chemistry, such as atoms, molecules, and stoichiometry. It presents definitions of key terms and examples of calculations, for example, how to calculate moles and number of atoms in a substance.

Full Transcript

1 Atoms, molecules and stoichiometry try DEFINITION: Relative atomic mass (Ar) is the average mass of one atom compared to one twelfth of the mass of one atom of carbon-12 DEFINITION: Relative Isotopic mass is the mass of one isotope compared to one twelfth of the mass of one atom of carbo...

1 Atoms, molecules and stoichiometry try DEFINITION: Relative atomic mass (Ar) is the average mass of one atom compared to one twelfth of the mass of one atom of carbon-12 DEFINITION: Relative Isotopic mass is the mass of one isotope compared to one twelfth of the mass of one atom of carbon-12 The term molecule should only be DEFINITION: Relative molecular mass (Mr) is the weighted average mass of a used for covalent molecules. For molecule compared to one twelfth of the mass of one atom of carbon-12 ionic substances use the term relative formula mass. They are, DEFINITION: Relative formula mass (Mr) is the weighted average masses of the however, calculated in the same formula units compared to one twelfth of the mass of one atom of carbon-12 way. The mole Avogadro's Number The mole is the key concept for chemical calculations There are 6.022 x 1023 atoms in 12 grams of carbon-12. Therefore DEFINITION: The mole is the amount of substance in grams that has the same explained in simpler terms 'One number of particles as there are atoms in 12 grams of carbon-12. mole of any specified entity contains 6.022 x 1023 of that entity': For pure solids, liquids and gases Relative Formula mass (Mr) for a compound can be calculated by adding moles = mass up the relative atomic masses(from the periodic table) of each element in the compound Mr eg CaCO3 = 40.1 + 12.0 +16.0 x3 = 100.1 Unit of Mass: grams Unit of moles : mol Many questions will involve changes of units 1000 mg =1g Example 1: What is the number of moles in 35.0g of 1000 g =1kg CuSO4? 1000kg = 1 tonne moles = mass/Mr Example 2: What is the number of moles in 75.0mg of CaSO4.2H2O? = 35.0/ (63.5 + 32.0 +16.0 x4) moles = mass/Mr = 0.219 mol = 0.075/ (40 + 32.0 +16.0 x4 + 18.0x2) = 4.36x10-4 mol 1 mole of copper atoms will contain 6.022 x 1023 atoms Avogadro's Constant can be used 1 mole of carbon dioxide molecules will contain 6.022 x 1023 molecules for atoms, molecules and ions 1 mole of sodium ions will contain 6.022 x 1023 ions No of particles = moles of substance (in mol) X Avogadro's constant (L) Example 3 : How many atoms of Tin are there Example 4 : How many chloride ions are there in a 25.0 cm3 of a in a 6.00 g sample of Tin metal? solution of magnesium chloride of concentration 0.400 moldm-3 ? moles = mass/Ar moles= concentration x Volume = 6.00/ 118.7 MgCl2= 0.400 x 0.0250 = 0.05055 mol = 0.0100 mol There are two moles of chloride ions for every one Number atoms = moles x 6.022 x 1023 moles of chloride ions = 0.0100 x2 mole of MgCl 2 = 0.0200 = 0.05055 x 6.022 x 1023 Number ions of Cl- = moles x 6.022 x 1023 = 3.04 x1022 = 0.0200 x 6.022 x 1023 = 1.20 x1022 (to 3 sig fig) 1 N Goalby chemrevise.org Determination of Relative Atomic Mass The relative atomic mass quoted on the periodic table is a weighted average of all the isotopes Fig: spectra for 100 Magnesium from mass 80 78.70% spectrometer % abundance 60 24Mg+ If asked to give the species for a peak 40 in a mass spectrum then give charge 25Mg+ 26Mg+ and mass number e.g. 24Mg+ 20 10.13% 11.17% m/z 24 25 26 R.A.M =  (isotopic mass x % abundance) Use these equations to work out the R.A.M 100 For above example of Mg R.A.M = [(78.7 x 24) + (10.13 x 25) + (11.17 x 26)] /100 = 24.3 R.A.M =  (isotopic mass x relative abundance) If relative abundance is used instead of total relative abundance percentage abundance use this equation Example 5: Calculate the relative atomic mass of Tellurium from the following abundance data: 124-Te relative abundance 2; 126-Te relative abundance 4; 128-Te relative abundance 7; 130-Te relative abundance 6 R.A.M = [(124x2) + (126x4) + (128x7) + (130x6)] 19 = 127.8 Example 6: Copper has two isotopes 63-Cu and 65-Cu. The relative atomic mass of copper is 63.5. Calculate the percentage abundances of these two isotopes. 63.55 = yx63 + (1-y)x65 63.55 = 63y +65 -65y 63.55 = 65 -2y 2y = 1.45 y = 0.725 %abundance 63-Cu =72.5% %abundance 65-Cu = 27.5% N Goalby chemrevise.org 2 Empirical formulae Definition: An empirical formula is the simplest ratio of atoms of each element in the compound. General method The same method can be Step 1 : Divide each mass (or % mass) by the atomic mass of the element used for the following types Step 2 : For each of the answers from step 1 divide by the smallest one of those of data: numbers. 1. masses of each element in Step 3: sometimes the numbers calculated in step 2 will need to be multiplied up to the compound give whole numbers. 2. percentage mass of each These whole numbers will be the empirical formula. element in the compound Example 7 : Calculate the empirical formula for a compound that contains 1.82g of K, 5.93g of I and 2.24g of O Step1: Divide each mass by the atomic mass of the element to give moles K = 1.82 / 39.1 I = 5.93/126.9 O = 2.24/16 = 0.0465 mol = 0.0467mol = 0.14mol Step 2 For each of the answers from step 1 divide by the smallest one of those numbers. K = 0.0465/0.0465 I = 0.0467/0.0465 O = 0.14 / 0.0465 =1 =1 =3 Empirical formula =KIO3 Molecular formula from empirical formula Definition: A molecular formula is the actual number of atoms of each element in the compound. From the relative molecular mass (Mr) work out how many times the mass of the empirical formula fits into the Mr. Remember the Mr of a substance can be found out from using a mass spectrometer. The molecular ion Example 8 : work out the molecular formula for the ( the peak with highest m/z) will be equal to the Mr. compound with an empirical formula of C3H6O and a Mr of 116 C3H6O has a mass of 58 Spectra for C4H10 The empirical formula fits twice into Mr of 116 43 So molecular formula is C6H12O2 The Mr does not need to be exact to turn an empirical formula 29 Molecular ion into the molecular formula because the molecular formula will 58 be a whole number multiple of the empirical formula 10 20 30 40 50 60 70 80 90 100 110 m/z N Goalby chemrevise.org 3 Combustion Analysis for Calculating Empirical Formula Example 9 0.328 g of a compound containing C,H and O was burnt completely in excess oxygen, producing 0.880 g of carbon dioxide and 0.216 g of water. Use these data to calculate the empirical formula of the compound. Work out moles of CO2 = Mass of CO2/Mr of CO2 = 0.88/44 =0.02mol Moles of C in compound = moles of CO2 Mass of C in = mol of C x 12 = 0.02 mol compound =0.02 x12 =0.24g Work out moles of H2O = Mass of H2O /Mr of H2O = 0.216/18 =0.012mol Moles of H in compound = 2 x moles of H2O Mass of H in = mol of H x 1 = 0.024 mol compound =0.024 x1 =0.024g Work out mass of O = mass of compound – mass of C – mass of H in compound = 0.328 – 0.24 -0.024 =0.064 Work out moles of O = Mass of O /Ar of O in compound = 0.064/16 = mol 0.004 Work out molar ratio of 3 elements (divide C = 0.02/0.004 H = 0.024/0.004 O = 0.004/0.004 by smallest moles) =5 =6 =1 empirical formula = C5H6O Molar Gas Volume Example 10 : Calculate the volume in dm3 at room temperature and pressure of 50.0g of Carbon dioxide gas ? 1 mole of any gas at room pressure amount = mass/Mr (1atm) and room temperature 25oC = 50/ (12 + 16 x2) will have the volume of 24dm3 = 1.136 mol Gas Volume (dm3)= amount x 24 = 1.136 x 24 = or 27.3 dm3 to 3 sig fig N Goalby chemrevise.org 4 For most calculations at A-level use the following 3 equations to calculate amount in moles Learn these equations carefully and what units to use in them. 1. For pure solids, liquids and gases 2. For gases 3. For solutions moles = mass Gas Volume (dm3)= amount x 24 Concentration = moles Mr This equation gives the volume of a volume gas at room pressure (1atm) and Unit of Mass: grams room temperature 25oC. Unit of concentration: mol dm-3 or M Unit of moles : mol Unit of Volume: dm3 Note the PV = nRT different Remember the Mr must be Unit of Pressure (P):Pa units for Converting volumes calculated and quoted to Unit of Volume (V): m3 volume 1dp Unit of Temp (T): K cm3  dm3 ÷ 1000 n= moles cm3  m3 ÷ 1000 000 R = 8.31 dm3  m3 ÷ 1000 Converting temperature oC  K add 273 Significant Figures Give your answers to the same number of significant figures as the number of significant figures for the data you given in a question. If you are given a mixture of different significant figures, use the smallest Density, ρ Density calculations are usually used with pure liquids but to work out the mass from a measured volume. It can also be used with solids and gases. density = mass Density is usually given in g cm-3 but can be kg m–3, g dm-3 Care needs to be taken if different units are used. Volume Example 11 : How many molecules of ethanol are there in a Example 12 : There are 980mol of pure gold in a 0.500 dm3 of ethanol (CH3CH2OH) liquid ? The density of bar measuring 10 cm by 20 cm by 50 cm. What is ethanol is 0.789 g cm-3 the density of gold in kg dm−3 Mass = moles x Mr Mass = density x Volume ethanol = 980 x 197 = 0.789 x 500 = 193060 g = 394.5g = 193.06kg moles = mass/Mr Volume = 10x20x50 = 394.5/ 46.0 = 10 000cm3 = 8.576 mol = 10dm3 Number of molecules= moles x 6.022 x 1023 density = mass/volume = 8.576 x 6.022 x 1023 = 193/10 = 19.3 kg dm-3 = 5.16 x1024(to 3 sig fig) N Goalby chemrevise.org 5 Hydrated salt A Hydrated salt contains water of crystallisation Example 13 Na2SO4. xH2O has a molar mass of 322.1, Calculate. Cu(NO3)2 6H2O the value of x hydrated copper (II) nitrate(V). Molar mass xH2O = 322.1 – (23x2 + 32.1 + 16x4) = 180 Cu(NO3)2 X = 180/18 Anhydrous copper (II) nitrate(V). =10 This method could be used for measuring mass loss in various Heating in a crucible thermal decomposition reactions and also for mass gain when reacting magnesium in oxygen. The water of crystallisation in calcium sulphate crystals can be The lid improves the accuracy of the removed as water vapour by heating as shown in the following experiment as it prevents loss of solid equation. from the crucible but should be loose CaSO4.xH2O(s) → CaSO4(s) + xH2O(g) fitting to allow gas to escape. Method. Weigh an empty clean dry crucible and lid. Add 2g of hydrated calcium sulphate to the crucible and weigh again Heat strongly with a Bunsen for a couple of minutes Allow to cool Weigh the crucible and contents again Heat crucible again and reweigh until you reach a constant mass ( do this to ensure reaction is complete). Large amounts of hydrated calcium sulphate, such as 50g, should not be used in this experiment as the decomposition is likely to be incomplete. Small amounts of the solid , such as 0.100 g, should not be used in this The crucible needs to be dry otherwise a wet crucible would experiment as the percentage give an inaccurate result. It would cause mass loss to be too uncertainties in weighing will be too large as the water would be lost when heating. high. Example 14. 3.51 g of hydrated zinc sulphate were heated and 1.97 g of anhydrous zinc sulphate were obtained. Use these data to calculate the value of the integer x in ZnSO4.xH2O Calculate the mass of H2O = 3.51 – 1.97 = 1.54g Calculate moles = 1.97 Calculate = 1.54 of ZnSO4 161.5 moles of H2O 18 = 0.0122 = 0.085 Calculate ratio of mole of 0.0122 = 0.085 ZnSO4 to H2O = 0.0122 0.0122 =7 =1 X=7 N Goalby chemrevise.org 6 Concentration of Solutions A solution is a mixture formed when a solute dissolves in a solvent. In chemistry we most commonly use water as the solvent to form aqueous solutions. The solute can be a solid, liquid or a gas. Molar concentration can be measured for solutions. This is calculated by dividing the amount in moles of the solute by the volume of the solution. The volume is measure is dm 3. The unit of molar concentration is mol dm-3 ; it can also be called molar using symbol M Concentration = moles Unit of concentration: mol dm-3 or M volume Unit of Volume: dm3 Converting volumes A m3 is equivalent to a cube A dm3 is equivalent to a cube A cm3 is equivalent to a cube 100cmx100cmx100cm= 1000000cm3 10cmx10cmx10cm= 1000cm3 1cmx1cmx1cm 1dm3 = 1litre 1cm3 = 1 ml 100cm 10cm 10cm 1cm 1cm 10cm 1cm 100cm 100cm 1cm3 1dm3 or 1 litre 1m3 1 m3 = 1000 dm3 or 1000L 1 dm3 = 1000 cm3 or 1000mL To convert m3 into dm3 multiply by 1000 To convert cm3 into dm3 divide by 1000 cm3  dm3 ÷ 1000 cm3  m3 ÷ 1000 000 dm3  m3 ÷ 1000 Example 15 What is the concentration of solution Example 16 What is the concentration of solution made by dissolving 5.00g of Na2CO3 in 250 cm3 water? made by dissolving 10kg of Na2CO3 in 0.50 m3 water? moles = mass/Mr moles = mass/Mr = 5 / (23.0 x2 + 12 +16 x3) = 10 000 / (23.0 x2 + 12 +16 x3) = 0.0472 mol = 94.2 mol conc= moles/Volume conc= moles/Volume = 0.0472 / 0.25 = 94.2 / 500 = 0.189 mol dm-3 = 0.19 mol dm-3 N Goalby chemrevise.org 7 Mass Concentration The concentration of a solution can also be measured To turn concentration measured in mol dm-3 into in terms of mass of solute per volume of solution concentration measured in g dm-3 multiply by Mr of the substance Mass Concentration = mass conc in g dm-3 = conc in mol dm-3 x Mr volume The concentration in g dm-3 is the same as the mass of solute dissolved in 1dm3 Unit of mass concentration: g dm-3 Unit of Mass g Unit of Volume: dm3 Ions dissociating When soluble ionic solids dissolve in water they will dissociate into separate ions. This can lead to the concentration of ions differing from the concentration of the solute. Example 17 If 5.86g (0.1 mol) of sodium chloride (NaCl) is dissolved in 1 dm3 of water then the concentration of sodium chloride solution would be 0.1moldm-3. NaCl(s) +aq  Na+(aq) + Cl- (aq) However the 0.1mol sodium chloride would split up to form 0.1 mol of sodium ions and 0.1 mol of chloride ions. The concentration 0.1mol 0.1mol 0.1mol of sodium ions is therefore 0.1 mol dm-3 and the concentration of chloride ions is also 0.1 mol dm-3 Example 18 If 9.53g (0.1 mol) of magnesium chloride (MgCl2) is dissolved in 1 dm3 of water then the concentration of magnesium chloride solution (MgCl2 aq) would be 0.1moldm-3. MgCl2(s) +aq  Mg2+(aq) + 2Cl- (aq) However the 0.1mol magnesium chloride would split up to form 0.1 0.1mol 0.1mol 0.2mol mol of magnesium ions and 0.2 mol of chloride ions. The concentration of magnesium ions is therefore 0.1 mol dm-3 and the concentration of chloride ions is now 0.2 mol dm-3 Making a solution Weigh the sample bottle containing the required mass of solid Alternatively the known mass of solid on a 2 dp balance in the weighing bottle could be Transfer to beaker and reweigh sample bottle transferred to beaker, washed and Record the difference in mass washings added to the beaker. Add 100cm3 of distilled water to the beaker. Use a glass rod to stir to help dissolve the solid. Sometimes the substance may not dissolve well in cold water so the beaker and its contents could be heated gently until all the solid had dissolved. Pour solution into a 250cm3 graduated flask via a funnel. Remember to fill so the bottom of the Rinse beaker and funnel and add washings from the beaker meniscus sits on the line on the neck of the and glass rod to the volumetric flask. flask. With dark liquids like potassium make up to the mark with distilled water using a dropping manganate it can be difficult to see the pipette for last few drops. meniscus. Invert flask several times to ensure uniform solution. N Goalby chemrevise.org 8 Dilutions Diluting a solution Using a volumetric pipette is more accurate than a measuring cylinder because it has a Pipette 25cm3 of original solution into a 250cm3 volumetric smaller uncertainty flask make up to the mark with distilled water using a dropping Use a teat pipette to make up to the mark in pipette for last few drops. volumetric flask to ensure volume of solution Invert flask several times to ensure uniform solution. accurately measured and one doesn’t go over the line Calculating Dilutions Diluting a solution will not change the amount of moles of solute present but increase the volume of solution and hence the concentration will lower moles= volume x concentration If amount of moles does not change then Original volume x original concentration = new diluted volume x new diluted concentration so new diluted concentration = original concentration x Original volume new diluted volume The new diluted volume will be equal to the original volume of solution added + the volume of water added. Example 19 If 50 cm3 of water are added to 150 cm3 of a 0.20 mol dm-3 NaOH solution, what will the concentration of the diluted solution be? new diluted concentration = original concentration x Original volume new diluted volume new diluted concentration = 0.20 x 0.150 0.200 = 0.15 mol dm-3 Example 20 Calculate the volume of water in cm3 must be added to dilute 5.00 cm3 of 1.00 mol dm−3 hydrochloric acid so that it has a concentration of 0.050 mol dm−3 ? Moles original solution = conc x vol = 1.00 x 0.005 = 0.005 New volume = moles /conc = 0.005/0.05 = 0.1dm3 = 100cm3 Volume of water added = 100 - 5 = 95cm3 Safety and hazards Irritant - dilute acid and alkalis- wear googles Hazardous substances in low Corrosive- stronger acids and alkalis wear goggles concentrations or amounts will Flammable – keep away from naked flames not pose the same risks as the Toxic – wear gloves- avoid skin contact- wash hands after use pure substance. Oxidising- Keep away from flammable / easily oxidised materials N Goalby chemrevise.org 9 Converting quantities between different substances using a balanced equation Typically the quantity of one substance is given N2 + 3H2  2NH3 and you are asked to calculate a quantity for another substance in the reaction. Any of the The balancing (stoichiometric) numbers are mole ratios above three equations can be used. e.g. 1 mole of N2 reacts with 3 moles of H2 to produce 2moles of NH3 1. For pure solids, liquids and gases 2. For gases 3. For solutions PV = nRT moles = mass Concentration = moles Mr Or use the molar gas volume volume 1 mol gas =24dm3 at RTP Step 3 Step 1: Convert moles of second substance Use one of the above 3 equations to Step 2: into quantity question asked for convert any given quantity into moles Use balanced equation to convert using relevant equation Mass moles moles of initial substance into e.g. Moles ,Mr  mass PVT of gas  moles moles of second substance Mole, P, T gas  vol gas Conc and vol of solution  moles Moles, vol solution  conc Example 21: What mass of Carbon dioxide would be produced Example 22: 23.6cm3 of H2SO4 neutralised 25.0cm3 of 0.150M from heating 5.50 g of sodium hydrogencarbonate? NaOH. What is the concentration of the H2SO4? 2NaHCO3  Na2CO3 + CO2 + H2O H2SO4 + 2NaOH  Na2SO4 +2H2O Step 1: work out moles of sodium hydrogencarbonate Moles = mass / Mr Step 1: work out moles of sodium hydroxide = 5.50 /84 Moles = conc x vol = 0.0655 mol = 0.150 x 0.025 = 0. 00375 mol Step 2: use balanced equation to give moles of CO2 2 moles NaHCO3 : 1 moles CO2 Step 2: use balanced equation to give moles of H2SO4 So 0.0655 HNO3 : 0.0328mol CO2 2 moles NaOH : 1 moles H2SO4 Step 3: work out mass of CO2 So 0.00375 NaOH : 0.001875 mol H2SO4 Mass = moles x Mr = 0.0328 x 44.0 Step 3 work out concentration of H2SO4 =1.44g conc= moles/Volume = 0.001875 / 0.0236 Example 23: What is the total volume of gas produced in = 0.0794 mol dm-3 dm3 at 333K and 100kPa when 0.651 g of magnesium nitrate decomposes when heated? 2Mg (NO3)2 (s) 2 MgO (s) + 4NO2 (g) + O2 (g) Example 24: What mass of Copper would react completely with 150 cm3 of 1.60M nitric acid? Step 1: work out moles of magnesium nitrate 3Cu + 8HNO3  3Cu(NO3 )2 + 2NO + 4H2O Moles = mass / Mr = 0.651 / 148.3 Step 1: work out moles of nitric acid = 0.00439 mol Moles = conc x vol = 1.6 x 0.15 Step 2: use balanced equation to give moles of gas = 0.24 mol produced 2 moles Mg (NO3)2 : 4NO2 (g) + O2 (g) ie 5moles of gas Step 2: use balanced equation to give moles of Cu So 0.00439 Mg (NO3)2 : 0.01098( 0.00439 x 5/2) moles gas 8 moles HNO3 : 3 moles Cu So 0.24 HNO3 : 0.09 (0.24 x 3/8) mol Cu Step 3: work out volume of gas Step 3: work out mass of Cu Volume = nRT/P Mass = moles x Mr = (0.01098 x 8.31 x 333 )/ 100000 = 0.09 x 63.5 = 0.000304m3 =5.71g = 0.303dm3 N Goalby chemrevise.org 10 Limiting and excess reactants Example 25 Calculate the maximum mass of titanium that could be produced from reacting 100 g of TiCl4 with 80 g of sodium TiCl4 + 4 Na  4 NaCl + Ti Step 1: work out amount, in mol, TiCl4 Step 1: work out amount, in mol, Na amount = mass / Mr amount = mass / Mr = 100 /189.9 = 80/23.0 = 0.527 mol = 3.48 mol Step 2 use balanced equation to work out which reactant is in excess Using 1TiCl4 :4 Na ratio we can see that 0.527mol of TiCl4 should react with 2.108 mol of Na. We actually have 3.48 mole of Na which is an excess of 1.372 moles. We can complete calculation using the limiting reactant of TiCl 4 Step 3: use balanced equation to work out amount in mol of Ti formed 1 mol TiCl4: 1 mole Ti So 0.527mol TiCl4 produces 0.527 mole Ti Step 4: work out mass of Ti formed Mass = amount x Mr = 0.527 x 47.9 =25.24g % Yield actual yield percentage yield = x 100 theoretical yield Example 26: 25.0g of Fe2O3 was reacted and it produced 10.0g of Fe. Calculate the percentage yield? Fe2O3 + 3CO  2Fe + 3 CO2 First calculate maximum mass of Fe that could be produced Step 1: work out moles of Iron oxide Moles = mass / Mr =25.0 / 159.6 = 0.1566 mol Step 2: use balanced equation to give moles of Fe 1 moles Fe2O3 : 2 moles Fe So 0.1566 Fe2O3 : 0.313moles Fe Step 3: work out mass of Fe Mass = moles x Ar = 0.313 x 55.8 =17.5g Step 4 : calculate %yield % yield = (actual yield/theoretical yield) x 100 = (10/ 17.5) x 100 = 57.1% N Goalby chemrevise.org 11 Titrations Safety precautions The method for carrying out the titration Acids and alkalis are corrosive rinse equipment (burette with acid, pipette with alkali, conical flask (at low concentrations acids are with distilled water) irritants) pipette 25 cm3 of alkali into conical flask Wear eye protection and gloves touch surface of alkali with pipette ( to ensure correct amount is If spilled immediately wash affected added) parts after spillage adds acid solution from burette make sure the jet space in the burette is filled with acid If substance is unknown treat it as add a few drops of indicator and refer to colour change at end point potentially toxic and wear gloves. phenolphthalein [pink (alkali) to colourless (acid): end point pink colour just disappears] [use if NaOH is used] methyl orange [yellow (alkali) to red (acid): end point orange] If the jet space is not filled properly prior [use if HCl is used] to commencing the titration it will lead to use a white tile underneath the flask to help observe the colour errors if it then fills during the titration, change leading to a larger than expected titre add acid to alkali whilst swirling the mixture and add acid dropwise at reading. end point note burette reading before and after addition of acid A conical flask is used in preference to a repeats titration until at least 2 concordant results are obtained- two beaker because it is easier to swirl the readings within 0.1 of each other mixture in a conical flask without spilling the contents. Indicators are generally weak acids so we Working out average titre results only add a few drops of them. If too much Only make an average of the concordant titre results is added it will affect the titration result lf 2 or 3 values are within 0.10cm3 and therefore concordant or close then we can say results are accurate and repeatable and the titration Distilled water can be added to the conical technique is good/ consistent flask during a titration to wash the sides of the flask so that all the acid on the side is Recording results washed into the reaction mixture to react Results should be clearly recorded in a table with the alkali. Result should be recorded in full (i.e. both initial and final readings) It does not affect the titration reading as Record titre volumes to 2dp (0.05 cm3) water does not react with the reagents or change the number of moles of acid added. Common Titration Equations Titrating mixtures If titrating a mixture to work out the concentration of an active ingredient CH3CO2H + NaOH  CH3CO2-Na+ + H2O it is necessary to consider if the mixture contains other substances that H2SO4 + 2NaOH  Na2SO4 +2H2O have acid base properties. If they don’t have acid base properties we can titrate with confidence. HCl + NaOH  NaCl +H2O NaHCO3 + HCl  NaCl + CO2 + H2O Na2CO3 + 2HCl 2NaCl + CO2 + H2O Testing batches In quality control it will be necessary to do titrations/testing on several samples as the amount/concentration of the chemical being tested may vary between samples. Safely dealing with excess acid Sodium hydrogen carbonate (NaHCO3) and calcium carbonate (CaCO3) are good for neutralising excess acid in the stomach or acid spills because they are not corrosive and will not cause a hazard if used in excess. They also have no toxicity if used for indigestion remedies but the CO2 produced can cause wind. Magnesium hydroxide is also suitable for dealing with excess stomach acid as it has low solubility in water and is only weakly alkaline so not corrosive or dangerous to drink (unlike the strong alkali sodium hydroxide). It will also not produce any carbon dioxide gas. N Goalby chemrevise.org 12 More complicated titration calculations- taking samples Example 27: A 25.0cm3 sample of vinegar was diluted in a Common Titration Equations 250cm3 volumetric flask. This was then put in a burette and 23.10cm3 of the diluted vinegar neutralised 25.0 cm3 of 0.100M CH3CO2H + NaOH  CH3CO2-Na+ + H2O NaOH. What is the concentration of the vinegar in gdm-3 ? H2SO4 + 2NaOH  Na2SO4 +2H2O CH3CO2H + NaOH  CH3CO2-Na+ + H2O HCl + NaOH  NaCl +H2O Step 1: work out moles of sodium hydroxide moles = conc x vol NaHCO3 + HCl  NaCl + CO2 + H2O = 0.10 x 0.025 Na2CO3 + 2HCl 2NaCl + CO2 + H2O = 0. 00250 mol Step 2: use balanced equation to give moles of CH3CO2H Example 29 1 moles NaOH : 1 moles CH3CO2H 950 mg of impure calcium carbonate tablet was crushed. 50.0 So 0.00250 NaOH : 0.00250 mol CH3CO2H cm3 of 1.00 mol dm–3 hydrochloric acid, an excess, was then added. After the tablet had reacted, the mixture was Step 3 work out concentration of diluted CH3CO2H in 23.1 transferred to a volumetric flask. The volume was made up to (and 250 cm3) in moldm-3 exactly 100 cm3 with distilled water. 10.0 cm3 of this solution conc= moles/Volume was titrated with 11.1cm3 of 0.300 mol dm–3 sodium = 0.00250 / 0.0231 hydroxide solution. What is the percentage of CaCO3 by mass in the tablet? = 0.108 mol dm-3 1. Calculate the number of moles of sodium hydroxide used Step 4 work out concentration of original concentrated moles= conc x vol CH3CO2H in 25cm3 in moldm-3 = 0.30 x 0.0111 conc = 0.108 x 10 = 1.08 mol dm-3 = 0. 00333 mol Step 5 work out concentration of CH3CO2H in original 2. Work out number of moles of hydrochloric acid left in 10.0 cm3 concentrated 25 cm3 in gdm-3 use balanced equation to give moles of HCl conc in gdm-3 = conc in mol dm-3 x Mr 1 mol NaOH : 1 mol HCl So 0.00333 NaOH : 0.00333 moles HCl = 1.08 x 60 = 64.8 g dm-3 3. Calculate the number of moles of hydrochloric acid left in 100 cm3 of solution Example 28. An unknown metal carbonate reacts with hydrochloric acid according to the following equation. Moles in 100cm3 = 0.00333 x10 M2CO3(aq) + 2HCl(aq)  2MCl(aq) + CO2(g) + H2O(l) =0.0333 A 3.96 g sample of M2CO3 was dissolved in distilled water to make 250 cm3 of solution. A 25.0 cm3 portion of this solution 4. Calculate the number of moles of HCl that reacted with required 32.8 cm3 of 0.175 mol dm–3 hydrochloric acid for the indigestion tablet. complete reaction. Calculate the Mr of M2CO3 and identify the In original HCl 50.0 cm3 of 1.00 mol dm–3 there is 0.05moles metal M 1. Calculate the number of moles of HCl used moles of HCl that =0.05 -0.0333 moles = conc x vol reacted with the =0.0167 = 0.175 x 0.0328 indigestion tablet. = 0. 00574 mol 2. Work out number of moles of M2CO3 in 25.0 cm3 put in conical 5 Use balanced equation to give moles of CaCO3 flask CaCO3(s) + 2HCl(aq)  CaCl2(aq) + CO2(g) + H2O(l) use balanced equation to give moles of M2CO3 2 mol HCl : 1 mol CaCO3 2 mol HCl : 1 mol M2CO3 So 0.0167 HCl : 0.00835 moles CaCO3 So 0. 00574 NaOH : 0.00287 moles M2CO3 6. work out the mass of CaCO3 in original tablet 3. Calculate the number of moles M2CO3 acid in original 250 cm3 of solution mass= moles x Mr Moles in 250cm3 = 0.00287 x10 = 0.00835 x 100 = 0.835 g =0.0287 percentage of 4. work out the Mr of M2CO3 = 0.835/0.950 x100 CaCO3 by mass in Mr = mass / moles the tablet = 87.9 % = 3.96/ 0.0287= 138.0 5. Work out Ar of M = (138-12- 16x3) 2 Ar of M = 39 M= potassium N Goalby chemrevise.org 13 Uncertainty Readings and Measurements Readings Measurements The uncertainty of a reading (one judgement) is at the values found from a single the values taken as the least ±0.5 of the smallest scale reading. judgement when using a piece difference between the The uncertainty of a measurement (two judgements) of equipment judgements of two values is at least ±1 of the smallest scale reading. (e.g. using a burette in a titration) Calculating Apparatus Uncertainties Each type of apparatus has a sensitivity uncertainty To decrease the apparatus uncertainties you can either decrease the sensitivity balance  0.001 g uncertainty by using apparatus with a volumetric flask  0.1 cm3 greater resolution (finer scale divisions ) or 25 cm3 pipette  0.1 cm3 you can increase the size of the burette (start & end readings and end point )  0.15 cm3 measurement made. Calculate the percentage error for each piece of equipment used by Uncertainty of a measurement using a burette. If the burette used in the % uncertainty =  uncertainty x 100 titration had an uncertainty for each Measurement made on apparatus reading of +/– 0.05 cm3 then during a titration two readings would be taken so e.g. for burette the uncertainty on the titre volume would % uncertainty = 0.15/average titre result x100 be +/– 0.10 cm3. Then often another 0.05 is added on because of uncertainty To calculate the maximum total percentage apparatus uncertainty in the identifying the end point colour change final result add all the individual equipment uncertainties together. Reducing uncertainties in a titration If looking at a series of measurements in an investigation the experiments with the Replacing measuring cylinders with pipettes or burettes which have smallest readings will have the highest lower apparatus uncertainty will lower the error experimental uncertainties. To reduce the uncertainty in a burette reading it is necessary to make the titre a larger volume. This could be done by: increasing the volume and concentration of the substance in the conical flask or by decreasing the concentration of the substance in the burette. Reducing uncertainties in measuring mass Using a more accurate balance or a larger mass will reduce the uncertainty in weighing a solid Weighing sample before and after addition and then calculating difference will ensure a more accurate measurement of the mass added. If the %uncertainty due to the apparatus < percentage difference between the actual value and Calculating the percentage difference between the actual the calculated value then there is a discrepancy in value and the calculated value the result due to other errors. If we calculated an Mr of 203 and the real value is 214, then the calculation is as follows: If the %uncertainty due to the apparatus > Calculate difference 214-203 = 11 percentage difference between the actual value and % = 11/214 x100 the calculated value then there is no discrepancy and =5.41% all errors in the results can be explained by the sensitivity of the equipment. N Goalby chemrevise.org 14

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