- Colors of chemicals
All chemical compounds have
color s, and in some cases these are distinctive or useful for identification.The study of chemical structure by means of energy adsorption and release is generally referred to asspectroscopy .Theory
All chemical compounds, including atoms, are capable of absorbing and releasing energy. The amount(s) of energy (
quanta ) absorbed and released is determined by the quantum structure of the chemical. The release of energy visible to the human eye spans the wavelengths 380 nm to 760 nm and is commonly referred to ascolor . The relationship between energy and wavelength is determined by the equation::where "E" is the energy of thequanta (photon ), "h" isPlanck's constant , is the wavelength and "c" is thespeed of light . The relationship between chemical structure and energy can be understood usingatomic orbital ,molecular orbital , orLigand Field Theory . In organic compounds the color can be determined by the difference between the Highest Occupied Molecular Orbital and the Lowest Unoccupied Molecular Orbital. The energy absorbed and/or released does not directly correlate to what humans perceive as color. The absorption of a particular wavelength of light effectively subtracts it from the full visible spectrum, and what we see is thecomplementary color , made up of the other visible wavelengths.Beta-carotene has maximum absorption at 454 nm (blue light) consequently what visible light remains appears orange.Colors by wavelength
Below is a rough table of wavelengths, colors and complementary colors.
Wavelength (nm) Color Complementary Color 400-424 Violet Green-yellow 424-491 Blue Yellow 491-570 Green Red 570-585 Yellow Blue 585-647 Orange Green-Blue 647-700 Red Green Examples
Ions in aqueous solution
Name Formula Color Alkali metals M+ None Alkaline earth metals M2+ None Scandium (III) Sc3+ None Titanium (III) Ti3+ Violet Titanyl TiO2+ None Vanadium (II) V2+ Lavender Vanadium (III) V3+ Dark grey/green Vanadyl VO2+ Blue Pervanadyl VO2+ Yellow Metavanadate VO3- None Orthovanadate VO43- None Chromate CrO4 2- Colorless or Yellow(sometimes) Dichromate Cr2O72- Orange Manganese (II) Mn2+ Light pink Manganate (VII) ("Permanganate") MnO4- Deep violet Manganate (VI) MnO42- Dark green Manganate (V) MnO43- Deep blue Iron (II) Fe2+ Light blue Iron (III) Fe3+ Yellow/brown Cobalt (II) Co2+ Light red Nickel (II) Ni2+ Light green Nickel-ammonium complex Ni(NH3)62+ Lavender/blue Copper (II) Cu 2+ Blue Copper-ammonium complex Cu(NH3)42+ Royal Blue Zinc (II) Zn2+ None Silver Ag+ None It is important to note, however, that elemental colors will vary depending on what they are complexed with, often as well as their chemical state. An example with vanadium(III); VCl3 has a distinctive redish hue, whilst V2O3 appears black.
Salts
Predicting the color of a compound can be extremely complicated. Some examples include:Cobalt chloride is pink or blue depending on the state of hydration (blue dry, pink with water) so it's used as a moisture indicator in silica gel. Zinc Oxide is white, but at higher temperatures becomes yellow, returning to white as it cools.
Name Formula Color Picture Copper (II) sulfate CuSO4 Blue Copper (II) sulfate pentahydrate CuSO4 · 5H2O Blue Cobalt (II) chloride CoCl2 Deep blue Cobalt (II) chloride hexahydrate CoCl2 · 6H2O Deep magenta Manganese(II) chloride tetrahydrate MnCl2 · 4H2O Pink Copper(II) chloride dihydrate CuCl2 · 2H2O Blue-green Nickel(II) chloride hexahydrate NiCl2 · 6H2O Green Oxidising Metals
Flame Tests on cations for Alkali and Alkali Earth Metals
Name Formula Color Potassium K Lilac/Purple Sodium Na Yellow Lithium Li Red Cesium Cs Blue Calcium Ca Red/Orange Strontium Sr Red Barium Ba Green/Yellow Oxidising Gases
Name Formula Color Hydrogen H2 Colorless
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