Emerging Trends of Carbon-Based Quantum Dots: Nanoarchitectonics and Applications.

Carbon-based quantum dots (QDs) have emerged as a fascinating class of advanced materials with a unique combination of optoelectronic, biocompatible, and catalytic characteristics, apt for a plethora of applications ranging from electronic to photoelectrochemical devices. Recent research works have established carbon-based QDs for those frontline applications through improvements in materials design, processing, and device stability. This review broadly presents the recent progress in the synthesis of carbon-based QDs, including carbon QDs, graphene QDs, graphitic carbon nitride QDs and their heterostructures, as well as their salient applications. The synthesis methods of carbon-based QDs are first introduced, followed by an extensive discussion of the dependence of the device performance on the intrinsic properties and nanostructures of carbon-based QDs, aiming to present the general strategies for device designing with optimal performance. Furthermore, diverse applications of carbon-based QDs are presented, with an emphasis on the relationship between band alignment, charge transfer, and performance improvement. Among the applications discussed in this review, much focus is given to photo and electrocatalytic, energy storage and conversion, and bioapplications, which pose a grand challenge for rational materials and device designs. Finally, a summary is presented, and existing challenges and future directions are elaborated.

Tuning Phase Transition and Thermochromic Properties of Vanadium Dioxide Thin Films via Cobalt Doping.

Vanadium dioxide (VO2) featuring a distinct thermally triggered phase transition is regarded as the most attractive thermochromic material for smart window applications. However, the high transition temperature (∼67 °C) and moderate luminous transmittance (<50%) of the pristine VO2 circumvent room temperature applications. In this work, epitaxial cobalt-doped VO2 thin films were fabricated to tailor the electric and optical properties on a c-plane sapphire substrate. At the highest doping concentration of 10%, the transition temperature of VO2 is reduced to 44 °C, accompanied by a high luminous transmittance of 79% for single-element Co-doped VO2. The roles of cobalt doping and detailed band variation are fully explained experimentally and by modeling (DFT calculation), respectively. Furthermore, the dramatically increased carrier concentration in cobalt-doped VO2 underscores the promising future of cobalt-doped VO2 unveiled by temperature-dependent Hall effect measurement.

Metal nitride-based nanostructures for electrochemical and photocatalytic hydrogen production.

The over-dependence on fossil fuels is one of the critical issues to be addressed for combating greenhouse gas emissions. Hydrogen, one of the promising alternatives to fossil fuels, is renewable, carbon-free, and non-polluting gas. The complete utilization of hydrogen in every sector ranging from small to large scale could hugely benefit in mitigating climate change. One of the key aspects of the hydrogen sector is its production via cost-effective and safe ways. Electrolysis and photocatalysis are well-known processes for hydrogen production and their efficiency relies on electrocatalysts, which are generally noble metals. The usage of noble metals as catalysts makes these processes costly and their scarcity is also a limiting factor. Metal nitrides and their porous counterparts have drawn considerable attention from researchers due to their good promise for hydrogen production. Their properties such as active metal centres, nitrogen functionalities, and porous features such as surface area, pore-volume, and tunable pore size could play an important role in electrochemical and photocatalytic hydrogen production. This review focuses on the recent developments in metal nitrides from their synthesis methods point of view. Much attention is given to the emergence of new synthesis techniques, methods, and processes of synthesizing the metal nitride nanostructures. The applications of electrochemical and photocatalytic hydrogen production are summarized. Overall, this review will provide useful information to researchers working in the field of metal nitrides and their application for hydrogen production.

Quantum Dot Passivation of Halide Perovskite Films with Reduced Defects, Suppressed Phase Segregation, and Enhanced Stability.

Structural defects are ubiquitous for polycrystalline perovskite films, compromising device performance and stability. Herein, a universal method is developed to overcome this issue by incorporating halide perovskite quantum dots (QDs) into perovskite polycrystalline films. CsPbBr3 QDs are deposited on four types of halide perovskite films (CsPbBr3 , CsPbIBr2 , CsPbBrI2 , and MAPbI3 ) and the interactions are triggered by annealing. The ions in the CsPbBr3 QDs are released into the thin films to passivate defects, and concurrently the hydrophobic ligands of QDs self-assemble on the film surfaces and grain boundaries to reduce the defect density and enhance the film stability. For all QD-treated films, PL emission intensity and carrier lifetime are significantly improved, and surface morphology and composition uniformity are also optimized. Furthermore, after the QD treatment, light-induced phase segregation and degradation in mixed-halide perovskite films are suppressed, and the efficiency of mixed-halide CsPbIBr2 solar cells is remarkably improved to over 11% from 8.7%. Overall, this work provides a general approach to achieving high-quality halide perovskite films with suppressed phase segregation, reduced defects, and enhanced stability for optoelectronic applications.

Optimizing Surface Chemistry of PbS Colloidal Quantum Dot for Highly Efficient and Stable Solar Cells via Chemical Binding.

The surface chemistry of colloidal quantum dots (CQD) play a crucial role in fabricating highly efficient and stable solar cells. However, as-synthesized PbS CQDs are significantly off-stoichiometric and contain inhomogeneously distributed S and Pb atoms at the surface, which results in undercharged Pb atoms, dangling bonds of S atoms and uncapped sites, thus causing surface trap states. Moreover, conventional ligand exchange processes cannot efficiently eliminate these undesired atom configurations and defect sites. Here, potassium triiodide (KI3) additives are combined with conventional PbX2 matrix ligands to simultaneously eliminate the undercharged Pb species and dangling S sites via reacting with molecular I2 generated from the reversible reaction KI3 â‡Œ I2 + KI. Meanwhile, high surface coverage shells on PbS CQDs are built via PbX2 and KI ligands. The implementation of KI3 additives remarkably suppresses the surface trap states and enhances the device stability due to the surface chemistry optimization. The resultant solar cells achieve the best power convention efficiency of 12.1% and retain 94% of its initial efficiency under 20 h continuous operation in air, while the control devices with KI additive deliver an efficiency of 11.0% and retains 87% of their initial efficiency under the same conditions.

Colossal Magnetization and Giant Coercivity in Ion-Implanted (Nb and Co) MoS2 Crystals.

Colossal saturation magnetization and giant coercivity are realized in MoS2 single crystals doped with Nb and/or Co using an ion implantation method. Magnetic measurements have demonstrated that codoping with 2 at % Nb and 4 at % Co invoked a "giant" coercivity, as high as 9 kOe at 100 K. Doping solely with 5 at % Nb induces a "colossal" magnetization of 1800 emu/cm3 at 5 K, which is higher than that of metallic Co. The high magnetization is due to the formation of Nb-rich defect complexes, as confirmed by first-principles calculations. It is proposed that the high coercivity is due to the combined effects of strong directional exchange coupling induced by the Nb and Co doping and pinning effects from defects within the layered structure. This high magnetization mechanism is also applicable to 2D materials with bilayers or few layers of thickness, as indicated by first-principles calculations. Hence, this work opens a potential pathway for the development of 2D high-performance magnetic materials.

Quantum-Dot Tandem Solar Cells Based on a Solution-Processed Nanoparticle Intermediate Layer.

Tandem cells are one of the most effective ways of breaking the single junction Shockley-Queisser limit. Solution-processable phosphate-buffered saline (PbS) quantum dots are good candidates for producing multiple junction solar cells because of their size-tunable band gap. The intermediate recombination layer (RL) connecting the subcells in a tandem solar cell is crucial for device performance because it determines the charge recombination efficiency and electrical resistance. In this work, a solution-processed ultrathin NiO and Ag nanoparticle film serves as an intermediate layer to enhance the charge recombination efficiency in PbS QD dual-junction tandem solar cells. The champion devices with device architecture of indium tin oxide/S-ZnO/1.45 eV PbS-PbI2/PbS-EDT/NiO/Ag NP/ZnO NP/1.22 eV PbS-PbI2/PbS-EDT/Au deliver a 7.1% power conversion efficiency, which outperforms the optimized reference subcells. This result underscores the critical role of an appropriate nanocrystalline RL in producing high-performance solution-processed PbS QD tandem cells.

[Effect of benazepril on the VEGF and MVD in the remnant kidney of 5/6 subtotal nephrectomized rats].

OBJECTIVE: To explore the effect of benazepril (one of angiotesin converting enzymes) on the expression of vascular endothelial growth factor (VEGF) and the change of microvessel density (MVD) in the remnant kidney of rats that undergone 5/6 subtotal nephrectomy (STNx). METHODS: The male Sprague-Dawley (SD) rats were performed 5/6 nephrectomy to produce chronic renal failure, and randomly divided into a model group (STNx group), a STNx combined with benazepril group (Benazepril group), and a sham group that served as normal controls. Pathological changes of the remnant kidney were evaluated at the 8th week after gastric gavage. Immunohistochemistry Methods were used to examine the expression of VEGF and MVD in the remnant kidney, and the correlation was determined between VEGF, MVD and glomerulosclerosis index (GSI), tubulointerstitial score (TIS), BUN, and creatinine (Cr). RESULTS: UP, BUN, Cr, GSI, and TIS significantly decreased in the benazepirl group (P<0.05); and the expression of VEGF and MVD significant increased (P<0.05). The expression of VEGF was positively related to MVD (P<0.05), and there was negative correlation between VEGF, MVD and GSI, TIS, BUN, Cr (P<0.05). CONCLUSION: The decrease of the expression of VEGF and MVD in the remnant kidney may be involved in the progressive remnant kidney fibrosis and renal function. Benazepril can significantly relieve the remnant kidney fibrosis and protect the renal function by increasing the expression of VEGF and MVD in the remnant kidney.

[Intrathecal administration of HSV-I amplicon vector-mediated HPPE gene therapy of nocicepion in rats with formalin pain].

OBJECTIVE: To investigate the antinociceptive effect of intrathecal administration of HSV-I amplicon vector-mediated HPPE. METHODS: Sprague Dawley rats (290+/-30) g were randomly divided into pHSVIRES-HPPE-LacZ (SHPZ) group, pHSVIRES-LacZ (SHZ) group, and saline group (NS), and 3 d, 1 week, 2 weeks, 3 weeks, 4 weeks, and 5 weeks group,which were anesthetized with 10% chlroral hydrate 300- 350 mg/kg. A microspinal catheter was inserted into the lumbar subarachnoid space. Rats were intrathecally delivered with recombinant HSV-I amplicon vector SHPZ, SHZ or NS. The HPPE expression was detected by reverse transcription-polymerase chain reaction (RT-PCR) and radioimmune assay. Formalin 50 microL (5%) was injected into the left hindpaw, pain intensity scoring (PIS) was used to assess the antinociceptive effect. RESULTS: After in vivo transferring,neurocyte demonstrated strong positive signals with X-gal immunohistochemical staining. RT-PCR and L-enkephalin radioimmune assay found that the neural cells transferred foreign gene (HPPE) had effective expression. Intrathecal delivery of SHPZ showed antinociceptive effects on formalin induced pain for 5 weeks compared with SHZ. CONCLUSION: This amplicon virus can transfer HPPE into rat central nerve system neural cells and express efficiently, suggesting SHPZ is satisfactory treatment for gene therapy for chronic pain. Intrathecal delivery SHPZ demonstrated antinociceptive effects on formalin induced pain.