Overview
Halogens: group 17 elements of the periodic table. Members: fluorine (F), chlorine (Cl), bromine (Br), iodine (I), astatine (At), and tennessine (Ts, synthetic). Highly reactive nonmetals. Exist in all three states at room temperature: F2 and Cl2 as gases, Br2 as liquid, I2 as solid. Characterized by high electronegativity, strong oxidizing ability, and formation of salts with metals. Used extensively in disinfection, synthesis, and materials science.
"Halogens represent some of the most versatile and reactive elements in chemistry, bridging organic and inorganic applications seamlessly." -- J. March, Advanced Organic Chemistry
Elemental Properties
Atomic Numbers and Symbols
Fluorine (9), chlorine (17), bromine (35), iodine (53), astatine (85), tennessine (117; synthetic, unstable). Atomic mass increases down the group.
Physical States
F2 and Cl2: pale yellow and greenish gases at STP. Br2: reddish-brown liquid. I2: lustrous violet-black solid. At: presumed metalloid-like solid; rare, radioactive. Ts: uncharacterized, short half-life.
Electronegativity and Electron Affinity
Highest electronegativity in fluorine (3.98, Pauling scale). Electron affinity decreases down the group but remains significant. Strong oxidizers due to tendency to gain one electron to form halide ions.
Electronic Structure
Valence Electron Configuration
ns² np⁵ outer shell configuration for all halogens. Seven valence electrons, one short of noble gas configuration.
Electron Shells and Subshells
Fluorine: 1s² 2s² 2p⁵; chlorine: 1s² 2s² 2p⁶ 3s² 3p⁵; bromine: 1s² ... 4p⁵; iodine: 1s² ... 5p⁵; astatine: 1s² ... 6p⁵. Increasing principal quantum number down group.
Implications for Reactivity
High tendency to accept one electron to complete octet. Reactivity influenced by atomic size and shielding effect. Fluorine most reactive; reactivity decreases down the group.
Physical Properties
Color and Appearance
Fluorine: pale yellow gas. Chlorine: greenish-yellow gas. Bromine: red-brown liquid. Iodine: dark gray crystalline solid with violet vapor. Astatine: scarce data; assumed metallic luster.
Melting and Boiling Points
Increase down the group due to van der Waals forces. Fluorine: mp −220 °C, bp −188 °C. Chlorine: mp −101 °C, bp −34 °C. Bromine: mp −7 °C, bp 59 °C. Iodine: mp 114 °C, bp 184 °C.
Density and State at Room Temperature
Densities increase down group. Halogens span all three states of matter at STP: F2 and Cl2 gases, Br2 liquid, I2 solid.
| Element | State at 25°C | Melting Point (°C) | Boiling Point (°C) | Density (g/cm³) |
|---|---|---|---|---|
| Fluorine (F2) | Gas | −220 | −188 | 0.0017 |
| Chlorine (Cl2) | Gas | −101 | −34 | 0.0032 |
| Bromine (Br2) | Liquid | −7 | 59 | 3.11 |
| Iodine (I2) | Solid | 114 | 184 | 4.93 |
Chemical Properties
Oxidation States
Common oxidation state: −1 (halide ions). Positive oxidation states: +1, +3, +5, +7 in interhalogen and oxyhalide compounds, especially for heavier halogens.
Reactivity and Halogenation
Reactivity order: F2 > Cl2 > Br2 > I2. Fluorine reacts explosively with most substances. Halogenation: electrophilic substitution in organics, free radical substitution, addition to alkenes.
Halogen Displacement Reactions
More reactive halogen displaces less reactive halogen from halide salts. Example: Cl2 displaces Br− from KBr solution.
Cl2 + 2KBr → 2KCl + Br2Br2 + 2KI → 2KBr + I2I2 + 2NaAt → No reaction (At not well studied)Halogen Compounds
Halides
Salts formed by halogens with metals: NaCl, KBr, CaF2. Ionic character decreases down the group due to increasing size and polarizability.
Interhalogen Compounds
Binary compounds between different halogens: ClF, BrF3, IF7. Exhibit multiple oxidation states, strong oxidizers, used in fluorination.
Oxyhalides and Oxoacids
Examples: ClO−, ClO2, HClO4. Oxidation states range +1 to +7. Important in bleaching, disinfection, and analytical chemistry.
| Compound Type | Example | Oxidation State of Halogen | Use/Application |
|---|---|---|---|
| Halide | NaCl | −1 | Common salt, food additive |
| Interhalogen | ClF3 | +3 | Fluorinating agent |
| Oxyhalide | ClO2 | +4 | Bleaching |
| Oxoacid | HClO4 | +7 | Strong acid |
Industrial Applications
Disinfection and Water Treatment
Chlorine widely used for municipal water treatment. Fluorine derivatives in toothpaste for dental health. Halogenated compounds as biocides.
Organic Synthesis
Halogens introduce functional groups in pharmaceuticals, agrochemicals. Fluorination improves bioavailability. Bromination for flame retardants.
Materials and Polymers
Polyvinyl chloride (PVC) from vinyl chloride. Fluoropolymers (PTFE) for chemical resistance. Iodine doping in semiconductors.
Biological Roles
Essential Halogens
Iodine: critical for thyroid hormone synthesis. Fluoride: strengthens dental enamel. Chloride: electrolyte balance, nerve function.
Halogen Toxicity
Excess halogens cause toxicity: fluorosis, halogenism. Some organohalogens are bioaccumulative and disrupt endocrine systems.
Halogenated Natural Products
Marine organisms produce halogenated alkaloids, terpenes with antimicrobial properties. Biological halogenation catalyzed by halogenases.
Isotopes and Radionuclides
Stable Isotopes
Chlorine: 35Cl and 37Cl. Bromine: 79Br and 81Br. Iodine: 127I (only stable). Used in isotope labeling and tracing.
Radioactive Isotopes
Astatine isotopes: all radioactive, short half-lives. Iodine-131: medical diagnostic and therapeutic use. Fluorine-18: positron emission tomography (PET) tracer.
Applications in Medicine
Radioisotopes for imaging, cancer therapy. Halogen isotopes in radiolabeling of drugs.
Environmental Impact
Ozone Depletion
Halogenated chlorofluorocarbons (CFCs) catalyze ozone destruction. Bromine compounds more destructive per atom. Montreal Protocol limits emissions.
Persistent Organic Pollutants
Halogenated organics resist degradation. Bioaccumulate in food chains. Toxicity to wildlife and humans.
Remediation Strategies
Advanced oxidation processes degrade halogenated pollutants. Bioremediation using halorespiring bacteria. Regulatory controls essential.
Trends in Group 17
Atomic and Ionic Radii
Increase down group due to added shells. Ionic radius: halide ions larger than atoms. Correlates with bond lengths and lattice energies.
Electronegativity and Reactivity
Electronegativity decreases down group. Reactivity highest in fluorine, lowest in iodine and astatine.
Acid-Base Behavior
Hydrogen halides: HF is weak acid; HCl, HBr, HI strong acids. Acid strength increases down group due to bond weakening.
Synthesis Methods
Elemental Halogens
Fluorine: electrolysis of HF with KF. Chlorine: electrolysis of brine (chloralkali process). Bromine and iodine: extracted from brines and minerals.
Halogenated Organic Compounds
Free radical halogenation, electrophilic substitution, halogen exchange reactions. Selectivity controlled by conditions and catalysts.
Interhalogen and Oxyhalogen Compounds
Direct combination of halogens under controlled conditions. Oxyhalides via controlled oxidation of halides.
Chloralkali process:2NaCl + 2H2O → Cl2 + H2 + 2NaOH (electrolysis)Fluorine production:2HF + 2KF → 2KHF2 (electrolysis) → F2 + H2 + other productsReferences
- Greenwood, N. N., & Earnshaw, A. (1997). Chemistry of the Elements. 2nd ed., Butterworth-Heinemann, pp. 500-540.
- Sharma, S. K., & Maiti, B. (2011). Halogens and Their Compounds. Journal of Chemical Education, 88(10), 1348-1355.
- Holleman, A. F., Wiberg, E., & Wiberg, N. (2007). Inorganic Chemistry. Academic Press, 1010-1050.
- McMurry, J. (2016). Organic Chemistry. 9th ed., Cengage Learning, pp. 850-880.
- Seinfeld, J. H., & Pandis, S. N. (2016). Atmospheric Chemistry and Physics. Wiley, 3rd ed., pp. 450-480.