Strain Influences the Hydrogen Evolution Activity and Absorption Capacity of Palladium

Strain engineering can increase the activity and selectivity of an electrocatalyst. Tensile strain is known to improve the electrocatalytic activity of palladium electrodes for reduction of carbon dioxide or dioxygen, but determining how strain affects the hydrogen evolution reaction (HER) is complicated by the fact that palladium absorbs hydrogen concurrently with HER. We report here a custom electrochemical cell, which applies tensile strain to a flexible working electrode, that enabled us to resolve how tensile strain affects hydrogen absorption and HER activity for a thin film palladium electrocatalyst. When the electrodes were subjected to mechanically‐applied tensile strain, the amount of hydrogen that absorbed into the palladium decreased, and HER electrocatalytic activity increased. This study showcases how strain can be used to modulate the hydrogen absorption capacity and HER activity of palladium.     

Dynamics of hot carrier cooling in photo-excited GaAs

Carrier relaxation following excitation with subpicosecond optical pulses, determined from time resolved nearband gap transmission spectrum changes, is described for GaAs. For n < 5×10¹⁷cm^-3 the observed relaxation can be related to carrier-phonon interaction, but at higher densities the rate of relaxation is significantly slowed, possibly due to carrier screening.     

STATE I-STATE II TRANSITIONS IN THE THERMOPHILIC BLUE-GREEN ALGA (CYANOBACTERIUM) Synechococcus lividus*

Time courses of state I-state II transitions were measured in the thermophilic blue-green alga (Cyanobacterium), Synechococcus lividus, that was grown at 55°C. The rate of the state I–II transition using light II illumination was the same as that in the dark, and the dark state was identified to be state II. Therefore, light regulation attained by state transitions is produced by the state II–I transition induced by system I light. The redox level of plastoquinone did not affect this dark state II. Arrhenius plots of the state transitions showed a break point around 43°C that corresponded to the phase transition temperature of this alga. Since both the state I–II and II–I transitions were very much temperature-independent, we could keep the alga in either state for a long time at a “low” temperature such as room temperature. Activities of both photosystems I and II in states I and II were also measured. After a state II–I transition, the system II activity increased about 16% and at the same time, svstem I activity decreased about 30%.     

LIGHT-INDUCED SHIFTS IN THE ABSORPTION SPECTRUM OF CAROTENOIDS IN RED AND BROWN ALGAE

Abstract— Changes in light absorption in the region 450–540 nm were observed upon illumination of the red algae Iridaea splendens, Schizymenia pacifica and Porphyra perforata and the brown alga Pheostrophion irregulare . The difference spectra of these changes in Iridaea and Schizymenia showed maxima and minima at about 465, 480, 495, 515 nm. The spectra were similar to difference spectra earlier observed in photosynthetic bacteria, and the location of the maxima and minima suggested a shift towards longer wavelength of a compound with absorption maxima at about 440, 470, and 500 nm, probably a carotenoid. Similar, but more distorted difference spectra were observed in the other algae. Time courses and size of the signals induced by light of different wavelengths suggest that excitation of both photosynthetic pigment systems causes a shift in carotenoid absorption, with kinetics which appear to be similar to those of the well-known change at 515 nm in green plants.     

ENERGY TRANSFER FROM PHYCOBILINS TO CHLOROPHYLL a IN HEAT-STRESSED CELLS OF Anacystis nidulans: CHARACTERIZATION OF THE LOW TEMPERATURE 683 nm FLUORESCENCE EMISSION BAND*

Abstract— Heat-induced changes of the characteristics of fluorescence spectra of Anacystis nidulans cells were studied after 39°C-grown cells were heated at 55°C. Heat-treatment of the cells induced no changes in the absorption properties or photosystem I-catalyzed cytochrome oxidation, but induced a dramatic change in the fluorescence characteristics of the cells. The low temperature fluorescence emission spectra of heated cells showed a large increase of fluorescence emission at683–685 nm (F683) and at 695 nm, while the bands at 660 nm (allophycocyanin) and at 718 nm (chlorophyll a of photosystem I) were not affected when the cells were excited with light absorbed by phycobilins. When the cells were heated for various periods, a progressive increase of the intensity of F683 occurred with the loss in oxygen evolution capacity. The increase of the F683 band was observed prior to the increase of the F695 band. Quenching of emission spectra by the addition of quinones indicates that the F683 band emanated mainly from a long wavelength form of allophycocyanin. Excitation spectra of heated cells measured at 77 K showed that light absorbed by phycobilins was effective in exciting F685, F695, and F715 emission. A possible energy distribution pathway in Anacystis nidulans is discussed.     

Picosecond dynamics of hot carrier relaxation in highly excited multi-quantum well structures

Dynamics of hot carrier relaxation, exciton screening and subband level renormalization in GaAsAlGaAs multiple quantum well structures are investigated by time resolved measurements of optical absorption and gain following subpicosecond optical excitation. The cooling rate of the electron hole plasma in these two dimensional structures is approximately the same as for bulk GaAs at comparable photoexcitation density.     

DIRECT MEASUREMENT OF PHYTOCHROME PHOTOCONVERSION INTERMEDIATES AT HIGH PHOTON FLUENCE RATES

A custom-built modulated split-beam spectrophotometer has been used to measure the absorbance of tissue samples and purified phytochrome whilst exposing the sample to actinic 633 nm laser radiation at fluence rates approaching those of daylight. This approach has allowed the direct observation of the accumulation of phytochrome photoconversion intermediates at high fluence rates. At ca 1250 μmol m^?2 s^?1 upwards of 35% of the total phytochrome was present in the form of photoconversion intermediates in tissues of maize, sunflower and tomato. In other tissues tested (wheat, bean and Amaranthus) and in purified oat phytochrome, rather smaller levels of intermediates accumulated. Upon “lights-off” only a proportion of the accumulated intermediates decayed to far-red absorbing phytochrome (Pfr), the remainder appearing as the red-absorbing form (Pr). Difference spectra suggested that, at high light levels, Pr may be reformed via a photochemical back-conversion of an intermediate in the Pr—Pfr pathway, although the involvement of intermediates in the Pfr—Pr pathway cannot be excluded. The implications of the results for the ecological function of phytochrome are discussed.