Sulfuric acid The term intermolecular forces of attraction can be used to represent all forces between molecules, 1:48 explain why the melting and boiling points of substances with simple molecular structures increase, in general, with increasing relative molecular mass, 1:49 explain why substances with giant covalent structures are solids with high melting and boiling points, 1:50 explain how the structures of diamond, graphite and C, 1:51 know that covalent compounds do not usually conduct electricity, 1:52 (Triple only) know how to represent a metallic lattice by a 2-D diagram, 1:53 (Triple only) understand metallic bonding in terms of electrostatic attractions, 1:54 (Triple only) explain typical physical properties of metals, including electrical conductivity and malleability, 1:55 (Triple only) understand why covalent compounds do not conduct electricity, 1:56 (Triple only) understand why ionic compounds conduct electricity only when molten or in aqueous solution, 1:57 (Triple only) know that anion and cation are terms used to refer to negative and positive ions respectively, 1:58 (Triple only) describe experiments to investigate electrolysis, using inert electrodes, of molten compounds (including lead(II) bromide) and aqueous solutions (including sodium chloride, dilute sulfuric acid and copper(II) sulfate) and to predict the products, 1:59 (Triple only) write ionic half-equations representing the reactions at the electrodes during electrolysis and understand why these reactions are classified as oxidation or reduction, 1:60 (Triple only) practical: investigate the electrolysis of aqueous solutions, (a) Group 1 (alkali metals) lithium, sodium and potassium, 2:01 understand how the similarities in the reactions of lithium, sodium and potassium with water provide evidence for their recognition as a family of elements, 2:02 understand how the differences between the reactions of lithium, sodium and potassium with air and water provide evidence for the trend in reactivity in Group 1, 2:03 use knowledge of trends in Group 1 to predict the properties of other alkali metals, 2:04 (Triple only) explain the trend in reactivity in Group 1 in terms of electronic configurations, (b) Group 7 (halogens) chlorine, bromine and iodine, 2:05 know the colours, physical states (at room temperature) and trends in physical properties of chlorine, bromine and iodine, 2:06 use knowledge of trends in Group 7 to predict the properties of other halogens, 2:07 understand how displacement reactions involving halogens and halides provide evidence for the trend in reactivity in Group 7, 2:08 (Triple only) explain the trend in reactivity in Group 7 in terms of electronic configurations, 2:09 know the approximate percentages by volume of the four most abundant gases in dry air, 2:10 understand how to determine the percentage by volume of oxygen in air using experiments involving the reactions of metals (e.g.
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