Chromism
In chemistry, chromism is a process that induces a change, often reversible, in the colors of compounds. In most cases, chromism is based on a change in the electron states of molecules, especially the π- or d-electron state, so this phenomenon is induced by various external stimuli which can alter the electron density of substances. It is known that there are many natural compounds that have chromism, and many artificial compounds with specific chromism have been synthesized to date. It is usually synonymous with chromotropism, the change in color of a substance due to the physical and chemical properties of its ambient surrounding medium, such as temperature and pressure, light, solvent, and presence of ions and electrons.
Chromism is classified by what kind of stimuli are used. Examples of the major kinds of chromism are as follows.thermochromism is chromism that is induced by heat, that is, a change of temperature. This is the most common chromism of all.photochromism is induced by light irradiation. This phenomenon is based on the isomerization between two different molecular structures, light-induced formation of color centers in crystals, precipitation of metal particles in a glass, or other mechanisms.electrochromism is induced by the gain and loss of electrons. This phenomenon occurs in compounds with redox active sites, such as metal ions or organic radicals.
- solvatochromism depends on the polarity of the solvent. Most solvatochromic compounds are metal complexes.
The output from the chromisms described above is observed by a change in the absorption spectra of the chromic material. An increasingly important group of chromisms are those where changes are displayed in their emission spectra. Hence they are called fluorochromisms, exemplified by solvatofluorochromism, electrofluorochromism and mechanofluorochromism.
Chromic phenomena
Chromic phenomena are those phenomena in which color is produced when light interacts with materials, often called chromic materials in a variety of ways. These can be categorized under the following five headings:- Stimulated color change
- The absorption and reflection of light
- The absorption of energy followed by the emission of light
- The absorption of light and energy transfer
- The manipulation of light.
Color change phenomena
Those phenomena which involve the change in color of a chemical compound under an external stimulus fall under the generic term of chromisms. They take their individual names from the type of the external influence, which can be either chemical or physical, that is involved. Many of these phenomena are reversible. The following list includes all the classic chromisms plus many others of increasing interest in newer outlets.| Type | Cause |
| Thermochromism | temperature |
| Electrochromism | electric current |
| Gasochromism | gas - hydrogen/oxygen redox |
| Solvatochromism | solvent polarity |
| Concentratochromism | changes in the concentration in the medium |
| Rigidichromism | changes in the rigidity of the medium |
| Vapochromism | vapour of an organic compound due to chemical polarity/polarisation |
| Ionochromism | ions |
| Halochromism | change in pH |
| Metallochromism | metal ions |
| Mechanochromism | mechanical actions |
| Tribochromism | mechanical friction |
| Piezochromism | mechanical pressure |
| Cathodochromism | electron beam irradiation |
| Radiochromism | ionising radiation |
| Magnetochromism | magnetic field |
| Biochromism | interfacing with a biological entity |
| Amorphochromism | changes in crystalline habitat |
| Cryochromism | lowering of temperature |
| Hydrochromism | interaction with bulk water or humidity |
| Chronochromism | indirectly as a result of the passage of time |
| Aggregachromism | dimerisation/aggregation of chromophores |
| Crystallochromism | changes in crystal structure of a chromophore |
| Sorptiochromism | when a species is surface adsorbed |
There are also chromisms which involve two or more stimuli. Examples include:
- Photoelectrochromism – Photovoltachromism – Bioelectrochromism – Solvatophotochromism – Thermosolvatochromism – Halosolvatochromism – Electromechanochromism.
Commercial applications
Color change materials have been used in several very common outlets but also in an increasing number of new ones. Commercial applications include photochromics in ophthalmics, fashion/cosmetics, security, sensors, optical memory and optical switches, thermochromics in paints, inks, plastics and textiles as indicators/sensors and in architecture, ionochromics in copy paper, thermal printing">thermal energy">thermal printing and textile sensors, electrochromics in car mirrors, smart windows, flexible devices and solar protection, solvatochromics in biological probes and sensors, gasochromics in windows and gas sensors.Dyes and pigments
Classical dyes and pigments produce color by the absorption and reflection of light; these are the materials that make a major impact on the color of our daily lives. In 2000, world production of organic dyes was 800,000 tonnes and of organic pigments, 250,000 tonnes and the volume has grown at a steady rate throughout the early years of this century. In 2019 the value of the organic dyes/pigments market is forecast to be $19.5bn. Their value is exceeded by the very large production of inorganic pigments. Organic dyes are used mainly to color textile fibers, paper, hair, leather, while pigments are used largely in inks, paints, plastic and cosmetics. Both are used in the growth area of the digital printing of textiles, paper and other surfaces.Dyes are also made using the properties of chromic substances: Examples being
Photochromic dyes and
Thermochromic dyes
Luminescence
The absorption of energy followed by the emission of light is often described by the term luminescence. The exact term used is based on the energy source responsible for the luminescence as in color-change phenomena.- Electrical – electroluminescence Galvanoluminescence Sonoluminescence.
- Photons (light) – Photoluminescence Fluorescence Phosphorescence Biofluorescence.
- Chemical – Chemiluminescence Bioluminescence Electrochemiluminescence.
- Thermal – Thermoluminescence Pyroluminescence Candololuminescence.
- Electron Beam – Cathodoluminescence Anodoluminescence Radioluminescence.
- Mechanical – Triboluminescence Fractoluminescence Mechanoluminescence Crystalloluminescence Lyoluminescence Elasticoluminescence.