Nanosecond laser flash photolysis kinetic studies

The merocyanine form of numerous BIPS compounds in solution complex with many transition and rare-earth metal ions. The complexation between 6-nitro-8-methoxyBIPS and several ions was studied by spectrophotometric, luminescent, stopped-flow, and nanosecond laser flash photolysis techniques. The absorption maximum of the dye, 580 nm, is shifted to the 480-500 nm region, and the relatively weak fluorescence shows a similar hypsochromic shift. The kinetics of the complexation involved a fast reaction between the components, followed by a slow equilibrium of the complex to its most stable isomer. The photoreactions of the complexes include formation of a short-lived triplet state (lifetime about 2 x 10 5 s,... 

This review summarizes the generation and spectroscopic characterization of alkene radical cations and kinetic and mechanistic studies of their reactions with nucleophiles and cycloaddition chemistry. Most of the data have been obtained using laser flash photolysis techniques, but comparisons with kinetic data obtained using other methods and with steady-state experiments are presented where appropriate. To date most kinetic measurements using laser Hash photolysis techniques have focused on arylalkene radical cations since these are relatively easy to generate and have spectroscopic and kinetic behavior that is commensurate with nanosecond laser flash photolysis techniques. 

The reaction kinetics of the electron transfer from the catalyst to the photogenerated oxidant [Ru(bpy)3] + has been studied by nanosecond laser flash photolysis experiment. The kinetics of the hole scavenging, are pseudo first order when [P u(bpy)3] +] [Ru4(POM)], and are characterized by a bimolecular rate con-... 

Kinetics of the reactions of singlet species 32b in solution at room temperature were studied using time-resolved IR spectroscopy (TRIR) " and nanosecond laser flash photolysis. The absolute rate constants of bimolecular reactions of 32b with... 

All of the molecules in this study have triplet states which are easily detectable by the technique of nanosecond transmission laser flash photolysis. (11) The triplet state of acetoveratrone has a lifetime in excess of 15 ps in ethanol (Figure 2) under conditions of laser excitation the decay involves a mixture of first and second order kinetics, with the latter dominating at high laser powers. This second order decay demonstrates that the triplet state is decaying at least partly by triplet-triplet annihilation. 

Recent laser flash photolysis studies of the kinetics of the process 7 —> 9 suggest that following photoexcitation with time-resolved spectroscopy, an isomer 8 (E form) is formed in the nanosecond or microsecond time domain which undergoes a first-order conversion to the Z form 9.42 43 Details will be published elsewhere. 

Smface modification with ruthenium complexes has proven valuable in studies of both interprotein and intraprotein electron transfer in systems that are difflcult to stndy by traditional kinetic tools. The choice of ruthenium complexes in these investigations stems from an extensive photochemistry as well as exceptional thermal stability. The photochemistry provides a means of examining reactions over a time range of nanoseconds to seconds by laser-flash photolysis and the thermal stability allows researchers to covalently bind a wide variety of complexes to proteins with... 

A number of alkene radical cations have been generated in matrices at low temperature and have also been studied by ESR, CIDNP, and electrochemical methods. However, until recently very little absolute kinetic data have been available for the reactions of these important reactive intermediates in solution under conditions comparable to those used in mechanistic or synthetic studies. In a few cases, competitive kinetic techniques have been used to estimate rates for nucleophilic additions or radical cation/alkene cycloaddition reactions. In addition, pulse radiolysis has been used to provide rate constants for some of the radical cation chemistry relevant to the pho-topolymerization of styrenes. More recently, wc and others have used laser flash photolysis to generate and characterize a variety of alkene radical cations. This method has been extensively applied to the study of other reactive intermediates such as radicals, carbenes, and carbenium ions and is particularly well-suited for kinetic measurements of species that have lifetimes in the tens of nanoseconds range and up and that have at least moderate extinction coeffleients in the UV-visible region. 

Capellos and Suryanarayanan (Ref 28) described a ruby laser nanosecond flash photolysis system to study the chemical reactivity of electrically excited state of aromatic nitrocompds. The system was capable of recording absorption spectra of transient species with half-lives in the range of 20 nanoseconds (20 x lO sec) to 1 millisecond (1 O 3sec). Kinetic data pertaining to the lifetime of electronically excited states could be recorded by following the transient absorption as a function of time. Preliminary data on the spectroscopic and kinetic behavior of 1,4-dinitronaphthalene triplet excited state were obtained with this equipment... 

Chemiluminescence has been used to measure the relative yields of excited ketones formed from self reaction of alkoxyl and alkylperoxyl radical pairs . In the photochemistry of aryl azides a dehydroazepine is detected by time resolved infra red spectroscopy and flash photolysis at room temperature . Singlet and triplet nitrenes and dehydroazepenes have also been detected in the photochemistry of 3- and 4-nitrophenyl azides . Picosecond and nanosecond laser photolysis of p-nitrophenyl acetate in aqueous media produces a triplet state of the -nitrobenzylanion and CO2 after cleavage of the rnr triplet. Absorption, emission, and reaction kinetics of dimethylsilylene produced by flash photolyses of dodecamethylcycloherasilane is another interesting study 2,... 

Flash techniques were originally developed for the study of gas reactions [2,g] but were soon applied to solutions [2,h]. By the mid-60s, apparatus with a time-resolution of a few microseconds, using gas flash-lamps, had come into common use. With such equipment it was possible to identify transient species in solution from their spectra, and to determine their rates of decay and other processes. Excited states became recognised as distinct chemical species. The first study in which the spectra of the initial excited state, of the products and of some radical intermediates, were all detected in solution, and the kinetics investigated, was published in 1958 [2,k], Nanosecond pulses became available after the invention of the laser in 1960, but were not applied in flash photolysis until the problem of synchronising the analysing ( probe ) flash with the initiating ( pump ) flash was solved... 

The conditions which determine whether flash photolysis can be used to smdy a given chemical system are (i) a precursor of the species of kinetic interest has to absorb light (normally from a pulsed laser) (ii) this species is produced on a timescale that is short relative to its lifetime in the system. Current technical developments make it easy to study timescales of nanoseconds for production and analysis of species, and the use of instrumentation with time resolution of picoseconds is already fairly common. In certain specific cases, as we will see in the last part of this chapter, it is possible to study processes on timescales greater than a few femtoseconds. Once the species of interest has been produced, it is necessary to use an appropriate rapid detection method. The most common technique involves transient optical absorption spectroscopy. In addition, luminescence has been frequently used to detect transients, and other methods such as time-resolved resonance Raman spectroscopy and electrical conductivity have provided valuable information in certain cases. 

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