Back Elektrohemiluminiscencija BS Elektrochemilumineszenz German Elektrokimioluminiszentzia Basque Électrochimiluminescence French Elektrokémiai lumineszcencia Hungarian エレクトロケミルミネッセンス Japanese Eletroquimioluminescência Portuguese மின்வேதி ஒளிர்வியல் Tamil Електрохемілюмінесценція Ukrainian 電化學發光 Chinese

Electrochemiluminescence

Electrochemiluminescence or electrogenerated chemiluminescence (ECL) is a kind of luminescence produced during electrochemical reactions in solutions. In electrogenerated chemiluminescence, electrochemically generated intermediates undergo a highly exergonic reaction to produce an electronically excited state that then emits light upon relaxation to a lower-level state. This wavelength of the emitted photon of light corresponds to the energy gap between these two states.[1][2] ECL excitation can be caused by energetic electron transfer (redox) reactions of electrogenerated species. Such luminescence excitation is a form of chemiluminescence where one/all reactants are produced electrochemically on the electrodes.[3]

ECL is usually observed during application of potential (several volts) to electrodes of electrochemical cell that contains solution of luminescent species (polycyclic aromatic hydrocarbons, metal complexes, quantum dots or nanoparticles[4]) in aprotic organic solvent (ECL composition). In organic solvents both oxidized and reduced forms of luminescent species can be produced at different electrodes simultaneously or at a single one by sweeping its potential between oxidation and reduction. The excitation energy is obtained from recombination of oxidized and reduced species.

In aqueous medium, which is mostly used for analytical applications, simultaneous oxidation and reduction of luminescent species is difficult to achieve due to electrochemical splitting of water itself so the ECL reaction with the coreactants is used. In the latter case luminescent species are oxidized at the electrode together with the coreactant which gives a strong reducing agent after some chemical transformations (the oxidative reduction mechanism).

Schematic representation of the "oxidative-reduction" heterogeneous ECL mechanisms for the couple Ru(bpy)32+/TPrA. The ECL generation is obtained only by TPrA oxidation and involving the homogeneous reaction of the radical cation (TPrA°+), as proposed by Bard.[5] The luminophore in the excited state Ru2+* relaxes to the ground state and emits photon. Inset image of electrode surface during an ECL emission [6]
  1. ^ Forster RJ, Bertoncello P, Keyes TE (2009). "Electrogenerated Chemiluminescence". Annual Review of Analytical Chemistry. 2: 359–85. Bibcode:2009ARAC....2..359F. doi:10.1146/annurev-anchem-060908-155305. PMID 20636067.
  2. ^ Valenti G, Fiorani A, Li H, Sojic N, Paolucci F (2016). "Essential Role of Electrode Materials in Electrochemiluminescence Applications". ChemElectroChem. 3 (12): 1990–1997. doi:10.1002/celc.201600602. hdl:11585/591485.
  3. ^ Electrogenerated Chemiluminescence, Edited by Allen J. Bard, Marcel Dekker, Inc., 2004
  4. ^ Valenti G, Rampazzo R, Bonacchi S, Petrizza L, Marcaccio M, Montalti M, Prodi L, Paolucci F (2016). "Variable Doping Induces Mechanism Swapping in Electrogenerated Chemiluminescence of Ru(bpy)32+ Core−Shell Silica Nanoparticles". J. Am. Chem. Soc. 138 (49): 15935–15942. doi:10.1021/jacs.6b08239. hdl:11585/583548. PMID 27960352.
  5. ^ Miao W, Choi J, Bard A (2002). "Electrogenerated Chemiluminescence 69: The Tris(2,2′-bipyridine)ruthenium(II), (Ru(bpy)32+)/ Tri-n-propylamine (TPrA) System RevisitedsA New Route Involving TPrA•+ Cation Radicals". J. Am. Chem. Soc. 124 (48): 14478–14485. doi:10.1021/ja027532v.
  6. ^ Valenti G, Zangheri M, Sansaloni S, Mirasoli M, Penicaud A, Roda A, Paolucci F (2015). "Transparent Carbon Nanotube Network for Efficient Electrochemiluminescence Devices". Chemistry: A European Journal. 21 (36): 12640–12645. doi:10.1002/chem.201501342. PMID 26150130.

Rich TVX News Network Site

Rich TVX News Network Info

© MMXXIII Rich X Search. We shall prevail. All rights reserved. Rich X Search