Electrochemical reconstruction of non-noble metal-based heterostructure nanorod arrays electrodes for highly stable anion exchange membrane seawater electrolysis

Direct seawater electrolysis for hydrogen production has been regarded as a viable route to utilize surplus renewable energy and address the climate crisis.However,the harsh electrochemical environment of seawater,particularly the presence of aggressive Cl^(-),has been proven to be prone to parasitic chloride ion oxidation and corrosion reactions,thus restricting seawater electrolyzer lifetime.Herein,hierarchical structure(Ni,Fe)O(OH)@NiCoS nanorod arrays(NAs)catalysts with heterointerfaces and localized oxygen vacancies were synthesized at nickel foam substrates via the combination of hydrothermal and annealing methods to boost seawater dissociation.The hiera rchical nanostructure of NiCoS NAs enhanced electrode charge transfer rate and active surface area to accelerate oxygen evolution reaction(OER)and generated sulfate gradient layers to repulsive aggressive Cl^(-).The fabricated heterostructure and vacancies of(Ni,Fe)O(OH)tuned catalyst electronic structure into an electrophilic state to enhance the binding affinity of hydroxyl intermediates and facilitate the structural transformation into amorphousγ-NiFeOOH for promoting OER.Furthermore,through operando electrochemistry techniques,we found that theγ-NiFeOOH possessing an unsaturated coordination environment and lattice-oxygen-participated OER mechanism can minimize electrode Cl^(-)corrosion enabled by stabilizing the adsorption of OH*intermediates,making it one of the best OER catalysts in the seawater medium reported to date.Consequently,these catalysts can deliver current densities of 100 and 500 mA cm-2for boosting OER at minimal overpotentials of 245and 316 mV,respectively,and thus prevent chloride ion oxidation simultaneously.Impressively,a highly stable anion exchange membrane(AEM)seawater electrolyzer based on the non-noble metal heterostructure electrodes reached a record low degradation rate under 100μV h-1at constant industrial current densities of 400 and 600 mA cm-2over 300 h,which exhibits a promising future for the nonprecious and stable AEMWE in the direct seawater electrolysis industry.

基于可再生能源的水电解制氢技术（英文）

在全球变暖,污染日益严重的今天,发展可再生清洁能源成为了当务之急.然而可再生能源(风能、太阳能)本身具有间断特性,这就需要寻找一种合适的能量媒介储存能量来保证其能源的稳定输出.当前,我国各地不断出现弃风、弃光和弃水电事件,据国家能源局的公开数据,仅2016年,全国弃风电量497×10~8 kW·h,弃光率仅西部地区就已达20%,弃风弃光日臻凸显[1].从地域方面来看,我国光伏发电呈现东中西部共同发展格局,其中,西部地区主要发展集中式光伏发电,新疆、甘肃、青海、宁夏的累计装机容量均超过5×10~6 k W·h,而中东部地区除集中式光伏发电外,还重点建设分布式光伏发电,江苏、浙江、山东、安徽的分布式光伏装机规模已超过100万千瓦.我国光伏发电集中开发的西北地区也存在严重的弃光问题.根据中国光伏行业协会发布的报告,我国的弃光现象主要集中于西北的新疆、甘肃、青海、宁夏和陕西五省区.据统计,2016年,五省区光伏发电量287.17×10~8 k W·h,弃光电量70.42×10~8 k W·h,弃光率为19.81%,各省区光伏发电并网运行数据如表格所示.可以看出,新疆、甘肃光伏发电运行较为困难,弃光电量绝对值高,弃光率分别达到32.23%和30.45%[2].在新能源体系中,氢能是一种理想的二次能源,与其它能源相比,氢热值高,其能量密度(140 MJ/kg)是固体燃料(50MJ/kg)的两倍多.且燃烧产物为水,是最环保的能源,既能以气、液相的形式存储在高压罐中,也能以固相的形式储存在储氢材料中,如金属氢化物、配位氢化物、多孔材料等.对可再生和可持续能源系统,氢气是一种极好的能量存储介质.氢气作为能源载体的优势在于:(1)氢和电能之间通过电解水技术可实现高效相互转换;(2)压缩的氢气有很高的能量密度;(3)氢气具有成比例放大到电网规模应用的潜力.制氢的方式有很多,包括:化石燃料重整、分解、光解或水解等.全球每年总共需要约40亿吨氢气,95%以上的氢气是通过化石燃料重整来获得,生产过程必然排出CO_2,而电解水技术利用可再生能源获得的电能进行规模产氢,可实现CO_2的零排放,可将具有强烈波动特性的风能、太阳能转换为氢能,更利于储存与运输.所存储的氢气可用于燃料电池发电,或单独用作燃料气体,也可作为化工原料.通过水电解方式获得的氢气纯度较高,可达99.9%以上.

自支撑NiFe LDHs@Co-OH-CO_(3)纳米棒阵列电极用于碱性阴离子交换膜电解水

开发高效耐用的电极对碱性阴离子交换膜电解水(AEMWEs)制氢至关重要。在这项研究中,我们展示了一种高效且稳定的自支撑NiFe LDHs@Co-OH-CO_(3)/NF纳米棒阵列电极分别用于析氧反应(OER)和AEMWE的阳极。在这项工作中,我们将2D的镍铁层状双金属氢氧化物纳米片(NiFe LDHs)原位生长在1D的碱式碳酸钴纳米线上(Co-OH-CO_(3)/NF),最终得到独特的纳米棒阵列复合结构电极。在三电极体系中,自支撑NiFe LDHs@Co-OH-CO_(3)/NF对OER具有良好的催化活性,在1 mol·L^(-1)KOH中,当电流密度为20 m A·cm^(-2)时,过电位为215 mV。当自支撑NiFe LDHs@Co-OH-CO_(3)/NF作为AEMWE的阳极(70℃,1 mol·L^(-1)KOH),在电流密度为0.5 A·cm^(-2)时,电解电压为1.72 V,并且具有较好的稳定性。进一步的实验表征结果显示了自支撑NiFe LDHs@Co-OH-CO_(3)/NF的优异性能是其具有特殊的形貌结构。这是由于纳米棒阵列电极的三维分层结构可以有效防止纳米片团聚,从而有利于电子转移,为水分解提供大量的边缘活性位点。

Prognostic values of apoptosis-stimulating P53-binding protein 1 and 2 and their relationships with clinical characteristics of esophageal squamous cell carcinoma patients:a retrospective study

Background: Esophageal squamous cell carcinoma(ESCC) is a leading cause of cancer?related death, and new prognostic biomarkers are urgently needed. Apoptosis?stimulating P53?binding protein 1(ASPP1) and 2(ASPP2) have been reported to play important roles in the development, progression, metastasis, and prognosis of cancers, but their roles in ESCC have not been elucidated. In this study, we examined the expression of ASPP1 and ASPP2 in ESCC to evaluate their prognostic values.Methods: The protein expression of ASPP1, ASPP2, and P53 in 175 specimens of ESCC was detected using immuno?histochemical staining; their expression in cancerous and noncancerous tissues was scored according to the stain?ing intensity and the percentage of stained cells. The associations of ASPP1, ASPP2, and P53 with clinicopathologic parameters, overall survival(OS), and disease?free survival(DFS) were analyzed.Results: The protein expression levels of ASPP2 and P53 were significantly higher in cancerous tissues than in paired noncancerous tissues(P < 0.001), whereas the expression levels of ASPP1 in the two groups were similar. In ESCCs, ASPP1 expression was significantly associated with histological differentiation(P = 0.002) and invasive depth(P = 0.014); ASPP2 expression was associated with age(P = 0.029) and histological differentiation(P < 0.001); and P53 expression was associated with age(P and P53 expression. Survival an= 0.021) and tumor size(P alysis revealed that high AS= 0.040). No correlations were found between ASPP1, ASPP2,PP2 expression was significantly associated with increased 5?year OS(P = 0.001) and DFS rates(P ate of ESCC patients(= 0.010) and that high P53 expression was significantly associated with a reduced 5?year DFS rP atio(HR): 0.541, 9= 0.015). Multivariate Cox analysis indicated that ASPP2 was an inde?pendent predictor of OS [hazard r5% confidence interval(CI) 0.363–0.804] and DFS(HR: 0.599, 95% CI 0.404–0.888) of ESCC patients and that P53 was an independent predictor of DFS(HR: 2.161, 95% CI 1.100–4.245).Conclusions: ASPP1 might be involved in the progression of ESCC, and ASPP2 was a potential prognostic biomarker of ESCC and should be evaluated in future studies.

An effective oxygen electrode based on Ir0.6Sn0.4O2 for PEM water electrolyzers

An effective oxygen evolution electrode with Ir0.6Sn0.4O2 was designed for proton exchange membrane(PEM)water electrolyzers.The anode catalyst layer exhibits a jagged structure with smaller particles and pores,which provide more active sites and mass transportation channels.The prepared IrSn electrode showed a cell voltage of 1.96 V at 2.0 A cm^-2 with Ir loading as low as 0.294 mg cm^-2.Furthermore,Ir Sn electrode with different anode catalyst loadings was investigated.The IrS n electrode indicates higher mass current and more stable cell voltage than the commercial Ir Black electrode at low loading.

Spirolindemers A and B,Lindenane Sesquiterpenoid Oligomers Equipped with Oxaspiro[4.5]decane from Chloranthus henryi

Spirolindemers A and B,unprecedented lindenane sesquiterpenoid dimer(1)and trimer(2)equipped with oxaspiro[4.5]decane unit,were discovered from the medicinal plant Chloranthus henryi.Their structures including absolute configurations were achieved by HRMS,NMR,ECD,X-ray diffraction analyses,and quantum chemical calculations.Biogenetically,hetero-and homo-Diels-Alder additions may dominate the formation of oxaspiro[4.5]decane and spiro[4.5]decane skeletons,respectively.Compound 1 showed anti-inflammatory activity by inhibiting the expression of iNOS and COX-2.

Sarcaglarols A-D, Lindenane-Monoterpene Heterodimers from Sarcandra glabra Based on Molecular Networks

Sarcaglarols A-D(1-4),two pairs of lindenane-monoterpene heterodimers fused by a 1,2-dioxane moiety,were discovered and isolated from the leaves of Sarcandra glabra guided by MS/MS molecular networking-based strategy.Their planar structures,absolute configurations of basic skeleton and flexible polyhydric side chain were established by analysis of HRESIMS,NMR spectroscopic data,ECD spectrum,and the X-ray diffraction study of isopropylidene derivatives.An intermolecular[2+2+2]cycloaddition may play a key role in the biosynthesis pathway of the 1,2-dioxane moiety fused lindenane-monoterpene heterodimer skeleton,which can be recognized as the biogenetic precursors of our previous reported lindenane-normonoterpene conjugates.In addition,compounds 1,3 and 4 exhibited moderate inhibitory effects of lipid accumulation in free fatty acid-exposed L02 cells.