Spiro-based triphenylamine molecule with steric structure as a cathode material for high-stable all organic lithium dual-ion batteries

Redox p-type organic compounds are promising cathode materials for dual-ion batteries.However,the triphenylamine-based polymers usually with agglomerate and intertwined molecular chain nature limit the maximum reaction of their active sites with large-sized anions.Herein,we demonstrate the application of a small molecule with rigid spirofluorene structu re,namely 2,2’,7,7’-tetrakis(diphenylamine)-9,9’-spirobifluorene(Spiro-TAD),as a cathode material for lithium dual-ion batteries.The inherent sterical structure endows the Spiro-TAD with good chemical stability and large internal space for fast diffusion kinetics of anions in the organic electrolyte.As a result,the Spiro-TAD electrode shows significant insolubility and less steric hindrance,and gives a high actual capacity of 109 mA h g^(-1)(active groups utilization ratio approximately 100%) at 50 mA g^(-1)with a high discharge voltage of 3.6 V(vs.Li+/Li),excellent rate capability(60 mA h g^(-1)at 2000 mA g^(-1)) and extremely stable cycling life(98.4% capacity retention after 1400 cycles at 500 mA g^(-1)) in half cells.Such good electrochemical performance is attributed to the robust and rapid adsorption/desorption of ClO4-anions,which can be proved by the in-situ FTIR and XPS.Moreover,an all-organic lithium dual-ion battery(a-OLDIBs) is constructed using the Spiro-TAD as cathode and 3,4,9,10-Perylenetetracarboxylic diimide(PTCDI) as anode and displays long-term cycling performance of 87.5 mA h g^(-1)after 800 cycles.This study will stimulate further developments in designing all organic battery systems.

Theoretical investigation of F-P cavity mode manipulation by single gold nanoparticles

The ability to manipulate microlaser is highly desirable towards high-performance optoelectronic devices.Here we demonstrate feasible mode manipulation of Fabry-Perot type microlasers of a perovskite nanowire via incorporation of single gold nanoparticles.The influences of resonant wavelength,quality factor and emission directions are successively investigated using a two-dimensional finite-difference time-domain method.It is found that blueshift of resonant wavelength could be achieved together with either promoted or degraded quality factor of the microlaser via single Au NPs with varied sizes.Unidirectional emission could also be realized which is favorable for on-chip integration.Our results provide useful reference for feasible manipulation of light-matter interactions and mode selection.

高原地区胃癌的研究进展

胃癌是世界范围内常见的恶性肿瘤之一,且胃癌的病因及危险因素复杂。西藏地区恶性肿瘤死亡率排位与全国大多数省市自治区不同,目前胃癌仍是影响西藏最主要的肿瘤死因。这提示高原环境对胃癌的发病率、死亡率都可能产生影响。本综述结合国内外的研究讨论了高原环境的低氧、辐射以及高原人群为适应这种环境而形成的生活饮食习惯与胃癌发生、发展的关系,回顾国内外关于高原地区胃癌发病率、死亡率的研究现状。当前国内外关于高原地区胃癌人群的临床及基础研究均较为有限,未来仍需更多工作进行深入研究,为西藏高原地区胃癌的防治提供新的思路与方法。

Unit Commitment under the Environment of Wind Power and Large-Scale Bilateral Transactions

Bilateral electric power contract is settled based on contract output curve. This paper considered the bilateral transactions execution, new energy accommodation, power grid security and generation economy, considering the executive priority of different power components to establish a multi-objective coordination unit commitment model. Through an example to verify the effectiveness of the model in promoting wind power consumption, guaranteeing trade execution, and improving power generation efficiency, and analyzed the interactions to each other among the factors of wind power, trading and blocking. According to the results, when wind power causes reverse power flow in the congestion line, it will promote the implementation of contracts, the influence of wind power accommodation to trade execution should be analyzed combined with the grid block, the results can provide reference for wind power planning.

Risks in the Transformation of Scientific and Technological Achievements concerning Tropical Agriculture

The transformation of scientific and technological achievements concerning tropical agriculture has the characteristics of high risk and high return. Based on the characteristics of transformation of scientific and technological achievements concerning tropical agriculture,this paper analyzes the risk factors during the transformation of scientific and technological achievements concerning tropical agriculture. In accordance with the current situation of low transformation rate of scientific and technological achievements concerning tropical agriculture in China,this paper proposes the measures to avoid the risks in the transformation of scientific and technological achievements concerning tropical agriculture and enhance the transformation rate of scientific and technological achievements concerning tropical agriculture.

Day-Ahead Probabilistic Load Flow Analysis Considering Wind Power Forecast Error Correlation

Short-term power flow analysis has a significant influence on day-ahead generation schedule. This paper proposes a time series model and prediction error distribution model of wind power output. With the consideration of wind speed and wind power output forecast error’s correlation, the probabilistic distributions of transmission line flows during tomorrow’s 96 time intervals are obtained using cumulants combined Gram-Charlier expansion method. The probability density function and cumulative distribution function of transmission lines on each time interval could provide scheduling planners with more accurate and comprehensive information. Simulation in IEEE 39-bus system demonstrates effectiveness of the proposed model and algorithm.

大体积微孔和富吡啶氮掺杂的纳米多孔碳高效吸附碘用于高能量密度和长寿命Zn-I_(2)水电池

水系锌碘电池(AZIBs)是一种非常受欢迎的绿色储能技术,但它的能量密度极大地限制了其应用.在此,我们报道了一种高能量密度的可充电AZIBs,通过将高质量碘锚定到具有大微孔体积和富吡啶氮掺杂的独特分级多孔碳中来实现.多孔碳结合了微孔对碘的强约束和氮掺杂对碘的强化学吸附的优点,可使碘的负载量高达61.6 wt%.密度泛函理论计算和实验研究表明,氮掺杂所赋予的丰富活性位点能促进AZIBs的氧化还原动力学,吡啶氮掺杂对AZIBs的吸附可逆转化比普通氮掺杂更有效.高负载碘电极在1.0 C时表现出219.3 mA h g^(-1)的高容量,优异的速率性能,以及优越的循环稳定性,在5.0 C时,循环10,000次内的容量衰减极低,每圈仅为0.00147%.由三节电池串联的初步装置,能量密度高,按电池总质量计算可达72.6 W h kg^(-1),几乎是商用铅酸和镍-镉电池能量密度的两倍.该水系电池的高能量密度和长循环寿命使其在大规模储能应用领域具有巨大潜力.

Sensors-integrated organ-on-a-chip for biomedical applications

As a promising new micro-physiological system,organ-on-a-chip has been widely utilized for in vitro pharmaceutical study and tissues engineering based on the three-dimensional constructions of tissues/organs and delicate replication of in vivo-like microenvironment.To better observe the biological processes,a variety of sensors have been integrated to realize in-situ,realtime,and sensitive monitoring of critical signals for organs development and disease modeling.Herein,we discuss the recent research advances made with respect to sensors-integrated organ-on-a-chip in this overall review.Firstly,we briefly explore the underlying fabrication procedures of sensors within microfluidic platforms and several classifications of sensory principles.Then,emphasis is put on the highlighted applications of different types of organ-on-a-chip incorporated with various sensors.Last but not least,perspective on the remaining challenges and future development of sensors-integrated organ-on-a-chip are presented.

Developing hierarchical microneedles for biomedical applications

As a new kind of microcarrier device,microneedles are featured by micrometer needle arrays with an overall size in the centimeter scale.Due to the needle shape and the micron size,microneedles can penetrate the skin without harming nerves and blood vessels,which causes many advantages such as minimally invasive,safe and convenient.The past few decades have witnessed a great leap in microneedles research.The main materials of microneedles have changed from metal and ceramic to polymers with more complex functions,and the optimiza-tion of materials and preparation strategies has led to a greater variety of microneedle styles.Among them,the construction or combination of smaller size structures or materials on microneedles to fabricate hierarchical mi-croneedles is a major research hotspot.Here,we present the recent research progress of hierarchical microneedles for biomedicine.We begin by discussing the fabrication strategies of hierarchical microneedles,including main-stream casting and coating methods based on microneedle molds and three dimensions(3D)printing methods.We then expand the discussion from the hierarchical microneedles with porous structure to those composited with nanomaterials.Eventually,we have a discussion about the research progress of hierarchical microneedles in the area of biomarkers detection and transdermal drug delivery,as well as its future development direction.

Aquaculture derived hybrid skin patches for wound healing

Natural biomaterials have been widely applied in wound treatment.Hotspots in this area are focused on reducing their immunogenicity and improving their therapeutic effect.In this work,we present a novel aquaculture de-rived hybrid skin patch based on acellular fish skin(AFS)and chitosan(CS)for wound healing.Such functional patch was simply constructed by infiltrating the vascular endothelial growth factor(VEGF)-loaded CS pregel into the porous scaffold of the AFS.As the natural molecules and structure of fish skin are well-retained dur-ing the synthesis processes,the final patch presented brilliant tensile property,water-absorption property,good biocompatibility and low immunogenicity.In addition,the integrated CS and VEGF endow the patch with an-tibacterial and angiogenesis capability respectively for promoting tissue growth and wound healing.Thus,in a full-thickness wound rat model,the hybrid patch has been demonstrated with dramatic therapeutic efficacy in inhibiting inflammatory,accelerating angiogenesis,collagen deposition,and tissue generation during the wound repair procedure.These features imply the practical value of this multifunctional aquaculture derived hybrid skin patch in clinical wound management.

Stratified-structural hydrogel incorporated with magnesium-ion-modified black phosphorus nanosheets for promoting neuro-vascularized bone regeneration

Angiogenesis and neurogenesis play irreplaceable roles in bone repair.Although biomaterial implantation that mimics native skeletal tissue is extensively studied,the nerve-vascular network reconstruction is neglected in the design of biomaterials.Our goal here is to establish a periosteum-simulating bilayer hydrogel and explore the efficiency of bone repair via enhancement of angiogenesis and neurogenesis.In this contribution,we designed a bilayer hydrogel platform incorporated with magnesium-ion-modified black phosphorus(BP)nanosheets for promoting neuro-vascularized bone regeneration.Specifically,we incorporated magnesium-ion-modified black phosphorus(BP@Mg)nanosheets into gelatin methacryloyl(GelMA)hydrogel to prepare the upper hydrogel,whereas the bottom hydrogel was designed as a double-network hydrogel system,consisting of two interpenetrating polymer networks composed of GelMA,PEGDA,andβ-TCP nanocrystals.The magnesium ion modification process was developed to enhance BP nanosheet stability and provide a sustained release platform for bioactive ions.Our results demonstrated that the upper layer of hydrogel provided a bionic periosteal structure,which significantly facilitated angiogenesis via induction of endothelial cell migration and presented multiple advantages for the upregulation of nerve-related protein expression in neural stem cells(NSCs).Moreover,the bottom layer of the hydrogel significantly promoted bone marrow mesenchymal stem cells(BMSCs)activity and osteogenic differentiation.We next employed the bilayer hydrogel structure to correct rat skull defects.Based on our radiological and histological examinations,the bilayer hydrogel scaffolds markedly enhanced early vascularization and neurogenesis,which prompted eventual bone regeneration and remodeling.Our current strategy paves way for designing nerve-vascular network biomaterials for bone regeneration.

E]iomimetic approaches toward smart bio-hybric systems

Bio-integrated materials and devices can blur the interfaces between living and artificial systems. Microfluidics, bioelectronics, and engineered nanostructures, with close interactions with biology at the cellular or tissue levels, have already yielded a spectrum of new applications. Many new designs emerge, including of organ-on-a-chip systems, biodegradable implants, electroceutical devices, minimally invasive neuro-prosthetic tools, and soft robotics. In this review, we highlight a few recent advances of the fabrication and application of smart bio-hybrid systems, with a particular emphasis on the three-dimensional （3D） bio-integrated devices that mimic the 3D feature of tissue scaffolds. Moreover, neurons integrated with engineered nanostructures for wireless neuromodulation and dynamic neural output are briefly discussed. We also discuss the progress in the construction of cell-enabled soft robotics, where a tight coupling of the synthetic and biological parts is crucial for efficient function. Finally, we summarize the approaches for enhancing bio-integration with biomimetic micro- and nanostructures.

Microfluidic electrospray photo-crosslinkable κ-Carrageenan microparticles for wound healing

When organs,especially external organs are injured,pathogens and excessive water loss can threaten the wound healing process and cause local irreversible tissue damage.Here,novel natural κ-Carrageenan microparticles(MPs)able to deliver bioactive proteins and small molecules to the wound surface for promoted regeneration were developed using microfluidic electrospray.The side chains of κ-Carrageenan were modified with methacrylate pendant groups to make the monomer photonic cross-linkable.By changing the concentration of methacrylated-κ-Carrageenan,different porosities of MPs with controllable drug loading were achieved.The size of the MPs can also be tailored by adjusting the voltage of the applied electric field.Vascular endothelial growth factor(VEGF)and antimicrobial peptides Eumenitin were co-loaded into the microparticles(VEGF-Eumenitin-MPs)and released sustainedly in phosphate-buffered saline.The VEGF-Eumenitin-MPs had high biocompatibility and intensive antibacterial activities for bacteria.Furthermore,the antibacterial and angiogenetic properties of the VEGF-Eumenitin-MPs were demonstrated in a infectious wound model and the chronic wound healing process was significantly enhanced in vivo.Therefore,the developed porous MPs with sustained drug release properties have the potential to serve as a platform to deliver bioactive proteins and small molecules to the wound surface for promoted regeneration.