Homogeneous systems for light-driven reduction of protons to H(2) typically suffer from short lifetimes because of decomposition of the light-absorbing molecule. We report a robust and highly active system for solar hydrogen generation in water that uses CdSe nanocrystals capped with dihydrolipoic acid (DHLA) as the light absorber and a soluble Ni(2+)-DHLA catalyst for proton reduction with ascorbic acid as an electron donor at pH = 4.5, which gives >600,000 turnovers. Under appropriate conditions, the precious-metal-free system has undiminished activity for at least 360 hours under illumination at 520 nanometers and achieves quantum yields in water of over 36%.
The photoluminescence from a variety of individual molecules and nanometre-sized crystallites is defined by large intensity fluctuations, known as 'blinking', whereby their photoluminescence turns 'on' and 'off' intermittently, even under continuous photoexcitation. For semiconductor nanocrystals, it was originally proposed that these 'off' periods corresponded to a nanocrystal with an extra charge. A charged nanocrystal could have its photoluminescence temporarily quenched owing to the high efficiency of non-radiative (for example, Auger) recombination processes between the extra charge and a subsequently excited electron-hole pair; photoluminescence would resume only after the nanocrystal becomes neutralized again. Despite over a decade of research, completely non-blinking nanocrystals have not been synthesized and an understanding of the blinking phenomenon remains elusive. Here we report ternary core/shell CdZnSe/ZnSe semiconductor nanocrystals that individually exhibit continuous, non-blinking photoluminescence. Unexpectedly, these nanocrystals strongly photoluminesce despite being charged, as indicated by a multi-peaked photoluminescence spectral shape and short lifetime. To model the unusual photoluminescence properties of the CdZnSe/ZnSe nanocrystals, we softened the abrupt confinement potential of a typical core/shell nanocrystal, suggesting that the structure is a radially graded alloy of CdZnSe into ZnSe. As photoluminescence blinking severely limits the usefulness of nanocrystals in applications requiring a continuous output of single photons, these non-blinking nanocrystals may enable substantial advances in fields ranging from single-molecule biological labelling to low-threshold lasers.
We present the structural and optical characterization of colloidal PbSe nanocrystals. The lowest-energy exciton transitions in these structures, with diameters between 3 and 8 nm, occur at wavelengths between 1.0 and 1.85 µm. Band-edge luminescence spectra with quantum yields as high as 80% are observed. Unexpectedly long (∼300 ns) luminescence lifetimes are observed. These properties are promising for applications in optoelectronics and microscopy.
We have investigated the reaction mechanism responsible for QD nucleation using optical absorption and nuclear magnetic resonance spectroscopies. For typical II-VI and IV-VI quantum dot (QD) syntheses, pure tertiary phosphine selenide sources (e.g. trioctylphosphine selenide (TOPSe)) were surprisingly found to be unreactive with metal carboxylates and incapable of yielding QDs. Rather, small quantities of secondary phosphines, which are impurities in tertiary phosphines, are entirely responsible for the nucleation of QDs; their low concentrations account for poor synthetic conversion yields. QD yields increase to nearly quantitative levels when replacing TOPSe with a stoiciometric amount of a secondary phosphine chalcogenide such as diphenylphosphine selenide. Based on our observations, we have proposed potential monomer identities, reaction pathways and transition states, and believe this mechanism to be universal to all II-VI and IV-VI QDs synthesized using phosphine based methods.The significant potential of semiconductor nanocrystal quantum dots (QDs) for photovoltaics, bio-labeling/imaging, and light-emitting diodes has been well-reported. 1 Unfortunately, realizing this potential has yet to occur, in part due to a synthetic procedure that lacks scalability and high conversion yield. Current syntheses can produce high-quality QDs with respect to photoluminscent quantum yield (QY >50%) and size distribution (± 5%). However, growth temperatures are high (∼300 °C for CdSe), conversion yields are poor (< 2%) and the method suffers from well-known irreproducibilities. 2,3 We suggest that the lack of a rational synthetic mechanism has stalled advancements in QD synthetic design.The essential components in the synthesis of high-quality II-VI and IV-VI QDs have remained largely unchanged for 20 years; typically employing tertiary phosphine We studied reactions performed between high purity tertiary phosphine chalcogenides (e.g. triethylphosphine selenide, triisopropylphosphine selenide and triphenylphosphine selenide) and Pb(oleate) 2 heated to 120 °C, which were monitored by both optical absorption spectroscopy and 31 P NMR. In all casers, no reactivity was observed even after five hours of heating, in stark contrast to commercially obtained trioctylphosphine selenide (TOPSe), which reacts with Pb(oleate) 2 in minutes, forming a dark product. Upon addition of a secondary phosphine (diisopropylphosphine) to high purity tertiary phosphine chalcogenide precursors, reaction rates in all cases accelerated rapidly yielding PbSe QDs. Typical tertiary phosphine sources (tributylphosphine and trioctylphosphine (TOP)) used for QD syntheses are highly impure, and all contain measurable quantities of secondary phosphines (dibutylphosphine ( 31 P δ -69.5 ppm) and dioctylphosphine ( 31 P δ −69.7 ppm) respectively), as shown in the supporting information figures 1 and 2. The importance of secondary phosphines is further emphasized by Figure 1, which shows that growth kinetics and yield for PbSe magic-sized clusters (MS...
Single-molecule fluorescence spectroscopy was used to determine the electronic properties of individual single-walled carbon nanotubes. Carbon nanotube structure was determined simultaneously from Raman spectroscopy. Fluorescence spectra from individual nanotubes with identical structures have different emission energies and linewidths that likely arise from defects or the local environment. Unlike most other molecules studied to date, the fluorescence intensity or spectrum from a single nanotube unexpectedly did not fluctuate.
The use of single wall carbon nanotubes (SWCNTs) in current and future applications depends on the ability to process SWCNTs in a solvent to yield high-quality dispersions characterized by individual SWCNTs and possessing a minimum of SWCNT bundles. Many approaches for the dispersion of SWCNTs have been reported. However, there is no general assessment which compares the relative quality and dispersion efficiency of the respective methods. Herein we report a quantitative comparison of the relative ability of "wrapping polymers" including oligonucleotides, peptides, lignin, chitosan, and cellulose and surfactants such as cholates, ionic liquids, and organosulfates to disperse SWCNTs in water. Optical absorption and fluorescence spectroscopy provide quantitative characterization (amount of SWCNTs that can be suspended by a given surfactant and its ability to debundle SWCNTs) of these suspensions. Sodium deoxy cholate (SDOCO), oligonucleotides (GT)(15), (GT)(10), (AC)(15), (AC)(10), C(10-30), and carboxymethylcellulose (CBMC-250K) exhibited the highest quality suspensions of the various systems studied in this work. The information presented here provides a good framework for further study of SWCNT purification and applications.
Colloidal CdS quantum dots (QDs) were synthesized with tunable surface composition. Surface stoichiometry was controlled by applying reactive secondary phosphine sulfide precursors in a layer-by-layer approach. The surface composition was observed to greatly affect photoluminescence properties. Band edge emission was quenched in sulfur terminated CdS QDs and fully recovered when QDs were cadmium terminated. Calculations suggest that electronic states inside the band gap arising from surface sulfur atoms could trap charges, thus inhibiting radiative recombination and facilitating nonradiative relaxation.
The separate developments of microarray patterning of DNA oligonucleotides, and of DNA hairpins as sensitive probes for oligonucleotide identification in solution, have had a tremendous impact on basic biological research and clinical applications. We have combined these two approaches to develop arrayable and label-free biological sensors based on fluorescence unquenching of DNA hairpins immobilized on metal surfaces. The thermodynamic and kinetic response of these sensors, and the factors important in hybridization efficiency, were investigated. Hybridization efficiency was found to be sensitive to hairpin secondary structure, as well as to the surface distribution of DNA hairpins on the substrate. The identity of the bases used in the hairpin stem as well as the overall loop length significantly affected sensitivity and selectivity. Surface-immobilized hairpins discriminated between two sequences with a single base-pair mismatch with high sensitivity (over an order of magnitude difference in signal) under identical assay conditions (no change in stringency). This represents a significant improvement over other microarray-based techniques.
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