AQA Chemistry A-level Group 7 - The Halogens Detailed Notes PDF
Document Details
Uploaded by FelicitousPortland1685
AQA
Tags
Summary
These detailed notes cover the properties of Group 7 elements (halogens), including atomic radius, reactivity, ionization energy, boiling points, and oxidizing power. The document explains how halogens react with other substances and different test procedures.
Full Transcript
AQA Chemistry A-level 3.2.3: Group 7 - The Halogens Detailed Notes This work by PMT Education is licensed under https://bit.ly/pmt-cc https://bit.ly/pmt-edu-cc CC BY-NC-ND 4.0...
AQA Chemistry A-level 3.2.3: Group 7 - The Halogens Detailed Notes This work by PMT Education is licensed under https://bit.ly/pmt-cc https://bit.ly/pmt-edu-cc CC BY-NC-ND 4.0 https://bit.ly/pmt-cc https://bit.ly/pmt-edu https://bit.ly/pmt-cc 3.2.3.1 - Trends in Properties The group 7 elements are highly reactive non-metals that need to gain an electron to form a 1- ion and achieve a full outer shell of electrons. Atomic Radius The atomic radius of group 7 elements increases down the group due to additional electron shells. Reactivity The group 7 elements need to gain an electron. As atomic radius increases this becomes harder as the positive attraction of the nucleus is weakened by additional shielding. Therefore it is harder to attract an electron so reactivity decreases down the group. Ionisation Energy The first ionisation energy of group II metals decreases down the group due to a greater atomic radius and increased amounts of shielding. Boiling Point The group 7 elements are simple covalent molecules held together with van der waals forces. The strength of these intermolecular forces increases as the Ar of the molecule increases. Therefore the strength of the van der waals forces increases down the group meaning more energy is required to overcome them, resulting in a higher boiling point. Fluorine is a gas at room temperature whereas iodine is a solid. Oxidising Power The halogens act a good oxidising agents as they accept electrons from the species being oxidised and are reduced. This oxidising power decreases down the group as their ability to attract electrons decreases due to shielding and a greater atomic radius. The relative oxidising strengths mean a halogen will displace any halide beneath it in the Periodic Table. Example: https://bit.ly/pmt-cc https://bit.ly/pmt-edu https://bit.ly/pmt-cc Halide Ions The negative ions of halogens are known as halide ions. These ions are good reducing agents as they donate electrons to the species being reduced and are themselves oxidised. This reducing power increases down the group as electrons are easier to lose from larger ions due to shielding and a larger atomic radius. These redox reactions with H2SO4 have to be known: 1. Fluoride and Chloride ions. 2. Bromide ions. 3. Iodide ions. The greater the reducing power, the longer the reaction as the halide is powerful enough to reduce more species. https://bit.ly/pmt-cc https://bit.ly/pmt-edu https://bit.ly/pmt-cc Silver Nitrate Acidified silver nitrate is used to test for halide ions as it reacts to form different coloured precipitates depending on the ion present. The precipitates formed may not be clear to distinguish so they can be tested further using ammonia. Cl- Br- I- + AgNO3 White precipitate Cream precipitate Yellow Precipitate (AgCl) (AgBr) (AgI) + dilute NH3 Precipitate dissolves No Change No Change + conc. NH3 Precipitate dissolves Precipitate dissolves No Change 3.2.3.2 - Chlorine and Chlorate(I) ions Chlorine reacts with cold water to produce Chlorate(I) ions (ClO-) and chloride ions. Example: This is a disproportionation reaction as the chlorine is both oxidised and reduced. The oxidation state goes from zero to both +1 and -1. In the presence of UV light, chlorine decomposes water to produce oxygen and hydrochloric acid. The chlorine is reduced in this reaction. Example: Chlorine is used in small quantities to kill bacteria in water treatment processes. This poses some risks as chlorine can be toxic; however the benefits of clean, treated water outweigh the risks. https://bit.ly/pmt-cc https://bit.ly/pmt-edu https://bit.ly/pmt-cc Bleach Production Chlorine can be mixed with cold, aqueous sodium hydroxide to produce sodium hypochlorite. This is a key ingredient in the production of bleach. Example: Tests for ions You need to know how to test for certain anions and cations for your required practical. Anions - Halides ilver nitrate and ammonia. The silver nitrate is These are tested for using acidified s acidified so that any other impurities that could form a precipitate are removed. Cl- Br- I- + AgNO3 White precipitate Cream precipitate Yellow Precipitate (AgCl) (AgBr) (AgI) + dilute NH3 Precipitate dissolves No Change No Change + conc. NH3 Precipitate dissolves Precipitate dissolves No Change Anions - Sulfate (SO42-) These are tested for using BaCl2 which reacts to form a white precipitate. Anions - Hydroxide (OH-) These ions indicate that the substance is alkaline. Therefore they can be identified with red litmus, which turns blue or using universal indicator, which turns blue-purple. Anions - Carbonate (CO32-) When an acid such as HCl is added, the substance containing the carbonate ions will fizz (effervescence) and CO2 gas is given off. This gas can be collected and bubbled through limewater which will turn cloudy, confirming it as carbon dioxide. https://bit.ly/pmt-cc https://bit.ly/pmt-edu https://bit.ly/pmt-cc Cations - Group 2 The group 2 ions can be identified with a series of flame tests. Calcium (Ca2+) Brick red Strontium (Sr2+) Red Barium (Ba2+) Pale green Cations - Ammonium (NH4+) If ammonium ions are present, ammonia gas is given off, which is a base. Therefore the presence of ammonium ions can be tested by holding red litmus over a petri dish of the substance being tested. It will turn blue if ammonium ions are present. Alternatively, they can be tested for in the same way but by adding NaOH to produce the ammonia gas faster. https://bit.ly/pmt-cc https://bit.ly/pmt-edu https://bit.ly/pmt-cc