A
chromophore is the part of a
molecule responsible for its
color.
The color arises when a molecule
absorbs certain
wavelengths of
visible light and transmits or reflects others. The chromophore is a region in the molecule where the energy difference between two different
molecular orbitals falls within the range of the visible spectrum. Visible light that hits the chromophore can thus be absorbed by exciting an
electron from its
ground state into an
excited state.
In biological molecules that serve to capture or detect light energy, the chromophore is the moiety that causes a conformational change of the molecule when hit by light.
. The eleven conjugated double bonds that form the chromophore of the molecule are highlighted in red.]]
Types of chromophore
γ (light), of the correct wavelength: 11-cis-retinal becomes
all-trans-retinal]]
Chromophores almost always arise in one of two forms: conjugated pi systems (also known as resonating systems) and metal complexes.
Conjugated pi-bond system chromophores
In the conjugated chromophores, the electrons jump between energy levels that are extended
pi orbitals, created by a series of alternating
single and double bonds, often in
aromatic systems. Common examples include
retinal (used in the eye to detect light), various
food colorings, fabric dyes (
azo compounds),
pH indicators,
lycopene,
β-carotene, and
anthocyanins. Various factors in a chromophore's structure go into determining at what wavelength region in a spectrum the chromophore will absorb. Lengthening or extending a conjugated system with more unsaturated (multiple) bonds in a molecule will tend to shift absorption to longer wavelengths.
Woodward-Fieser rules can be used to approximate
ultraviolet-visible maximum absorption wavelength in organic compounds with conjugated pi-bond systems.
Metal complex chromophores
The metal complex chromophores arise from the splitting of
d-orbitals by binding of a
transition metal to
ligands. Examples of such chromophores can be seen in
chlorophyll (used by plants for
photosynthesis),
hemoglobin,
hemocyanin, and colorful
minerals such as
malachite and
amethyst.
A common motif in biochemistry is chromophores consisting of four pyrrole rings. These come in two types:
the pyrroles form an open chain, no metal: phytochrome, phycobilin, bilirubin
the pyrroles form a ring (porphyrin), with a metal in the center: heme, chlorophyll
Auxochrome
An
auxochrome is a functional group of atoms attached to a chromophore which modifies the ability of the chromophore to absorb light, altering the wavelength or intensity of the absorption.
Halochromism in chromophores
Halochromism occurs when a substance changes color as the
pH changes. This is a property of pH indicators, whose
molecular structure changes upon certain changes in the surrounding pH. This change in structure affects a chromophore in the pH indicator molecule. For example,
phenolphthalein is a pH indicator whose structure changes as pH changes as shown in the following table:
In a pH range of about 0-8, the molecule has three aromatic rings all bonded to a tetrahedral sp3 hybridized carbon atom in the middle which does not make the π-bonding in the aromatic rings conjugate. Because of their limited extent, the aromatic rings only absorb light in the ultraviolet region, and so the compound appears colorless in the 0-8 pH range. However as the pH increases beyond 8.2, that central carbon becomes part of a double bond becoming sp2 hybridized and leaving a p orbital to overlap with the π-bonding in the rings. This makes the three rings conjugate together to form an extended chromophore absorbing longer wavelength visible light to show a fuchsia color. At pH ranges outside 0-12, other molecular structure changes result in other color changes; see Phenolphthalein for details.
See also
Visual phototransduction
Woodward's rules
Chromatophore
Pigment
Photophore
External links
Causes of Color: physical mechanisms by which color is generated.
High Speed Nano-Sized Electronics May be Possible with Chromophores - Azonano.com
References
Category:Chemical compounds
Category:Color