High-performance polymer electrolyte membranes incorporated with 2D silica nanosheets in high-temperature proton exchange membrane fuel cells

Silica nanosheets(SN)derived from natural vermiculite(Verm)were successfully incorporated into polyethersulfone-polyvinylpyrrolidone(PES-PVP)polymer to fabricate high-temperature proton exchange membranes(HT-PEMs).The content of SN filler was varied(0.1-0.75 wt%)to study its influence on proton conductivity,power density and durability.Benefiting from the hydroxyl groups of SN that enable the formation of additional proton-transferring pathways,the inorganic-organic membrane displayed enhanced proton conductivity of 48.2 mS/cm and power density of 495 mW/cm^(2) at 150℃ without humidification when the content of SN is 0.25 wt%.Furthermore,exfoliated SN(E-SN)and sulfonated SN(S-SN),which were fabricated by a liquid-phase exfoliation method and silane condensation,respectively,were embedded in PES-PVP polymer matrix by a simple blending method.Due to the significant contribution from sulfonic groups in S-SN,the membrane with 0.25 wt%S-SN reached the highest proton conductivity of51.5 mS/cm and peak power density of 546 mW/cm^(2) at150℃,48%higher than the pristine PES-PVP membranes.Compared to unaltered PES-PVP membrane,SN added hybrid composite membrane demonstrated excellent durability for the fuel cell at 150℃.Using a facile method to prepare 2D SN from natural clay minerals,the strategy of exfoliation and functionalization of SN can be potentially used in the production of HT-PEMs.

Recent advances in phosphoric acid-based membranes for high-temperature proton exchange membrane fuel cells

High-temperature proton exchange membrane fuel cells(HT-PEMFCs)are pursued worldwide as efficient energy conversion devices.Great efforts have been made in the area of designing and developing phosphoric acid(PA)-based proton exchange membrane(PEM)of HT-PEMFCs.This review focuses on recent advances in the limitations of acid-based PEM(acid leaching,oxidative degradation,and mechanical degradation)and the approaches mitigating the membrane degradation.Preparing multilayer or polymers with continuous network,adding hygroscopic inorganic materials,and introducing PA doping sites or covalent interactions with PA can effectively reduce acid leaching.Membrane oxidative degradation can be alleviated by synthesizing crosslinked or branched polymers,and introducing antioxidative groups or highly oxidative stable materials.Crosslinking to get a compact structure,blending with stable polymers and inorganic materials,preparing polymer with high molecular weight,and fabricating the polymer with PA doping sites away from backbones,are recommended to improve the membrane mechanical strength.Also,by comparing the running hours and decay rate,three current approaches,1.crosslinking via thermally curing or polymeric crosslinker,2.incorporating hygroscopic inorganic materials,3.increasing membrane layers or introducing strong basic groups and electron-withdrawing groups,have been concluded to be promising approaches to improve the durability of HT-PEMFCs.The overall aim of this review is to explore the existing degradation challenges and opportunities to serve as a solid basis for the deployment in the fuel cell market.

Graphene/carbon structured catalyst layer to enhance the performance and durability of the high-temperature proton exchange membrane fuel cells

In this study,nitrogen doped electrochemically exfoliated reduced graphene oxide and carbon black supported platinum(Pt/Nr EGO_(2)-CB_(3))has been prepared to enhance the performance and durability of hightemperature PEMFCs with lower Pt loading.On the one hand,Pt/Nr EGO_(2)-CB_(3)with the strong interaction between the Pt and nitrogen(N)prevent agglomeration of Pt particles and Pt particles is 5.46±1.46 nm,which is smaller than that of 6.78±1.34 nm in Pt/C.Meanwhile,ECSA of Pt/Nr EGO_(2)-CB_(3)decrease 13.65%after AST,which is much lower than that of 97.99%in Pt/C.On the other hand,the Nr EGO flakes in MEAac act as a barrier to mitigate phosphoric acid redistribution,which improves the formation of triple-phase boundaries(TPBs)and gives stable operation of the MEAacwith a lower decay rate of 0.02 mV h^(-1)within100 h.After steady-state operation,the maximum power density of Pt/Nr EGO_(2)-CB_(3)(0.411 W cm^(-2))is three times higher than that of conventional Pt/C(0.134 W cm^(-2))in high-temperature PEMFCs.After AST,the mass transfer resistance of Pt/Nr EGO_(2)-CB_(3)electrode(0.560Ωcm^(2))is lower than that in Pt/C(0.728Ωcm^(2)).

Correlation between hydration properties and electrochemical performances on Ln cation size effect in layered perovskite for protonic ceramic fuel cells

PrBa_(0.5)Sr_(0.5)Co_(1.5)Fe_(0.5)O_(5+δ)(PrBSCF) has attracted much research interest as a potential triple ionic and electronic conductor(TIEC) electrode for protonic ceramic fuel cells(PCFCs). The chemical formula for Pr BSCF is AA'B_(2)O_(5+δ), with Pr(A-site) and Ba/Sr(A'-site) alternately stacked along the c-axis. Due to these structural features, the bulk oxygen ion diffusivity is significantly enhanced through the disorder-free channels in the PrO layer;thus, the A site cations(lanthanide ions) play a pivotal role in determining the overall electrochemical properties of layered perovskites. Consequently, previous research has predominantly focused on the electrical properties and oxygen bulk/surface kinetics of Ln cation effects,whereas the hydration properties for PCFC systems remain unidentified. Here, we thoroughly examined the proton uptake behavior and thermodynamic parameters for the hydration reaction to conclusively determine the changes in the electrochemical performances depending on LnBa_(0.5)Sr_(0.5)Co_(1.5)Fe_(0.5)O_(5+δ)(LnBSCF,Ln=Pr, Nd, and Gd) cathodes. At 500 ℃, the quantitative proton concentration of PrBSCF was 2.04 mol% and progressively decreased as the Ln cation size decreased. Similarly, the Gibbs free energy indicated that less energy was required for the formation of protonic defects in the order of Pr BSCF < Nd BSCF < Gd BSCF. To elucidate the close relationship between hydration properties and electrochemical performances in LnBSCF cathodes, PCFC single cell measurements and analysis of the distribution of relaxation time were further investigated.

Effects of Sc doping on electrical conductivity of BaZrO_3 protonic conductors

BaZr1-xScxO3-0.5x (x=0.07,0.10,0.13,0.16) powders were prepared by solid-state reaction method,and ZnO was used as sintering aid.Samples with different amount of ZnO additive were sintered at 1450·C for 6 h in air.Single cubic perovskite phase proton conductors were obtained.Conductivity was measured by electrochemical workstation.It was shown that Sc doping could increase conductivity through enhancing the carrier concentration in the material,but excessive Sc content might decrease the carrier concentration because of its charge compensation.ZnO had an influence on carrier concentration and mobility and affected the electrical conductivity.2 mol% ZnO and 13 mol% ScO1.5 doped sample showed the highest DC conductivity of 3.6×10-3 S·cm-1 tested at 800·C in wet hydrogen atmosphere.

Application of protonic conductors in metallurgy

Two types of disposable EMF hydrogen sensors for measurements ofsolute contents of liquid metals in situ in metal-refining processesand their general principles are introduced. The way to design newelectrochemical sensors and the direction to develop new protonicconductors as new electrochemical sensors are discussed. Thefeasibility of protonic conductors worked as hydrogen pump innon-ferrous metal refining processes is discussed as well.

Low-voltage antimony-doped SnO_2 nanowire transparent transistors gated by microporous SiO_2-based proton conductors

A battery drivable low-voltage transparent lightly antimony（Sb）-doped SnO2 nanowire electric-double-layer （EDL） field-effect transistor （FET） is fabricated on an ITO glass substrate at room temperature. An ultralow operation voltage of 1 V is obtained on account of an untralarge specific gate capacitance （- 2.14 μF/cm2） directly bound up with mobile ions-induced EDL （sandwiched between the top and bottom electrodes） effect. The transparent FET shows excellent electric characteristics with a field-effect mobility of 54.43 cm2/V. s, current on/off ration of 2 × 104, and subthreshold gate voltage swing （S = dVgs/d（logIds）） of 140 mV/decade. The threshold voltage Yth （0.1 V） is estimated which indicates that the SnO2 namowire transistor operates in an n-type enhanced mode. Such a low-voltage transparent nanowire transistor gated by a microporous SiO2-based solid electrolyte is very promising for battery-powered portable nanoscale sensors.

离子导体电解质的研究进展

传统固体氧化物燃料电池(SOFC)由阴极、阳极和电解质三部分组成。电解质作为SOFC的重要组成部分是离子传输的主要通道。开发具有高离子传导性的电解质是使电池获得良好性能的关键。目前电解质的研究主要集中在氧离子导体、质子导体和混合离子导体三大类。简述了近些年这三类电解质材料的研究进展,综合目前发展低温固体氧化物燃料电池的趋势,对未来电解质的发展前景进行了展望。

含孤立四面体基元的AMO_(4)型质子导体的研究进展

AMO_(4)(A=稀土元素,M=Nb,P,As,V…)氧化物因结构中含有灵活旋转和易变形的孤立MO 4四面体结构基元,有利于氧和质子的稳定和离子的长程迁移,是良好的无机固态离子导体候选体系。根据载流子种类可将无机固态离子导体主要分为氧离子导体和质子导体,与氧离子导体相比,质子导体具有较低的迁移能垒。本文首先概述了AMO_(4)型质子导体的晶体结构、导电性与受体掺杂剂对质子导电性的影响,以及部分结构中质子缺陷的稳定形式与离子迁移机制;然后总结了影响AMO_(4)型质子导体导电性、质子稳定及迁移的关键因素,包括A位和M位阳离子尺寸、MO 4四面体的畸变程度和相邻MO 4四面体氧离子之间的距离等;最后展望了AMO_(4)型质子导体未来的发展方向。

基于BaCo_(0.4)Fe_(0.4)Zr_(0.1)Y_(0.1)O_(3-δ)空气电极的可逆质子陶瓷膜电池性能研究

采用柠檬酸络合-硝酸盐燃烧法合成的BaCo_(0.4)Fe_(0.4)Zr_(0.1)Y_(0.1)O_(3-δ)(BCFZY)作为空气电极材料,组装了燃料电极支撑的可逆质子陶瓷膜电池(R-HCMC),并且探讨了单电池在不同工作模式下的电化学性能。结果表明:在900℃下合成的BCFZY表现为单一立方钙钛矿结构,在700℃燃料电池模式下,单电池最大输出功率为424.7 mW·cm^(-2)、最低的极化阻抗为0.23Ω·cm^(2);在电解模式下,电解电压为1.4 V时,最大电流密度为1084 mW·cm^(-2)、氢气产率为3.1 mL·min^(-1)·cm^(-2)。说明,BCFZY空气电极在中低温条件下表现出良好的电催化活性和结构与性能稳定性。

SYNTHESIS AND CHARACTERIZATION OF HYBRID PROTON CONDUCTING MEMBRANES OF POLY(VINYL ALCOHOL) AND PHOSPHOMOLYBDIC ACID

Hybrid proton conducting membranes of poly（vinyl alcohol） （PVA） and phosphomolybdic acid （PMA） were prepared by solution casting method. The effect of PMA doping and PVA crosslinking density on the membrane properties and proton conductivity were investigated. The crosslinking reaction between the hydroxyl group of PVA and the aldehyde group of glutaraldehyde （GA） was characterized by IR spectroscopy. Proton conductivity of the membranes increases with an increase in concentration of the doped PMA and also with an increase in crosslinking density of the membranes. Proton conductivity results indicate that a significant amount of PMA was maintained in the membranes even after several hours of immersion in water. A maximum conductivity of 0.0101 S cm^-1 was obtained for the membrane with 33.3 wt% PMA and crosslinking density of 5.825 mol%. X-ray diffraction studies were carried out to investigate the influence of PMA doping and crosslinking density on the nature of the membranes. These properties make them very good candidates for polymer electrolyte membranes for direct methanol fuel cell application.

Collagen-Based Fuel Cell and Its Proton Transfer

We have fabricated the fuel cell based on the tissue derived biomaterial “collagen” and investigated its proton transfer. It was found that “collagen” becomes the electrolyte of fuel cell in the humidified condition. The power density of the fuel cell becomes typically 8.6 W/m2 in the 80% humidity. Further, these results indicate that collagen exhibits proton conductivity in the humidified condition. Both of proton conductivity and dielectric constant increase by the increase of humidity. From the analyses of the frequency dependence of AC conductivity, it was found that proton conductivity and the dielectric dispersion observed in the humidified condition are caused by the formation of the water bridge, which is bonded with the collagen peptide chain. Considering that hydration induces the formation of the water bridge and that increases proton conductivity and dielectric constant, it is deduced that proton transfer in the fuel cell based on collagen is caused by the breaking and rearrangement of hydrogen bond in the water bridge.

BaZr_(0.9)Y_(0.1)O_(2.95)/Na_2SO_4 Composite with Enhanced Protonic Conductivity

Heterogeneous composite BaZr0.9Y0.1O2.95/Na2SO4 was designed and fabricated with Y-doped BaZrO3 as matrix and Na2SO4 as dispersant by conventional powder processing to improve the total conductivity of barium zirconate. The electrical conduction of the composite was studied by electrical and electrochemical methods. Microstructure of the heterogeneous composite was examined by SEM. The experimewtal results show that the protonic conductivity of Y-doped BaZrO3 is greatly improved upon incorporating Na2SO4 in the material. Microstructure observation indicates that a multiphase structure with Na2SO4 disperses at the grain boundaries of BaZr0.1Y0.9O2.95. Electromotive force （EMF） measurements under fuel cell conditions reveal that the total ionic transport number of the composite is more than 0.9 at 750 ℃.

Anomalous Proton Conductivity in Chitin-Chitosan Mixed Compounds

In order to investigate a key factor for the appearance of proton conductivity in chitin-chitosan mixed compounds, the chitin-chitosan mixed compounds (chitin)x(chitosan)1-x were prepared and these proton conductivities have been investigated. DC proton conductivity σ is obtained from Nyquist plot of impedance measurement data, and the relationship between σ and mixing ratio x has been made clear. It was found that the x dependence of σ is non-monotonous. That is, σ shows the anomalous behavior, and has peaks around x = 0.4 and 0.75. This result indicates that there exist optimal conditions for the realization of high-proton conductivity in the chitin-chitosan mixed compound in which the number of acetyl groups is different. From the FT-IR measurement, we have found that the behavior of proton conductivity in (chitin)x(chitosan)1-x is determined by the amount of water content changed by x. Using these results, proton conductivity, which is important for the application of conducting polymers in chitin-chitosan mixed compounds, will be able to be easily controlled by adjusting the mixing ratio x.

Chitin Based Fuel Cell and Its Proton Conductivity

We have fabricated a fuel cell based on the tissue-derived biomaterial “chitin”, and investigated its proton conductivity. It was found that chitin becomes the electrolyte of the fuel cell in the humidified condition, and power density of the fuel cell using chitin electrolyte becomes typically 1.35 mW/cm2 at the 100% relative humidity. This result is the first result showing that the polysaccharide obtained from nature becomes the fuel cell electrolyte. Moreover, this result indicates that chitin is proton conductor in the humidified condition. In the chitin sheet plane, proton conductivity in chitin is observed approximately 0.1 S/m. Further, it was also found that chitin has the anisotropic proton conductivity. The proton conductivity along the chitin fiber direction is higher than that perpendicular to the chitin fiber direction. From these results, it is deduced that the formation of water bridges accompanied by hydration plays an important role in the appearance of proton conductivity in chitin.

质子导体陶瓷膜用于氢分离的研究进展

氢气因来源广、能量密度高和无污染等优点,有望成为未来的主要绿色燃料之一。发展“氢经济”需要建立生产、提纯、储存、利用和回收等完整的技术与产业链,其中,从含氢混合气中提纯氢气仍具挑战性,特别是从含碳的稀释氢混合气中提纯氢气。与传统的氢气分离技术相比,质子导体陶瓷氢分离膜因具有耗能低、稳定性良好、机械强度高、操作简单和膜材料便宜等众多优点而备受关注。质子导体陶瓷氢分离膜技术作为“下一代”的氢分离技术,在氢气纯化市场中显示出了巨大的应用潜力。综述了钙钛矿基质子导体的传输机制、陶瓷氢分离膜的工作原理及研究进展,并对氢泵、单相质子导体陶瓷氢分离膜和双相质子导体陶瓷氢分离膜进行了讨论和总结。最后,对质子导体陶瓷氢分离膜的挑战和未来发展方向进行了阐述和分析。

Yb掺杂CaZrO_(3)质子导体中氢扩散系数的确定

为研究Yb掺杂CaZrO_(3)体系质子导体的物化性能,以分析纯CaCO_(3),ZrO_(2)及Yb_(2)O_(3)为原料,经固相反应法在1873 K温度下烧结10h制备得到了Yb掺杂CaZrO_(3)质子导体电解质。利用电化学工作站分别测试了5%H_(2)O-95%N_(2)和5%D_(2)O(重水)-95%N_(2)气氛中电解质的阻抗,并获得了电阻弛豫曲线。采用自行设计的数学算法和计算机程序确定了不同温度下氢在电解质试样中的化学扩散系数。计算结果表明,在1073~1373K温度下,CaZr_(0.85)Yb_(0.15)O_(3)-α电解质中氢的化学扩散系数为1.24×10^(-6)~2.23×10^(-6)cm^(2)/s;而CaZr_(0.8)Yb_(0.2)O_(3-α)中氢的化学扩散系数为1.47×10^(-6)~6.67×10^(-6)cm^(2)/s。氢化学扩散系数与温度的关系式分别为D_(H)=1.60×10^(-5)e^(-22499/RT)和D_(H)=1.22×10^(-3)e^(-59509/RT),而对应的扩散激活能分别为0.62和0.23 eV。

探究Mg掺杂对Al_(2)O_(3)质子导体电化学性能的影响

为了进一步系统研究Al_(2)O_(3)基质子导体的电化学性能,通过传统高温固相法在1873 K烧结10 h成功制备Al_(2-x)Mg_(x)O_(3-δ)系列固体氧化物电解质试样。XRD和SEM测试结果表明,Al_(2-x)Mg_(x)O_(3-δ)系列电解质均已成功制备,同时该电解质晶粒尺寸均一,相对致密度均高于97%。在1173~1373 K富氢气大气环境中,Al_(2-x)Mg_(x)O_(3-δ)总电导率为3.1×10^(-5)~7.5×10^(-2)S·cm^(-1),导电活化能最低为0.49 eV。在1173~1323 K的温度范围内H/D同位素效应测试结果表明,质子作为主要载流子参与导电过程。同时在这一温度范围内,电动势测试结果表明,其质子转移数均高于97%。当温度高于1323 K且在富氧气大气环境中时,电子也将变为主要导电载流子参与导电过程。另外,在1173~1373 K范围内,Al_(2-x)Mg_(x)O_(3-δ)的化学扩散系数为3.4×10^(-7)~9.7×10^(-6)cm^(2)s^(-1)。因此,Al_(2-x)Mg_(x)O_(3-δ)系列电解质可以作为氢传感器电解质的代替材料应用于高温电化学装置中。

Structural architectures of polymer proton exchange membranes suitable for high-temperature fuel cell applications

High-temperature proton exchange membrane(HT-PEM)fuel cells offer more advantages than low-temperature PEM fuel cells.The ideal characteristics of HT-PEMs are high conductivities,low-humidity operation conditions,adequate mechanical properties,and competitive costs.Various molecular moieties,such as benzimidazole,benzothiazole,imide,and ether ether ketone,have been introduced to polymer chain backbones to satisfy the application requirements for HT-PEMs.The most common sulfonated polymers based on the main chain backbones have been employed to improve the rties.Side group/chain engineering,including the introduction of SO_(3)^(-) on the side chain,grafting,branching,and crosslinking,has been widely applied to HTPEMs to further improve their proton conductivity,thermal stability,and mechanical properties.Currently,phosphoric acid-doped polybenzimidazole is the most successful polymer material for application in HT-PEMs.The compositing/blending modification methods of polymers are effective in obtaining high PA-doping levels and superior mechanical properties.In this review,the current progress of various membrane materials used for HT-PEMs is summarized.The synthesis and performance characteristics of polymers containing specific moieties in the chain backbones applied to HT-PEMs are discussed systemically.Various modification approaches and their deficiencies associated with HT-PEMs are analyzed and clarified.Prospects and future challenges are also presented.

Non-associative learning behavior in mixed proton and electron conductor hybrid pseudo-diode

With inherent ionic priorities, mixed ion and electron conductor hybrid devices have been proposed for brain-inspired neuromorphic system applications, demonstrating interesting neuromorphic functions. Here, mixed proton and electron conductor (MPEC) hybrid oxide neuromorphic transistor is proposed by adopting aqueous solution-processed mesoporous silica coating (MSC)-based electrolyte as gate dielec- tric. With optical and electrical synergetic coupling behaviors, the device demonstrates typical synap- tic responses and transition between short-term plasticity and long-term plasticity. With unique field- configurable proton self-modulation behaviors, a pseudo-diode operation mode is demonstrated on the MPEC hybrid transistor. Moreover, the device demonstrates interesting non-associative learning, including habituation and sensitization behavior. The results show that the proposed MPEC hybrid oxide neuromor- phic transistor has great potential in the field of neuromorphic engineering and would have potential in the bionic visual perception platform .