The progress in nitrides technology is widely believed to be limited and hampered by the lack of high-quality gallium nitride wafers. Though various epitaxial techniques like epitaxial lateral overgrowth and its derivatives have been used to reduce defect density, there is still plenty of room for the improvement of gallium nitride crystal. Here, we report graphene or hexagonal boron nitride nanosheets can be used to improve the quality of GaN crystal using hydride vapor phase epitaxy methods. These nanosheets were directly deposited on the substrate that is used for the epitaxial growth of GaN crystal. Systematic characterizations of the as-obtained crystal show that quality of GaN crystal is greatly improved. The fabricated light-emitting diodes using the as-obtained GaN crystals emit strong electroluminescence under room illumination. This simple yet effective technique is believed to be applicable in metal-organic chemical vapor deposition systems and will find wide applications on other crystal growth.
Background: Primary intracranial leiomyosarcoma (LMS) is a rare tumor of the central nervous system and therefore has only been reported sporadically. Methods: The MEDLINE database was searched for relevant case reports and series published in English from 1969 to March 2012. These papers were reviewed to identify clinical and histopathological features, treatment modalities, and prognoses of patients with primary intracranial LMS. Results: We reviewed 37 patients, including our patient, with primary intracranial LMS. Of these cases, 16 (43.2%) involved immunosuppression, 4 (10.8%) involved radiation-induced LMS, 3 (8.1%) cases involved a potential leiomyosarcomatous transformation of a brain lesion, and 7 (18.9%) cases, including the presented case, had no specific medical history. The treatment for these cases included resection (33/37, 89.2%), postoperative radiotherapy (20/37, 54.1%), and chemotherapy (7/37, 18.9%). Conclusions: The best method for the treatment of LMS could not be determined due to the limited number of cases that have been reported. However, optimized surgical resection, postoperative radiotherapy, and sarcoma-based chemotherapy may improve treatment outcomes.
Obesity is correlated with increased colorectal cancer (CRC) risk, but few studies have investigated lifetime body mass index (BMI) metrics and CRC risk. In a cohort of 139 229 subjects in the Prostate, Lung, Colorectal, and Ovarian (PLCO) Cancer Screening Trial, we analysed the effects of life-course BMI trajectories on CRC risk. At 13 years of follow-up, 2031 subjects developed CRC. Compared with subjects who were never overweight/obese, subjects who first exceeded the threshold of 25 kg m at age 20 had a higher CRC risk (HR = 1.28, 95% confidence interval (CI) = 1.11-1.48). A body weight gain of ≥15 kg between 20 and 50 years of age (HR = 1.34, 95% CI = 1.18-1.52) and baseline (HR = 1.24, 95% CI = 1.08-1.43) was significantly associated with increased CRC risk. BMI trajectory analyses revealed that the CRC risk increased gradually over the three BMI trajectories (HR = 1.11-1.27, P = 0.005) compared with subjects who maintained a normal BMI. Being overweight/obese at the onset of adulthood and BMI trajectories over the lifespan that result in obesity lead to an increased CRC risk.
Single-crystal gallium nitride (GaN) membranes have great potential for a variety of applications. However, fabrication of single-crystalline GaN membranes remains a challenge owing to its chemical inertness and mechanical hardness. This study prepares large-area, free-standing, and single-crystalline porous GaN membranes using a one-step high-temperature annealing technique for the first time. A promising separation model is proposed through a comprehensive study that combines thermodynamic theories analysis and experiments. Porous GaN crystal membrane is processed into supercapacitors, which exhibit stable cycling life, high-rate capability, and ultrahigh power density, to complete proof-of-concept demonstration of new energy storage application. Our results contribute to the study of GaN crystal membranes into a new stage related to the elelctrochemical energy storage application.
The relatively low operating voltage window is the main factor limiting the energy density of aqueous energy storage devices. The delicate design of heterostructured electrode materials can efficiently increase the intrinsic electrochemical performance through synergistic effects. For the first time, to broaden the voltage window of aqueous supercapacitors the synergistic effect between boroncarbonitrides (BCN) and built‐in electric field existing in heterostructures is designed to utilize. Based on this design concept, MnO/MnS@BCN electrode materials are synthesized, in which the synergistic effect can effectively strengthen the storage of electrolyte ions on the electrode surface, thus inhibiting the electrolysis of H2O and eventually broadening the voltage window of aqueous supercapacitor. In MnO/MnS@BCN‐based symmetrical supercapacitors, the voltage window of the device is extended from 1.2 V (single‐component) to 2 V, with the energy density enhanced to 75.0 W h kg−1. The strategy blazes an efficient and convenient path to broaden the intrinsic voltage window of transition metal oxide supercapacitors.
Lithium-ion
capacitors (LICs) have emerged as attractive energy
storage devices to bridge the gap between lithium-ion batteries and
supercapacitors. While the distinct charge storage kinetics between
the anode and the cathode is still a challenge to the widespread application
of LICs, the key to improving the energy density of these devices
is to widen the operating voltage window and balance the mismatch
of the electrode kinetics. To this end, we propose a strategy based
on electrostatic attraction by adjusting the B and N atom contents
of boron carbonitride (BCN) electrode materials to alter their electronegativities
and successfully prepared B-rich and N-rich BCN nanotubes (BCNNTs)
via a facile solid-phase synthesis approach. The B-rich BCN (B-BCN)
cathode and N-rich BCN (N-BCN) anode noticeably enhance the adsorption
of anions and cations, promoting a matching degree between the anode
and cathode. In particular, the rationally designed B-BCN//N-BCN LIC
achieves a maximum voltage range of 4.8 V, setting a new record for
LICs. Furthermore, the energy density reaches up to 200 Wh kg–1 (based on the total mass of cathodic and anodic active
materials). Density functional theory calculations provided insight
into the mechanism underlying our strategy of widening the voltage
range. Our philosophy provides new design guidelines and alternatives
for identifying and optimizing high-performance electrodes for energy
storage devices.
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