Photochemical methods time resolution

The conventional flash photolysis setup to study photochemical reactions was drastically improved with the introduction of the pulsed laser in 1970 [17], Soon, nanosecond time resolution was achieved [13], However, the possibility to study processes faster than diffusion, happening in less than 10 10 s, was only attainable with picosecond spectroscopy. This technique has been applied since the 1980s as a routine method. There are reviews covering the special aspects of interest of their authors on this topic by Rentzepis [14a], Mataga [14b], Scaiano [18], and Peters [14c],... 

Photochemical methods offer a convenient tool to study intra- and interprotein ET because of their time resolution and selectivity. Various mechanistic and design approaches based on photochemistry of metal complexes have been undertaken. Most of the studies on protein electron transfer processes have been done for hae-moproteins using among others ruthenium complex as a photosensitizer, modified haemoproteins in which haem iron is substituted by another metal (mainly Zn), and CO-bonded haem proteins [6,7],... 

Sensitivity may also affect the choice of experiment. The concentration of intermediate is frequently too small for detection in static thermal or photochemical reaction systems. Investigations are therefore restricted either to those reactions in which exceptionally high intermediate concentrations are found—for example, in flames—or in systems designed to produce high concentrations. The latter group includes flow systems as well as the non-stationary methods such as flash-photolysis and shock-tube studies. Use of non-stationary methods may itself impose restrictions on the minimum time-resolution of the instrument employed. 

The enhanced signal-to-noise ratio that is provided by resonance enhancement as well as the reduced complexity of the vibrational spectrum make it possible to perform a wide variety of time-resolved studies to determine the structure of the chromophore in the photocycle intermediates. These approaches are discussed in more detail elsewhere in this volume by Kincaid with emphasis on time-resolved Raman studies of heme proteins. Room-temperature flow methods have been extensively used to obtain time-resolved spectra with time resolution ranging from seconds to microseconds.The basic idea is to flow the sample and then introduce an optical pump beam upstream from the probe to initiate the photochemical cycle. Such experiments have been performed on the millisecond and microsecond time scales. For experiments with time resolution faster than microseconds, it is necessary to convert the setup to a two-pulse, pump-probe technique where the time resolution is established by the delay between the pump and probe laser pulses. The time resolution of this approach can be increased to around 1 psec beyond this point increased time resolution will be achieved only with reduced spectral resolution according to the uncertainty principle. 

From the viewpoint of experimental techniques, the major potentialities are now realized for research into CIDNP in photochemical reactions. In this case, time-resolved techniques (so-called flash-CIDNP) are widely used. These techniques utilize laser-pulse photoexcitation with pulse detection of CIDNP effects. The solution of the sensitivity versus time-resolution dilemma stipulates the following restrictions of the attainable time resolution the duration of the detecting radiofrequency pulse should not be shorter than 100 ns, otherwise the sensitivity of the NMR method is lost. Shorter pulses can be employed only to study the processes demonstrating an extreme absolute enhancement coefficient of CIDNP. The latter are characteristic only for a limited number of model... 

A state-of-the-art description of broadband ultrafast infrared pulse generation and multichannel CCD and IR focal plane detection methods has been given in this chapter. A few poignant examples of how these techniques can be used to extract molecular vibrational energy transfer rates, photochemical reaction and electron transfer mechanisms, and to control vibrational excitation in complex systems were also described. The author hopes that more advanced measurements of chemical, material, and biochemical systems will be made with higher time and spectral resolution using multichannel infrared detectors as they become available to the scientific research community. 

In principle, any of the photoproducts shown in Table 4 could have been prepared in enantiomerically pure form by irradiating their achiral precursors in solution to form a racemate and then separating the enantiomers by means of the classical Pasteur resolution procedure [36]. This sequence is shown in the lower half of Fig. 3. The top half of Fig. 3 depicts the steps involved in the solid-state ionic chiral auxiliary method of asymmetric synthesis. The difference between this approach and the Pasteur method is one of timing. In the ionic chiral auxiliary method, salt formation between the achiral reactant and an optically pure amine precedes the photochemical step, whereas in the Pasteur procedure, the photochemical step comes first and is followed by treatment of the racemate with an optically pure amine to form a pair of diastereomeric salts. The two methods are similar in that the crystalline state is crucial to their success. The Pasteur resolution procedure relies on fractional crystallization for the separation of the diastereomeric salts, and the ionic chiral auxiliary approach only gives good ees when the photochemistry is carried out in the crystalline state. 

Quantitative studies of chemotactic signaling require experimental techniques that can expose single cells to chemical stimuli with high resolution in both space and time. Recently, we have introduced the method of flow photolysis (Anal. Chem. 79 3940-3944, 2007), which combines microfluidic techniques with the photochemical release of caged compounds. This method allows us to tailor chemical stimuli on the length scale of individual cells with subsecond temporal resolution. In this chapter, we provide a detailed protocol for the setup of flow photolysis experiments and exemplify this versatile approach by initiating membrane translocation of fluorescent fusion proteins in chemotactic Dictyostdium discoideum cells. 

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