气相SiO_(2)复合水凝胶聚合物电解质用于近中性锌-空气电池

近中性锌-空气电池具有对锌负极良好的沉积/剥离相容性和对空气中二氧化碳的化学稳定性,在长循环方面展现出极高的应用前景。然而,液态电解质固有的水分挥发问题和可穿戴设备所需的柔性等需求,限制了这一体系的实际应用。本研究复合了具有高离子电导率和机械强度的聚丙烯酰胺聚合物骨架、具有丰富硅羟基的保水添加剂气相SiO_(2)和对二氧化碳稳定的近中性电解液,制备了气相SiO_(2)复合水凝胶聚合物电解质(SiO_(2)-HPE)。所合成的SiO_(2)-HPE聚合程度高,表面孔道丰富且元素分布均匀。SiO_(2)表面丰富的硅羟基通过改变HPE中的氢键网络,加强了对水分子的束缚,SiO_(2)-HPE因此展现出了良好的保水性、优异的机械性能和较高的离子电导率,是一种理想的柔性锌-空气电池电解质。基于SiO_(2)-HPE组装的近中性锌-空气电池,在相对湿度为30%的条件下,循环寿命可达200 h。此外,基于SiO_(2)-HPE的柔性近中性锌-空气电池器件在弯曲和剪切等特殊条件下都展现出优异的性能,并且可作为电源为不同的用电器供电,是一种极具潜力的下一代电化学储能器件。

Minimally invasive reconstruction of extensive mid-lower ureteral strictures using a bilateral Boari flap

Objective:To describe and evaluate the technique using bilateral Boari flap ureteroneocystostomy(BBFUNC)for bilateral mid-lower ureteral strictures.Methods:We retrospectively reviewed five patients who underwent minimally invasive BBFUNC in our institution(Union Hospital,Wuhan,China)between July 2019 and December 2021.The bilateral ureters were mobilized and transected above the stenotic segments.The bladder was isolated and incised longitudinally from the middle of the anterior wall.Then,an inverted U-shaped bladder flap was created on both sides,fixed onto the psoas tendon,and anastomosed to the ipsilateral distal normal ureter.Following double-J stenting,the Boari flaps were tubularized,and the bladder was closed with continuous sutures.The patients’perioperative data and follow-up outcomes were collected,and a descriptive statistical analysis was performed.Results:No case converted to open surgery,and no intraoperative complication occurred.The median surgical time was 230(range 203-294)min.The median length of the bladder flaps was 6.2(range 4.3-10.0)cm on the left and 5.5(range 4.7-10.5)cm on the right side.All patients had not developed recurrent ureteral stenosis during the median follow-up time of 17(range 16-45)months and had a normal maximum flow rate after surgery.The median post-void residual was 7(range 0-19)mL.The maximal bladder capacity was decreased in one(20%)patient.Conclusion:The present study demonstrates that minimally invasive BBFUNC is feasible and safe in treating is limited.

LightAD: 基于自适应采样的自动去偏框架加速方法

在推荐系统中,由于数据是从用户行为中收集而来而不是通过合理的实验得到,因此偏差问题是普遍存在的。自动去偏框架(AutoDebias)通过采用元学习寻找适当地去偏置配置(即伪标签和置信权重),已被证明是应对各种偏差的一种通用和有效的解决方案。然而,为每个用户-物品对设置伪标签和权重是一个极度耗时的过程。因此,自动去偏框架面临巨大的计算成本,这使其在实际应用中的适用性较差。虽然使用带有均匀采样器的随机梯度下降可以加速模型训练,但这会显著恶化模型的收敛性和稳定性。为了解决这个问题,我们提出了LightAutoDebias (简称LightAD),它为自动去偏框架配备了一种专门的权重采样策略。该采样器可以自适应地和动态地获取信息量更大的训练样本,这带来的收敛性和稳定性比标准的均匀采样器更好。在三个基准数据集上的广泛实验证明,我们的LightAD可以加速自动去偏框架的训练达几个数量级,同时保持几乎相同的精度。

室内植物表型平台及性状鉴定研究进展和展望

植物表型组学研究正逐渐向综合化、规模化、多尺度和高通量的方向快速发展。本文首先介绍了植物表型研究的最新动向。然后针对室内表型监测平台的特点和各类室内表型针对的表型性状进行了系统介绍,包括产量、品质、胁迫抗性(包括干旱、抗冷热、盐胁迫、重金属和病虫害)等。在此基础上,本文还根据通量、传感器集成度和平台大小等把一些国内外流行的室内植物表型平台进行了分类,并介绍了这些室内表型平台在植物研究中的应用情况。同时,本文还介绍了室内表型数据的管理和解析方法。最后,本文着重讨论了室内表型平台的发展方向,并结合中国植物研究的实际情况对表型组学在中国的发展提出了展望,以期为中国植物表型研究提供指导和建议。

Insight into the interaction between Ni-rich LiNi0.8Co0.1Mn0.1O2 cathode and BF4--introducing electrolyte at 4.5V high voltage

Owing to the high specific capacity and high voltage,Ni-rich(LiNi0.8Co0.1Mn0.1O2,LNCM811)cathode has been considered as one of the most promising candidate cathode materials for next generation lithium ion batteries,whereas severe capacity fading greatly hinders its practical application.Notably,the compatibility of Ni-rich materials with LiBF4-containing electrolyte has not yet been realized.Herein,1 M LiPF6-based electrolyte with introducing 2 M LiBF4 is proposed to dramatically improve the cyclic stability of high voltage LNCM811/Li half-cell.Addition of high concentrated LiBF4 improves the moisture stability of electrolyte,which hinders the generation of harmful by-product HF,resulting in improved interfacial stability of LNCM811.Lithium plating/stripping reaction of Li/Li symmetric cell confirms that the enhanced cyclic stability is ascribed to the improved interfacial stability of LNCM811 instead of lithium electrode.Morphology and composition characterization results reveal that LiBF4 participates in the CEI film-forming reaction,resulting in suppressed oxidation of electrolyte and interfacial structural destruction of LNCM811.

Integrated DNA-based/biochemical screening for early diagnosis of multiple endocrine neoplasia type 2A (MEN2A)

Multiple endocrine neoplasia type 2A （MEN2A）, a subtype of MEN2, is characterized by medullary thyroid cancer, pheochromocytoma, and primary hyperparathyroidism. A Han Chinese pedigree with MEN2A was investigated following confirmation of the proband＇s diagnosis by pathological findings and DNA/biochemical screening. DNA samples from 4 other family members were collected and exon 5, 8, 10, 11, 13, 16 and 18 of the RET proto-oncogene were sequenced and then analyzed. A missense mutation of TGG （Trp） to TGC （Cys） at codon 634 （the classic MEN2A mutation） in exon 11 of the RET gene was detected in 3 family members, including the proband. Sequencing data were compared with the human gene mutation database. Elevated serum calcitonin level was detected initially; medullary thyroid carcinoma was revealed in the 3 cases and adrenal pheochromocytoma was also found in the proband. Elective operations were successfully performed on the adrenal and thyroid glands because of pheochromocytoma and medullary thyroid carcinoma. Our case study confirms that integrated DNA-based/biochemical screening is crucial for early diagnosis of MEN2A and is helpful in the screening of their relatives. In addition, DNA-based screening may occasionally uncover a previously unknown RET sequence.

Revealing the critical effect of solid electrolyte interphase on the deposition and detriment of Co(Ⅱ) ions to graphite anode

"Dissolution,migration,and deposition"of transition metal ions (TMIs) result in capacity degradation of lithium-ion batteries (LIBs).Understanding such detrimental mechanism of TMIs is critical to the development of LIBs with long cycle life.In most previous works,TMIs were directly introduced into the electrolyte to investigate such a detrimental mechanism.In these cases,the TMIs are deposited directly on the fresh anode surface.However,in the practical battery system,the TMIs are deposited on the anode covered with solid electrolyte interphase (SEI) film.Whether the pre-presence of SEI film on anode surface influences the deposition and detriment of TMIs is unclear.In this work,the deposition of Co element on graphite anode with and without SEI film were systematically studied.The results clearly show that,in comparison with that of fresh graphite (SEI-free),the presence of SEI film aggravates the deposition of Co ions due to the Li^(+)–Co^(2+) ion exchange between the SEI and Co^(2+)-containing electrolyte without the driving of the electric field,leading to faster capacity fading of graphite anode.Therefore,how to regulate electrolytes and film-forming additives to design the components of SEI and prevent its exchange with TMIs,is a crucial way to inhibit the deposition and detriment of TMIs on graphite anode.

Inhibiting manganese(Ⅱ)from catalyzing electrolyte decomposition in lithium-ion batteries

A once overlooked source of electrolyte degradation incurred by dissolved manganese(Ⅱ)species in lithium-ion batteries has been identified recently.In order to deactivate the catalytic activity of such manganese(II)ion,1-aza-12-crown-4-ether(A12C4)with cavity size well matched manganese(Ⅱ)ion is used in this work as electrolyte additive.Theoretical and experimental results show that stable complex forms between A12C4 and manganese(II)ions in the electrolyte,which does not affect the solvation of Li ions.The strong binding effect of A12C4 additive reduces the charge density of manganese(II)ion and inhibits its destruction of the PF_(6)^(-)structure in the electrolyte,leading to greatly improved thermal stability of manganese(II)ions-containing electrolyte.In addition to bulk electrolyte,A12C4 additive also shows capability in preventing Mn^(2+) from degrading SEI on graphite surface.Such bulk and interphasial stability introduced by A12C4 leads to significantly improved cycling performance of LIBs.

Insight into interactions of olivine-scCO_2-water system at 140C and15 MPa during CO_2 mineral sequestration

CO_2 mineral sequestration(in ultrabasic or basaltic rocks) has been considered as a promising long-term and stable approach to reduce CO_2 in the atmosphere and would counteract the effect of global warming.Meanwhile, clays are widely found in ultrabasic reservoirs. In our study, clays were observed in natural olivine samples, which were used for laboratory experiments in a supercritical CO_2 system at 140C and15 MPa. Initial olivine samples were crushed into two sizes which were large grains of w850-1000 mm and powder particles of w75-150 mm, with the durations of 400 and 1000 h for the powder and grains,respectively. The results showed amorphous silica was newly formed and this passivating layer could mitigate the water-rock interaction to some extent, but it would not play a long-term prohibited effect on secondary mineral carbonate formation as it is a Fe(III) free silica coating. More interestingly, the secondary carbonates were observed to form near the surface sites where locates more clays. Our findings provide insights into the reaction mechanisms of olivine-scCO_2-water interaction process in natural ultrabasic rocks.

C1q/TNF-related protein 1 promotes vasodilatory dysfunctions by increasing arginase 1 activity and uncoupling of endothelial nitric oxide synthase

Objective C1q/TNF-related protein(CTRP)1 was initiallyidentified as a paralog of adiponectin based on the similarity in C1q domain of these two proteins.Previously,we showed that CTRP1promotes the development of atherosclerosis by increasing endothelial adhesiveness.Here,we sought to investigate whether CTRP1 also influences vascular dilatory functions.

Bending and Rolling Shear Properties of Cross-Laminated Timber Fabricated with Canadian Hemlock

In this paper,bending performance and rolling shear properties of crosslaminated timber(CLT)panels made from Canadian hemlock were investigated by varied approaches.Firstly,three groups of bending tests of three-layer CLT panels with different spans were carried out.Different failure modes were obtained:bending failure,rolling shear failure,bonding line failure,local failure of the outer layer and mixed failure mode.Deflection and strain measurements were employed to calculate the global and local modulus of elastic(MOE),compared with the theoretical value.In addition,a modified compression shear testing method was introduced to evaluate the rolling shear strength and modulus,compared with the results from strain measurements in bending shear tests.According to testing results,bonding line failure and rolling shear failure were dominant failure modes in bending tests,and the theoretical value of bending property was beyond the average level of the calculating results obtained from both deflection and strain measurements.In addition,the rolling shear strength and modulus obtained from compression shear tests were relatively smaller than those from bending tests.

C1q/TNF-Related Protein 1 promotes arterial endothelial barrier dysfunction under disturbed flow

Objective Atherosclerotic lesions preferentially occur at branch points of arterial trees where the blood flow is disturbed.Disturbed flow increases endothelial permeability,vascular barrier dysfunction,and finally the development of atherosclerosis.CTRP1,a member of C1q/TNF related protein(CTRP)family,is a novel secreted glycoprotein and its biological functions are largely undefined.

C1q/TNF-related protein 5 promotes atherogenesis by enhancing transcytosis and oxidative modification of low-density lipoprotein through increasing 12/15-lipoxygenase

Objective Increased transcytosis of low-density lipoprotein (LDL)across the endothelium and oxidation of LDL deposited within the subendothelial space are crucial early events in atherogenesis. C1q/TNF-related protein (CTRP) 5 is a novel secreted glycoprotein and its biological functions are largely undefined.

Mechanical Properties of a Eucalyptus-Based Oriented Oblique Strand Lumber for Structural Applications

Wood and wood-based composite materials have gained increasing attention in the sustainable building industry because of their renewability and environmental friendliness.Oriented oblique strand lumber(Eucalyptus Strand Wood,ESWood),which is manufactured from fast-growing small diameter eucalyptus wood(Eucalyptus urophylla×E.grandis),is introduced in this paper.Small clear specimen tests were conducted to determine the mechanical properties of ESWood material while full-scale component tests were performed to observe the structural performance of ESWood beams.A comparison of mechanical properties of ESWood with other wood/bamboo-based materials is then reported.From the results presented herein,it appears that the strength and stiffness properties of ESWood are affected by grain directionality and glued layers.However,it still has preferable mechanical properties as a building material,which is comparable or superior to those of other engineered wood/bamboo-based products(e.g.,Sitka spruce,LVL,OSL,Glulam,and Glubam).Furthermore,results from full-scale component tests show the stable mechanical performance of beams made by ESWood.This study makes a significant contribution to a potential utilization of fast-growing eucalyptus for general use in construction,and the presented mechanical tests results can serve as a fundamental data for more applications of ESWood in practical engineering.

Fission Properties of Neutron-Rich Nuclei around the End Point of r-Process

We studied the fission properties of neutron-rich nuclei278,286Cf around the end point of r-process by microscopic self-consistent approaches. The fission barriers and potential energy surfaces are obtained by constrained static Skyrme Hartree–Fock-BCS calculations. Fission fragments are studied by dynamical time-dependent Hartree–Fock+BCS calculations. Results show that286Cf has an octupole deformation at ground state, which can increase the fission barrier height by 1.1 Me V and enhance significantly the spontaneous fission half-life. To search possible fission channels, dynamical calculations with a broad coverage of initial deformations result in two slightly asymmetric peaks around A=128 and 150 for278Cf, and A=133 and 153 for286Cf. Very asymmetric fission channels as given by semi-empirical models are not found in our results.

Intravenous preemptive analgesia modifies the distribution of lymphocyte subsets after radical mastectomy

Objective: In this study, we evaluated the effect of preemptive analgesia of flurbiprofen axetil (FA) and tramadol on immune response in patients undergoing radical mastectomy. Methods: In this prospective randomized, double-blind, placebo-controlled study, 80 patients were randomly assigned to one of four groups (n = 20). The FA group (group A) patients received FA before tracheal intubation and at the end of surgery. The tramadol group (group B) patients received tramadol before tracheal intubation and at the end of surgery. The control group (group C) patients received saline before tracheal intubation and at the end of surgery. The combination group (group D) patients received FA and tramadol before tracheal intubation and at the end of surgery. Cluster of differentiation and lymphocytes were measured. Results: The CD3, CD4, CD8 and lymphocytes decreased postoperatively of all groups except of group A and D at 0.5 h postoperatively (P < 0.05). The CD3, CD4, CD8 and lymphocytes of group D were higher than those of group C at 0.5 h and 4 h postoperatively (P < 0.05). Conclusion: Preemptive analgesia using flurbiprofen axetil (FA) and tramadol may protect the immune system. The immune protective effect of FA may be better than that of tramadol. The combination of FA and tramadol may be the most effective among all the strategies.

SlZF3 regulates tomato plant height by directly repressing SlGA20ox4 in the gibberellic acid biosynthesis pathway

Plant height is an important target trait for crop genetic improvement.Our previous work has identified a salt-tolerant C2H2 zinc finger,SlZF3,and its overexpression lines also showed a semi-dwarf phenotype,but themolecular mechanism remains to be elucidated.Here,we characterized the dwarf phenotype in detail.The dwarfism is caused by a decrease in stem internode cell elongation and deficiency of bioactive gibberellic acids(GAs),and can be rescued by exogenous GA3 treatment.Gene expression assays detected reduced expression of genes in the GA biosynthesis pathway of the overexpression lines,including SlGA20ox4.Several protein-DNA interaction methods confirmed that SlZF3 can directly bind to the SlGA20ox4 promoter and inhibit its expression,and the interaction can also occur for SlKS and SlKO.Overexpression of SlGA20ox4 in the SlZF3-overexpressing line can recover the dwarf phenotype.Therefore,SlZF3 regulates plant height by directly repressing genes in the tomato GA biosynthesis pathway.

Revisiting the sodium-ion storage capability of hard carbon in carbonate-based electrolytes via a sodium-metal-free protocol

Common evaluation methodology of sodium(Na)-containing two-electrode or three-electrode configurations overlooks the interference from highly reactive Na metal,leading to the underestimation or inconsistent performance of low-potential hard carbon(HC)electrodes.Herein,the trap of Na metal was systematically investigated with or without applied current,uncovering its inadequacy as the reference or counter electrode in different configurations.A Na-metal-free three-electrode protocol is proposed for evaluating the actual Na^(+)-storage capability of the typical low-potential HC electrode.By avoiding Na crosstalk and precisely controlling the working electrode's potential,the actual electrochemical performance of HC in the carbonate esterbased electrolyte can be recognized with high capacity of 222 mAh g^(-1)at 2 C and 113 mAh g^(-1)at 5 C,correcting the misunderstanding of the inferior performance of HC in coin-type half cells(68%and 50%undervaluation at 2 C and 5 C,respectively).The advanced protocol is expected to reduce misunderstandings or underestimation due to evaluation methods and to guide the development of high-performance battery materials.

A weakly-solvated ether-based electrolyte for fast-charging graphite anode

Weakly-solvated electrolytes(WSEs)utilizing solvents with weak coordination ability offer advantages for low-potential graphite anode owing to their facile desolvation process and anions-derived inorganic-rich solid electrolyte interphase(SEI)film.However,these electrolytes face challenges in achieving a balance between the weak solvation affinity and high ionic conductivity,as well as between rigid inorganic-rich SEI and flexible SEI for long-term stability.Herein,we introduce 1,3-dioxolane(DOL)and lithium bis(trifluoromethanesulfonyl)-imide(LiTFSI)as functional additives into a WSE based on nonpolar cyclic ether(1,4-dioxane).The well-formulated WSE not only preserves the weakly solvated features and anion-dominated solvation sheath,but also utilizes DOL to contribute organic species for stabilizing the SEI layer.Benefitting from these merits,the optimized electrolyte enables graphite anode with excellent fast-charging performance(210 mAh/g at 5 C)and outstanding cycling stability(600 cycles with a capacity retention of 82.0%at room temperature and 400 cycles with a capacity retention of 80.4%at high temper-ature).Furthermore,the fabricated LiNi_(0.8)Co_(0.1)Mn_(0.1)O_(2)||graphite full cells demonstrate stable operation for 140 cycles with high capacity retention of 80.3%.This work highlights the potential of tailoring solvation sheath and interphase properties in WSEs for advanced electrolyte design in graphite-based lithium-ion batteries.

Electromagnetic anisotropic homogeneous model for eddy-current field in single-phase wound core

The analysis of the eddy-current field in the wound core widely used in the field of transformer energy conservation is taken as the theme.Adopting the homogenisation idea to consider the unique geometry of the wound core and features of its equivalent multi-stage circular cross-section magnetic boundary,a homogeneous model consisting of a columnar material with continuous homogeneous electromagnetic anisotropy is established by deriving the Maxwell equations of the magnetic quasi-static field in the columnar coordinate system.Finally,a homogeneous fine element model for the eddycurrent field in the wound core is established and the accuracy of the model has been verified by the test platform.The result shows that the homogeneous model can be effectively used for the analysis of the eddy-current field in the wound core,and the error of calculating the eddy-current loss under different excitation conditions is less than 6%under the premise of extremely saving the engineering calculation cost,which will help improve the operational performance of the wound core and contribute to the energysaving goal of the high-voltage equipment.