Chapter 3 Photophysics

Emission and loss processes: Several of pathways for loss of electronic excitation shown in Fig. as a emission of light as luminescence

The individual luminescence phenomena are named according to the mode of excitation of the energy-rich species. Emission from species excited by absorption of radiation is referred to fluorescence or phosphorescence Emission following excitation by chemical reaction (of natural or changed species) is chemiluminescence.

If emission of radiation continued after the exciting radiation was shut off, the emitting species was said to phosphorescent, while if emission appeared to cease immediately, then the phenomenon was one of fluorescence.

Bioluminescence Artistic rendering of bioluminescent Antarctic krillAntarctic krill Fireflies Firefly luciferin

Image of bioluminescent red tide event of 2005 at a beach in Carlsbad California showing brilliantly glowing crashing wavesred tide containing billions of Lingulodinium polyedrum dinoflagellatesLingulodinium polyedrumdinoflagellates

In 1935, Jablonski phosphorescence was emission from some long-lived metastable electronic state lying lower in energy than the state populated by absorption of radiation (see section 1.9). This long-lived metastable state is now known to be the first excited triplet in many cases where the ground state of a molecule is a singlet. The long lifetime of the emission is a direct consequence of the forbidden.

Absorption and emission pathways McGarvey and Gaillard, Basic Photochemistry at Dr. Suzan A. Khayyat9

Quenching or collisional deactivation In addition to loss by emission and intermolecular energy transfer (IC and ISC ), excited states often suffer losses in quenching processes. Quenching is especially important in the liquid phase where collisions are very frequent.

Fluorescence, Phosphorescence and Chemiluminescence There are three main types of “cold light” reactions in chemistry which are often confused but are in fact very different. It is important to make sure that you know the difference.

Fluorescence is the emission of light by a substance that has absorbed light or other electromagnetic radiation of a different wavelength It is a form of luminescence. In most cases, emitted light has a longer wavelength, and therefore lower energy, than the absorbed radiation. However, when the absorbed electromagnetic radiation is intense, it is possible for one electron to absorb two photons; this two- photon absorption can lead to emission of radiation having a shorter wavelength than the absorbed radiation. The most striking examples of fluorescence occur when the absorbed radiation is in the ultraviolet region of the spectrum, and thus invisible to the human eye, and the emitted light is in the visible region. Fluorescence has many practical applications, including chemical sensors (fluorescence spectroscopy), fluorescent labelling, dyes, biological detectors, and, most commonly, fluorescent lamps.

Fluorescence occurs when an orbital electron of a molecule, atom or nanostructure relaxes to its ground state by emitting a photon of light after being excited to a higher quantum state by some type of energy:electronnanostructureground statephotonexcited Excitation: : Fluorescence (emission): hν is a generic term for photon energy with h = Planck's constant and ν = frequency of light. (The specific frequencies of exciting and emitted light are dependent on the particular system.)Planck's constantfrequency State S 0 is called the ground state of the fluorophore (fluorescent molecule) and S 1 is its first (electronically) excited state.fluorophore

Fluorescence 1- First, absorption must occur at a wavelength long enough to ensure that chemical dissociation does not take place. a-Absorption to unstable state is clearly very unlikely to result in fluorescence. b-Further, in many molecules in which the absorption corresponds to energy greater than the cleavage energy of the least stable bond, no fluorescence is observed. 2-Secondely, intermolecular energy transfer must be relatively slow compared to the rate of radiation. This appears to mean the ISC from S  T must be slow. Geometrical factors such as rigidity and planarity can also affect the efficiency of fluorescence. There are two different types of spectrum discussed. First, obtained by measuring the intensity.

Fluorescence higher energy radiation is absorbed by a species and stored for long enough that the molecules have collided and lost vibrational energy in collisions. When the excited molecule re-emits, the photon is of less energy depending on the species and is therefore of a lower frequency.. Note that Fluorescence is normally emitting from a singlet state whereas phosphorescence (below) occurs from triplet states.

Phosphorescence light is absorbed by a molecule which becomes excited to a higher singlet state. The light can either be re- emitted straight away or (very-rarely), the electron can switch to a triplet state (this is technically forbidden but can happen often enough through a process known as intersystem crossing). Transitions between different multiplicities are forbidden by quantum selection rules and as the ground state of the molecule will often be a singlet state (recall all closed shells are singlets), the molecule is not allowed to emit a photon that will get it directly to the ground state. The molecule must wait a long time (in quantum chemistry) until it can make the forbidden transition.

What is Chemiluminescence? Chemiluminescence is the production of light from a chemical reaction in excess of the black body radiation expected from that body. As such, it is often referred to as “cold light”. Normally, chemiluminescence involves the production of an electronically excited species from a number of reactants which goes on to release visible light in order to revert to its ground state energy.

The mechanism for this reaction is outlined extensively throughout this site but the key difference to note is that no radiation is absorbed – the energy required to emit light comes from the energetics of the chemical reaction. The emission could proceed either from a singlet (fluorescence) or triplet (phosphorescence) state. "Light Sticks" are a popular example of Chemiluminescence

Emission of electromagnetic radiation, usually visible light, caused by excitation of atoms in a material, which then reemit almost immediately (within about 10  8 seconds). The initial excitation is usually caused by absorption of energy from incident radiation or particles, such as X-rays or electrons. Because reemission occurs so quickly, the fluorescence ceases as soon as the exciting source is removed, unlike phosphorescence, which persists as an afterglow. A fluorescent lightbulb is coated on the inside with a powder and contains a gas; electricity causes the gas to emit ultraviolet radiation, which then stimulates the tube coating to emit light. The pixels of a television or computer screen fluoresce when electrons from an electron gun strike them. Fluorescence is often used to analyze molecules, and the addition of a fluorescing agent with emissions in the blue region of the spectrum to detergents causes fabrics to appear whiter in sunlight. X-ray fluorescence is used to analyze minerals.

sensitized and delayed fluorescence. Chemiluminscence Photochemistry in nature Applied Photochemistry