9701_w23_qp_23 - revisedeck

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The elements phosphorus, sulfur and chlorine are in Period 3 of the Periodic Table. Table 1.1 shows some properties of the elements P to Cl . The first ionisation energy of S is not shown. Table 1.1 property P S Cl number of electrons in 3p subshell total number of unpaired electrons first ionisation energy / kJ mol–1 formula of most common anion P3– S2– Cl – Complete Table 1.1 to show the number of electrons in the 3p subshell and the total number of unpaired electrons in an atom of P, S and Cl . Construct an equation to represent the first ionisation energy of P. Three possible values for the first ionisation energy of S are given. 1000 kJ mol–1 1160 kJ mol–1 1320 kJ mol–1 Circle the correct value. Explain your choice by comparing your chosen value to those of P and Cl . P3–, S2– and Cl – have the same number of electrons. Give the full electronic configuration of P3–. State the trend in ionic radius shown by P3–, S2– and Cl –. Explain your answer. A student does three tests on separate samples of NaCl . Complete Table 1.2 with the observations the student makes in each test. Table 1.2 test test observations addition of a few drops of Br22 addition of a few drops of concentrated H2SO4 addition of a few drops of dilute AgNO3 POCl3 shows similar chemical properties to PCl5. POCl3 has a melting point of 1°C and a boiling point of 106 °C. POCl3 reacts vigorously with water, forming misty fumes and an acidic solution. Explain how the information in suggests the structure and bonding of POCl3 is simple covalent. Construct an equation for the reaction of POCl3 with water. POCl3 + POCl3 contains a double covalent bond between P and O. Complete the dot-and-cross diagram, in , to show the bonding in POCl3. Show outer shell electrons only. O P Cl Cl Cl POCl3forms when PCl3reacts with O2. 2PCl3+ O22POCl3Table 1.3 gives some relevant data. Table 1.3 process value / kJ mol–1 enthalpy change of formation of PCl3–289 enthalpy change of formation of POCl3–592 O22O+496 Define enthalpy change of formation, ΔHf . Calculate the bond energy of P=O in POCl 3 using the data in Table 1.3. Show your working. bond energy of P=O = kJ mol–1

1. Atomic structure → 1.4. Ionisation energy

9. The Periodic Table: chemical periodicity → 9.2. Periodicity of chemical properties of the elements in Period 3

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Barium hydroxide, Ba(OH)2 , is a strong base used in inorganic and organic reactions. shows a reaction scheme involving Ba(OH)2. BaOBa(OH)2BaCO3+ H2OCH3COOHreaction 3 H2Oreaction 1 reaction 2 A+ H2OState the variation in solubilities of group 2 hydroxides. State what is observed in reaction 1. Suggest a reactant for reaction 2. Identify A. Ba(OH)2 is made by the reaction of Ba with water. Write an equation for this reaction. The mineral barytocalcite contains both BaCO3 and CaCO3. Both compounds decompose on heating. State which compound decomposes first when barytocalcite is heated. Explain your answer. Construct an equation for the complete thermal decomposition of barytocalcite. The formula of barytocalcite is BaCa(CO3)2. BaCa(CO3)2 Ba(OH)2 is used to hydrolyse organic compounds. shows the reaction of B with Ba(OH)2, followed by acidification. Draw the structures of the organic products of the process shown in . CO2CH3 Ba(OH)2 then HNO3 + Ba(NO3)2 organic product 1 CN B organic product 2 +

10. Group 2 → 10.1. Similarities and trends in the properties of the Group 2 metals, magnesium to barium, and their compounds

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Potassium chlorate, KCl O3, is widely used as an oxidising agent and to make O2. Define oxidising agent. KCl O3decomposes when heated. MnO2catalyses the exothermic decomposition reaction. Complete and label the diagram in to show the effect of MnO2on the decomposition of KCl O3. enthalpy reactants progress of reaction products When KCl O3 is heated without a catalyst, KCl O4 and KCl form. 4KCl O3 3KCl O4 + KCl Explain why this reaction is described as a disproportionation reaction. Molten KCl O3 reacts with glucose, C6H12O6. 4KCl O3 + C6H12O6 6CO2 + 6H2O + 4KCl KCl O3 melts at 630 K. At this temperature, both CO2 and H2O are gases. Use the ideal gas equation to calculate the volume, in m3, of one mole of gas at 630 K and 1.00 × 105 Pa. Show your working. Give your answer to 3 significant figures. volume of 1 mol of gas = m3 5.00 g of C6H12O6 reacts completely with molten KCl O3. Use your answer to to calculate the total volume of gas released at 630 K and 1.00 × 105 Pa in this reaction. (If you were unable to answer , use 0.0463 m3 in this question. This is not the correct answer to .) total volume of gas released = m3 The structure of glucose, C6H12O6, is shown in . OH OH OH HO O OH glucose Complete Table 3.1 to identify the number of primary, secondary and tertiary alcohol groups present in the structure shown in . Table 3.1 type of alcohol group primary secondary tertiary number of groups Separate samples of aqueous glucose are tested with the reagents shown in Table 3.2. Complete Table 3.2 with the observation for each reaction. Write “no reaction” if applicable. Table 3.2 reagent and conditions observation with glucose acidified KMnO4and warm Fehling’s reagent and warm alkaline I2and warm There are many structural isomers of C6H12O6. Define structural isomers.

11. Group 17 → 11.4. The reactions of chlorine

2. Atoms, molecules and stoichiometry → 2.4. Reacting masses and volumes (of solutions and gases)

16. Hydroxy compounds → 16.1. Alcohols

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Compounds C and D are alkenes with the same molecular formula, C5H10. C D Give the systematic name of D. Explain why C and D do not show geometrical (cis/trans) isomerism. Draw the structure of a molecule that is a positional isomer of C and D. Give the structural formula of the compound formed when D reacts with H2in the presence of a Pt catalyst. C can form an addition polymer. Draw the structure of one repeat unit of this addition polymer. The mass spectrum of C shows a molecular ion peak at m/e = 70. This peak has a relative intensity of 48.7. The relative intensity of the [M+1] peak is 2.7. Show that this information is consistent with the molecular formula of C. C and D both react with HBr. C reacts with HBr to form E. Complete the diagram in to show the mechanism for this reaction. Draw the structure of the organic intermediate. Include charges, dipoles, lone pairs of electrons and curly arrows, as appropriate. C H – Br E Br D reacts with HBr to produce F, a chiral bromoalkane. Draw the structure of F. F Explain why the reaction of HBr with C and D produces different major products. C D C can be used to form H. H O O One possible synthesis of H is shown in . Different portions of C are used in reactions 1 and 3. Some of the products are then combined to produce H. does not show any of the inorganic products of the reactions. C E G + J + G then: J O Br HBrreaction 1 reaction 2 reaction 3 reaction 4 H O O

14. Hydrocarbons → 14.2. Alkenes

14. Hydrocarbons → 14.1. Alkanes

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