Color of chemicals

The colour of chemicals is a physical property of chemicals that in most cases comes from the excitation of electrons due to an absorption of energy performed by the chemical. What is seen by the eye is not the colour absorbed, but the complementary colour from the removal of the absorbed wavelengths.

The study of chemical structure by means of energy absorption and release is generally referred to as spectroscopy.

Theory

The UV-vis spectrum for a compound that appears orange in Dimethylformamide

All atoms and molecules are capable of absorbing and releasing energy in the form of photons, accompanied by a change of quantum state. The amount of energy absorbed or released is the difference between the energies of the two quantum states. There are various types of quantum state, including, for example, the rotational and vibrational states of a molecule. However the release of energy visible to the human eye, commonly referred to as visible light, spans the wavelengths approximately 380 nm to 760 nm, depending on the individual, and photons in this range usually accompany a change in atomic or molecular orbital quantum state. The perception of light is governed by three types of colour receptors in the eye, which are sensitive to different ranges of wavelength within this band.

The relationship between energy and wavelength is determined by the equation:

E = hf = \frac{hc}{\lambda} \,\!

where E is the energy of the quantum (photon), f is the frequency of the light wave, h is Planck's constant, \lambda is the wavelength and c is the speed of light.

The relationships between the energies of the various quantum states are treated by atomic orbital, molecular orbital, and Ligand Field Theory. If photons of a particular wavelength are absorbed by matter, then when we observe light reflected from or transmitted through that matter, what we see is the complementary colour, made up of the other visible wavelengths remaining. For example, beta-carotene has maximum absorption at 454 nm (blue light), consequently what visible light remains appears orange.

Colours by wavelength

Below is a rough table of wavelengths, colours and complementary colours. This utilizes the scientific CMY and RGB colour wheels rather than the traditional RYB colour wheel.[1]

Wavelength (nm) Colour Complementary Colour
400-424   Violet   Green-yellow
424-491 Blue Yellow
491-570 Green Violet
570-585 Yellow Blue
585-647 Orange Cyan-Blue
647-700 Red Cyan

This can only be used as a very rough guide, for instance if a narrow range of wavelengths within the band 647-700 is absorbed, then the blue and green receptors will be fully stimulated, making cyan, and the red receptor will be partially stimulated, diluting the cyan to a greyish hue.

By category

The vast majority of simple inorganic (e.g. sodium chloride) and organic compounds (e.g. ethanol) are colorless. Transition metal compounds are often colored because of transitions of electrons between d-orbitals of different energy. (see Transition metal#Coloured compounds). Organic compounds tend to be colored when there is extensive conjugation, causing the energy gap between the HOMO and LUMO to decrease, bringing the absorption band from the UV to the visible region. Similarly, color is due to the energy absorbed by the compound, when an electron transitions from the HOMO to the LUMO. Lycopene is a classic example of a compound with extensive conjugation (11 conjugated double bonds), giving rise to an intense red color (lycopene is responsible for the color of tomatoes). Charge-transfer complexes tend to have very intense colors for different reasons.

Examples

Ions in aqueous solution

Name Formula Colour
Alkali metals M+ Colourless
Alkaline earth metals M2+ Colourless
Scandium(III) Sc3+ Colourless
Titanium(III) Ti3+ Violet
Titanium(IV) Ti4+ Colourless
Titanyl TiO2+ Colourless
Vanadium(II) V2+ Lavender
Vanadium(III) V3+ Dark grey/green
Vanadyl VO2+ Blue
Hypovanadate V4O92- Brown
Pervanadyl VO2+ Yellow
Metavanadate VO3 Colourless
Orthovanadate VO43− Colourless
Chromium(III) Cr3+ Blue-green-grey
Chromate CrO42− Yellow
Dichromate Cr2O72− Orange
Manganese(II) Mn2+ Very light Pink
Manganate(VII) (Permanganate) MnO4 Deep violet
Manganate(VI) MnO42− Dark green
Manganate(V) MnO43− Deep blue
Iron(II) Fe2+ Very pale green
Iron(III) Fe3+ Very pale violet/brown/yellow
Iron(III) tetrachloro complex FeCl4- Yellow/brown
Cobalt(II) Co2+ Pink
Cobalt(III)-ammine complex Co(NH3)63+ Yellow/orange
Nickel(II) Ni2+ Light green
Nickel(II)-ammine complex Ni(NH3)62+ Lavender/blue
Copper(I)-ammine complex Cu(NH3)2+ Colourless
Copper(II) Cu2+ Blue
Copper(II)-ammine complex Cu(NH3)42+ Royal Blue
Copper(II) tetrachloro complex CuCl42− Yellow/green
Zinc(II) Zn2+ Colourless
Silver(I) Ag+ Colourless
Silver(III) in conc. HNO3 Ag3+ Dark brown

[2] It is important to note, however, that elemental colours 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 reddish hue, whilst V2O3 appears black.

Salts

Predicting the colour 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 is 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 White
Copper(II) sulfate pentahydrate CuSO4 · 5H2O Blue
Copper(II) benzoate C14H10CuO4 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
Lead(II) iodide PbI2 Yellow

Ions in Flame

Flame Tests on cations for Alkali, Alkali Earth Metals, and Hydrogen (see atomic spectroscopy) (see also Flame test)

Metals

Name Formula Color
Potassium K Lilac/Purple
Sodium Na Yellow/orange
Lithium Li Red
Cesium Cs Blue
Calcium Ca Brick Red
Strontium Sr Red[3]
Barium Ba Green/Yellow

Gases

Name Formula Color
Hydrogen H2 colorless
Oxygen O2 colorless
Fluorine F2 very pale yellow/brown
Chlorine Cl2 greenish yellow
Bromine Br2 red/brown
Iodine I2 dark purple
Chlorine dioxide ClO2 intense yellow
Dichlorine monoxide Cl2O brown/yellow
Nitrogen dioxide NO2 dark brown
Dinitrogen tetroxide N2O4 colorless
Trifluoro nitroso methane CF3NO deep blue
Diazomethane CH2N2 yellow

Bead tests

Main article: Bead test

A variety of colours, often similar to the colours found in a flame test, are produced in a bead test, which is a qualitative test for determining metals. A platinum loop is moistened and dipped in a fine powder of the substance in question and borax. The loop with the adhered powders is then heated in a flame until it fuses and the colour of the resulting bead observed.

Metal[4] Oxidizing flameReducing flame
Aluminiumcolourless (hot and cold), opaquecolourless, opaque
Antimonycolourless, yellow or brown (hot)gray and opaque
Bariumcolourless
Bismuthcolourless, yellow or brownish (hot)gray and opaque
Cadmiumcolourlessgray and opaque
Calciumcolourless
Ceriumred (hot)colourless (hot and cold)
ChromiumDark yellow (hot), green (cold)green (hot and cold)
Cobaltblue (hot and cold)blue (hot and cold)
Coppergreen (hot), blue (cold)red, opaque (cold), colourless (hot)
Goldgolden (hot), silver (cold)red (hot and cold)
Ironyellow or brownish red (hot and cold)green (hot and cold)
Leadcolourless, yellow or brownish (hot)gray and opaque
Magnesiumcolourless
Manganeseviolet (hot and cold)colourless (hot and cold)
Molybdenumcolourlessyellow or brown (hot)
Nickelbrown, red (cold)gray and opaque (cold)
Siliconcolourless (hot and cold), opaquecolourless, opaque
Silvercolourlessgray and opaque
Strontiumcolourless
Tincolourless (hot and cold), opaquecolourless, opaque
Titaniumcolourlessyellow (hot), violet (cold)
Tungstencolourlessbrown
UraniumYellow or brownish (hot)green
Vanadiumcolourlessgreen

References

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