iron) and non-metals (e.g. In what way and in what form does lithium react with water? The development of metallic/salty taste, dental caries, and swollen lips were unrelated to dosage. The reaction of lithium with water to produce a metal hydroxide and hydrogen is called hydrolysis. The volatility of Lithium is well known and has been demonstrated to be faulty on a number of occasions as reported in the technical press. All elements of group 1A undergo hydrolysis when placed in water because of their high electropositivity. Diarrhea and vomiting may be early signs of lithium toxicity, and may occur at lithium levels below 2 mEq/L. It gradually reacts and disappears, forming a colourless solution of lithium hydroxide. The reaction is exothermic, so heat is also given off, and if enough heat is given off, the hydrogen gas will burn in a crimson flame, though that doesn't happen often, as lithium … The observations for the reaction of lithium and water are: fizzing (hydrogen gas is released) lithium floats and moves around on the water; lithium disappears; Sodium is the second alkali metal in the group. The reaction of lithium with water to produce a metal hydroxide and hydrogen is called hydrolysis. The colourless solution is highly alkalic. Lithium. phosphorus) with air, 2:11 describe the combustion of elements in oxygen, including magnesium, hydrogen and sulfur, 2:12 describe the formation of carbon dioxide from the thermal decomposition of metal carbonates, including copper(II) carbonate, 2:13 know that carbon dioxide is a greenhouse gas and that increasing amounts in the atmosphere may contribute to climate change, 2:14 Practical: determine the approximate percentage by volume of oxygen in air using a metal or a non-metal, 2:15 understand how metals can be arranged in a reactivity series based on their reactions with: water and dilute hydrochloric or sulfuric acid, 2:16 understand how metals can be arranged in a reactivity series based on their displacement reactions between: metals and metal oxides, metals and aqueous solutions of metal salts, 2:17 know the order of reactivity of these metals: potassium, sodium, lithium, calcium, magnesium, aluminium, zinc, iron, copper, silver, gold, 2:18 know the conditions under which iron rusts, 2:19 understand how the rusting of iron may be prevented by: barrier methods, galvanising and sacrificial protection, 2:20 in terms of gain or loss of oxygen and loss or gain of electrons, understand the terms: oxidation, reduction, redox, oxidising agent, reducing agent, in terms of gain or loss of oxygen and loss or gain of electrons, 2:21 practical: investigate reactions between dilute hydrochloric and sulfuric acids and metals (e.g. The colourless solution is highly alkalic. The reaction of sodium and water is more vigorous than lithium’s: Potassium is the third alkali metal in the group. These outer electrons are readily ejected from the atom … The observations for the reaction of lithium and water are: fizzing (hydrogen gas is released) lithium floats and moves around on the water lithium disappears Sodium is the second alkali metal in the group. Transient and mild nausea may occur within the first few days of therapy. The reaction of sodium and water is more vigorous than lithium’s: Lithium reacts intensely with water, forming lithium hydroxide and highly flammable hydrogen. 2LiOH + CO2 = Li2CO3 + H2O Molar ratios are 2:1::1:1 Mr (LiOH) Li x 1 = 7 x 1 = 7 O x 1 = 16 x 1 = 16 H x 1 = 1 x 1 =1 7 + 16 + 1 = 24 (Mr (LiOH)) Moles … The electrons of the outer shells of this group are weakly attracted to the nucleus, being shielded from nuclear charge by the inner shells of electrons. 4:49 (Triple only) Understand how to write the structural and displayed formula of a polyester, showing the repeat unit, given the formulae of the monomers from which it is formed, including the reaction of ethanedioic acid and ethanediol: 4:50 (Triple only) know that some polyesters, known as biopolyesters, are biodegradable, (d) Energy resources and electricity generation, 2:01 understand how the similarities in the reactions of lithium, sodium and potassium with…, 2:07 understand how displacement reactions involving halogens and halides provide evidence…, 2:17 know the order of reactivity of these metals: potassium, sodium, lithium, calcium,…, 2:34 know the general rules for predicting the solubility of ionic compounds in water:…, 2:15 understand how metals can be arranged in a reactivity series based on their reactions…, 2:04 (Triple only) explain the trend in reactivity in Group 1 in terms of electronic configurations, d) Relative formula masses and molar volumes of gases, e) Chemical formulae and chemical equations, b) Group 1 elements: lithium, sodium and potassium, c) Group 7 elements: chlorine, bromine and iodine, d) The industrial manufacture of chemicals, lithium floats and moves around on the water, sodium floats and moves around on the water, potassium floats and moves around on the water. magnesium, zinc and iron), 2:22 (Triple only) know that most metals are extracted from ores found in the Earth’s crust and that unreactive metals are often found as the uncombined element, 2:23 (Triple only) explain how the method of extraction of a metal is related to its position in the reactivity series, illustrated by carbon extraction for iron and electrolysis for aluminium, 2:24 (Triple only) be able to comment on a metal extraction process, given appropriate information, 2:25 (Triple only) explain the uses of aluminium, copper, iron and steel in terms of their properties the types of steel will be limited to low-carbon (mild), high-carbon and stainless, 2:26 (Triple only) know that an alloy is a mixture of a metal and one or more elements, usually other metals or carbon, 2:27 (Triple only) explain why alloys are harder than pure metals, 2:28 describe the use of litmus, phenolphthalein and methyl orange to distinguish between acidic and alkaline solutions, 2:29 understand how to use the pH scale, from 0–14, can be used to classify solutions as strongly acidic (0–3), weakly acidic (4–6), neutral (7), weakly alkaline (8–10) and strongly alkaline (11–14), 2:30 describe the use of Universal Indicator to measure the approximate pH value of an aqueous solution, 2:31 know that acids in aqueous solution are a source of hydrogen ions and alkalis in a aqueous solution are a source of hydroxide ions, 2:32 know that bases can neutralise acids, 2:33 (Triple only) describe how to carry out an acid-alkali titration, 2:34 know the general rules for predicting the solubility of ionic compounds in water: common sodium, potassium and ammonium compounds are soluble, all nitrates are soluble, common chlorides are soluble, except those of silver and lead(II), common sulfates are soluble, except for those of barium, calcium and lead(II), common carbonates are insoluble, except for those of sodium, potassium and ammonium, common hydroxides are insoluble except for those of sodium, potassium and calcium (calcium hydroxide is slightly soluble), 2:35 understand acids and bases in terms of proton transfer, 2:36 understand that an acid is a proton donor and a base is a proton acceptor, 2:37 describe the reactions of hydrochloric acid, sulfuric acid and nitric acid with metals, bases and metal carbonates (excluding the reactions between nitric acid and metals) to form salts, 2:38 know that metal oxides, metal hydroxides and ammonia can act as bases, and that alkalis are bases that are soluble in water, 2:39 describe an experiment to prepare a pure, dry sample of a soluble salt, starting from an insoluble reactant, 2:40 (Triple only) describe an experiment to prepare a pure, dry sample of a soluble salt, starting from an acid and alkali, 2:41 (Triple only) describe an experiment to prepare a pure, dry sample of an insoluble salt, starting from two soluble reactants, 2:42 practical: prepare a sample of pure, dry hydrated copper(II) sulfate crystals starting from copper(II) oxide, 2:43 (Triple only) practical: prepare a sample of pure, dry lead(II) sulfate, 2:44a describe tests for these gases: hydrogen, carbon dioxide, 2:44 describe tests for these gases: hydrogen, oxygen, carbon dioxide, ammonia, chlorine, 2:45 describe how to carry out a flame test, 2:46 know the colours formed in flame tests for these cations: Li⁺ is red, Na⁺ is yellow, K⁺ is lilac, Ca²⁺ is orange-red, Cu²⁺ is blue-green, 2:47 describe tests for these cations: NH₄⁺ using sodium hydroxide solution and identifying the gas evolved, Cu²⁺, Fe²⁺ and Fe³⁺ using sodium hydroxide solution, 2:48 describe tests for these anions: Cl⁻, Br⁻ and I⁻ using acidified silver nitrate solution, SO₄²⁻ using acidified barium chloride solution, CO₃²⁻ using hydrochloric acid and identifying the gas evolved, 2:49 describe a test for the presence of water using anhydrous copper(II) sulfate, 2:50 describe a physical test to show whether a sample of water is pure, 3:01 know that chemical reactions in which heat energy is given out are described as exothermic, and those in which heat energy is taken in are described as endothermic, 3:02 describe simple calorimetry experiments for reactions such as combustion, displacement, dissolving and neutralisation, 3:03 calculate the heat energy change from a measured temperature change using the expression Q = mcΔT, 3:04 calculate the molar enthalpy change (ΔH) from the heat energy change, Q, 3:05 (Triple only) draw and explain energy level diagrams to represent exothermic and endothermic reactions, 3:06 (Triple only) know that bond-breaking is an endothermic process and that bond-making is an exothermic process, 3:07 (Triple only) use bond energies to calculate the enthalpy change during a chemical reaction, 3:08 practical: investigate temperature changes accompanying some of the following types of change: salts dissolving in water, neutralisation reactions, displacement reactions and combustion reactions, 3:09 describe experiments to investigate the effects of changes in surface area of a solid, concentration of a solution, temperature and the use of a catalyst on the rate of a reaction, 3:10 describe the effects of changes in surface area of a solid, concentration of a solution, pressure of a gas, temperature and the use of a catalyst on the rate of a reaction, 3:11 explain the effects of changes in surface area of a solid, concentration of a solution, pressure of a gas and temperature on the rate of a reaction in terms of particle collision theory, 3:12 know that a catalyst is a substance that increases the rate of a reaction, but is chemically unchanged at the end of the reaction, 3:13 know that a catalyst works by providing an alternative pathway with lower activation energy, 3:14 (Triple only) draw and explain reaction profile diagrams showing ΔH and activation energy, 3:15 practical: investigate the effect of changing the surface area of marble chips and of changing the concentration of hydrochloric acid on the rate of reaction between marble chips and dilute hydrochloric acid, 3:16 practical: investigate the effect of different solids on the catalytic decomposition of hydrogen peroxide solution, 3:17 know that some reactions are reversible and this is indicated by the symbol ⇌ in equations, 3:18 describe reversible reactions such as the dehydration of hydrated copper(II) sulfate and the effect of heat on ammonium chloride, 3:19 (Triple only) know that a reversible reaction can reach dynamic equilibrium in a sealed container, 3:20 (Triple only) know that the characteristics of a reaction at dynamic equilibrium are: the forward and reverse reactions occur at the same rate, and the concentrations of reactants and products remain constant, 3:21 (Triple only) understand why a catalyst does not affect the position of equilibrium in a reversible reaction, 3:22 (Triple only) predict, with reasons, the effect of changing either pressure or temperature on the position of equilibrium in a reversible reaction (references to Le Chatelier’s principle are not required), 4:01 know that a hydrocarbon is a compound of hydrogen and carbon only, 4:02 understand how to represent organic molecules using empirical formulae, molecular formulae, general formulae, structural formulae and displayed formulae, 4:03a know what is meant by the term isomerism, 4:03 know what is meant by the terms homologous series, functional group and isomerism, 4:04 understand how to name compounds relevant to this specification using the rules of International Union of Pure and Applied Chemistry (IUPAC) nomenclature.
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