单原子催化剂在便携式能源与传感器技术中的未来发展

doi:10.1016/S1872-2067(25)64814-5

催化学报 ›› 2025, Vol. 78: 100-137.DOI: 10.1016/S1872-2067(25)64814-5

单原子催化剂在便携式能源与传感器技术中的未来发展

赵天佑^a, 胡凤鸣^d, 朱美琦^a, 杨昌杰^b, 汪新宇^b, 潘永周^a^,^*(), 杨嘉睿^c, 张霞^a^,^*(), 李文豪^a^,^e^,^*(), 王定胜^b^,^*()

^a东北大学理学院化学系, 辽宁沈阳 110819
^b清华大学化学系, 北京 100084
^c香港城市大学化学系, 香港 999077
^d澳门大学应用物理与材料工程研究所, 教育部联合重点实验室, 澳门 999078
^e东北大学佛山创新研究生院, 广东佛山 528311

收稿日期:2025-06-09 接受日期:2025-07-25 出版日期:2025-11-18 发布日期:2025-10-14
通讯作者: *电子信箱: panyz0412@163.com (潘永周), xzhang@mail.neu.edu.cn (张霞), liwenhao@mail.neu.edu.cn (李文豪), wangdingsheng@mail.tsinghua.edu.cn (王定胜).
基金资助:
国家自然科学基金(22401038);国家自然科学基金(22325101);国家自然科学基金(22388102);国家自然科学基金(223B2902);国家重点研发计划(2023YFA1506801);北京自然科学基金(Z240027);广东省自然科学基金(2025A1515010830);中央高校基本研究经费(N2405014);中国博士后科学基金(2025M771039);兴辽宁人才计划(XLYC2403076);中国化学会青年科学家资助项目.

Future development of single-atom catalysts in portable energy and sensor technologies

Tianyou Zhao^a, Fengming Hu^d, Meiqi Zhu^a, Chang-Jie Yang^b, Xin-Yu Wang^b, Yong-Zhou Pan^a^,^*(), Jiarui Yang^c, Xia Zhang^a^,^*(), Wen-Hao Li^a^,^e^,^*(), Dingsheng Wang^b^,^*()

^aDepartment of Chemistry, Northeastern University, Shenyang 110819, Liaoning, China
^bDepartment of Chemistry, Tsinghua University, Beijing 100084, China
^cDepartment of Chemistry, City University of Hong Kong, 83 Tat Chee Avenue, Kowloon, 999077 Hong Kong, China
^dJoint Key Laboratory of the Ministry of Education, Institute of Applied Physics and Materials Engineering, University of Macau, Avenida da Uniyersidade, Taipa, Macau 999078, China
^eFoshan Graduate School of Innovation, Northeastern University, Foshan 528311, Guangdong, China

Received:2025-06-09 Accepted:2025-07-25 Online:2025-11-18 Published:2025-10-14
Contact: *E-mail: panyz0412@163.com (Y.-Z. Pan), xzhang@mail.neu.edu.cn (X. Zhang), liwenhao@mail.neu.edu.cn (W.-H. Li), wangdingsheng@mail.tsinghua.edu.cn (D. Wang).
About author:Yong-Zhou Pan obtained his B.S. degree in 2019 from Gannan Normal University. His Ph.D. degree in 2024 from Guangxi Normal University. Then, he conducted postdoctoral research at Northeastern University. His research interests primarily focus on the applications of single-atom materials in energy storage and conversion.
Xia Zhang received her B.S. degree in 1993 and M.S. degree in 1996 from Beijing Normal University, and her Ph.D. degree in 2004 from Northeastern University. Since 1996, she has been dedicated to the research of inorganic functional nanomaterials, inorganic-organic hybrid materials, and nanometallic materials, with an emphasis on their synthesis, performance optimization, and mechanistic investigation.
Wen-Hao Li obtained his B.S. degree in 2017 from Sichuan Normal University and his M.S. degree in 2020 from Guangxi Normal University. He received his Ph.D. under the supervisor of Prof. Dingsheng Wang in the Department of Chemistry, Tsinghua University. Then, he joined the faculty of College of Science, Northeastern University. His research interests are focused on the rational design, accurate synthesis, and application of single-atom and cluster catalysts.
Dingsheng Wang received his B.S. degree from the Department of Chemistry and Physics, University of Science and Technology of China in 2004, and his Ph.D. degree from the Department of Chemistry, Tsinghua University in 2009 under the supervision of Prof. Yadong Li. He did his postdoctoral research at the Department of Physics, Tsinghua University, with Prof. Shoushan Fan. Then, he joined the faculty of the Department of Chemistry, Tsinghua University in 2012. His research interests focus on the synthesis and applications of nanomaterials, clusters, and single-atom catalysts.
Supported by:
National Natural Science Foundation of China(22401038);National Natural Science Foundation of China(22325101);National Natural Science Foundation of China(22388102);National Natural Science Foundation of China(223B2902);National Key R&D Program of China(2023YFA1506801);Beijing Natural Science Foundation(Z240027);Natural Science Foundation of Guangdong Province(2025A1515010830);Fundamental Research Funds for the Central Universities(N2405014);China Postdoctoral Science Foundation(2025M771039);Liaoning Revitalization Talents Program(China);Liaoning Revitalization Talents Program(XLYC2403076);Young Elite Scientists Sponsorship Program by Chinese Chemical Society.

摘要/Abstract

摘要：

随着便携式电子设备、可穿戴技术以及环境与生物传感系统的快速发展, 对高效、稳定、便携化能源器件与传感器件的需求日益迫切. 提升这些器件的催化性能、传感灵敏度与实际应用的可靠性已成为材料化学与能源工程领域的重要研究方向. 其中, 单原子催化剂具备最大化的原子利用率以及可调控的电子结构, 展现出优异的催化和传感性能, 成为推动便携式能源器件(如金属空气电池、燃料电池)与高性能传感器技术革新的关键材料. 此外, 单原子催化剂结构清晰、易于模型构造, 便于结合密度泛函理论计算与先进表征手段, 能够更准确地研究反应机理并指导性能优化. 然而, 现有关于单原子催化剂的综述多集中于某一类便携式器件, 缺乏对其在多类便携式能源与传感器应用中所面临共性挑战与发展前景的系统性分析.

针对这一不足, 本文系统综述了单原子催化剂在便携式锌空气电池、质子交换膜燃料电池与传感技术中的研究现状, 深入探讨其应用前景、关键挑战与未来发展趋势. 首先, 介绍了便携式锌空气电池的基本反应机理, 并系统分析了关键材料的柔性化改进策略, 包括阴极催化剂、电解质以及阳极锌片的性能优化; 同时, 梳理了一维线缆型、二维平面型与三维层状型等多种柔性电池结构的发展路径. 随后, 围绕质子交换膜燃料电池的阴极氧还原反应催化机制, 阐述了气体扩散层、双极板和质子交换膜等柔性功能材料的设计思路, 以及柔性化、轻量化与管状等新型电池结构的集成策略. 接着, 聚焦单原子催化剂在便携式传感器领域的应用, 详细总结了其在气敏、湿敏等多类型传感器中的催化增强机制与优化路径. 最后, 指出当前单原子催化剂在便携式锌空气电池、质子交换膜燃料电池和传感器中的应用仍面临诸多挑战, 包括可控合成难度大、结构稳定性差、成本高昂以及在柔性器件中的集成过程复杂等问题.

为应对上述挑战, 未来研究将着重于非贵金属单原子催化剂的高效设计、柔性结构与器件的一体化构建, 以及人工智能与机器学习辅助的高通量筛选与性能预测, 为其在可穿戴电子、便携式能源系统与智能传感领域的实际应用奠定理论基础与工程支撑.

关键词: 单原子催化剂, 便携式, 锌空气电池, 燃料电池, 传感器

Abstract:

With the rapid advancement of portable energy devices and sensor technologies, enhancing their catalytic performance, sensing capabilities, and application reliability has become a critical challenge in the fields of materials and energy science. Single-atom catalysts (SACs), owing to their high atomic utilization, outstanding catalytic activity, and precisely engineered structures enabled by density functional theory and enhanced by artificial intelligence, have shown tremendous potential in advancing portable energy and sensing technologies. While existing reviews predominantly focus on the application of SACs in individual portable devices, systematic discussions on their overall development prospects and challenges within portable energy and sensor fields remain scarce. Therefore, this review comprehensively explores the application potential and recent advancements of SACs in portable zinc-air batteries, proton exchange membrane fuel cells, and sensor technologies. The article highlights the influence of key factors such as material design, structural optimization, and packaging integration on device performance, while also addressing the primary bottlenecks and challenges encountered in current practical applications. Furthermore, it suggests possible future development directions, aiming to offer theoretical insights and engineering guidance for the large-scale deployment of SACs in wearable electronic devices, portable energy systems, and smart sensing technologies.

Key words: Single-atom catalysts, Portable, Zinc-air batteries, Fuel cells, Sensors

赵天佑, 胡凤鸣, 朱美琦, 杨昌杰, 汪新宇, 潘永周, 杨嘉睿, 张霞, 李文豪, 王定胜. 单原子催化剂在便携式能源与传感器技术中的未来发展[J]. 催化学报, 2025, 78: 100-137.

Tianyou Zhao, Fengming Hu, Meiqi Zhu, Chang-Jie Yang, Xin-Yu Wang, Yong-Zhou Pan, Jiarui Yang, Xia Zhang, Wen-Hao Li, Dingsheng Wang. Future development of single-atom catalysts in portable energy and sensor technologies[J]. Chinese Journal of Catalysis, 2025, 78: 100-137.

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图/表 19

Fig. 1. (A) Application potential of SACs in portable ZABs, PEMFCs [2], and sensors [19,20]. Reprinted with permission from Ref. [2], Copyright 2022, Elsevier. Reprinted with permission from Ref. [19]. Copyright 2023, Springer Nature. Reprinted with permission from Ref. [20]. Copyright 2024, Springer Nature. (B) Data were retrieved from Scopus for the period 2011-2025 using the keywords “single-atom catalysts”, “zinc-air batteries”, “proton exchange membrane fuel cells”, and “portable sensors” (accessed on July 4, 2025).

Fig. 2. (A) Schematic illustration of the structure of a rechargeable ZABs using an aqueous electrolyte. (B) Polarization curves of the zinc anode and air cathode in the rechargeable ZABs.

Fig. 3. (A) Schematic illustration of a flexible quasi-solid-state ZAB. (B) Stability evaluation of Fe1/d-CN and Pt/C + RuO2 catalysts as air cathodes in alkaline and neutral flexible quasi-solid-state ZABs. (C) Cycling stability of flexible quasi-solid-state ZABs under different bending angles in both alkaline and neutral electrolytes. (D) Demonstration of three flexible quasi-solid-state ZABs powering an light emitting diode (LED) [61]. Reprinted with permission from Ref. [61]. Copyright 2021, Royal Society of Chemistry. (E) Schematic diagram of the flexible solid-state ZAB configuration. (F) Discharge and power density curves of ZAB-Fe3Co7-NC at various temperatures. (G) Cycling performance of ZAB-Fe3Co7-NC under current densities of 2 and 5 mA cm-2 at different temperatures [62]. Reprinted with permission from Ref. [62]. Copyright 2022, John Wiley and Sons. (H) Schematic illustration of the low-temperature flexible rechargeable ZAB based on FeMn-N/S-C-1000. (I) Comparison of discharge profiles and power density. (J) Discharge curves of flexible rechargeable ZABs at different current densities and temperatures. (K) Charge-discharge cycling performance at -40?°C under a constant current density of 2?mA?cm-2 [63]. Reprinted with permission from Ref. [63]. Copyright 2024, Elsevier.

Fig. 4. (A) Illustration of sandwich-type FZABs. (B) Liquid retention capacity comparison among PAM/EG, PAM, and PVA. (C) Cycling stability of FeSA/FeAC@PPy/CC-based FZABs under a current density of 2 mA cm-2 in different bending states and under hammering [71]. Reprinted with permission from Ref. [71]. Copyright 2025, Royal Society of Chemistry. (D) Schematic illustration of the fabrication process of IE-M/HPLIG. (E) Discharge profiles and power density performance of rechargeable flexible quasi-solid-state ZABs assembled with IE-NiFeCo/HPLIG as the air cathode. (F) Charge-discharge cycling performance at 5 mA cm-2 under various bending conditions. (G) Practical demonstration of three serially connected batteries [72]. Reprinted with permission from Ref. [72]. Copyright 2022, John Wiley and Sons. (H) Schematic illustration of the electrospinning process for the fabrication of Co SA/NCFs. (I) Galvanostatic cycling performance of Co SA/NCFs and 20% Pt/C + IrO2 cathodes at a current density of 2 mA cm-2. (J) Cycling performance of Co SA/NCFs-based batteries under different bending angles at a current density of 1 mA cm-2 [69]. Reprinted with permission from Ref. [69]. Copyright 2022, American Chemical Society.

Fig. 5. (A) Copper plating without electrolyte on spandex fabric through a pre-stretching-loading-recovery strategy, followed by dynamic stretching for zinc/nickel electroplating, and assembly into a ZAB based on in-situ crosslinked hydrogel electrolyte. (B) Photographs of the zinc-coated fabric before and after 100% stretching. (C) SEM images of the zinc-coated fabric before and after stretching. (D) Discharge polarization curve of large-area ZABs [74]. Reprinted with permission from Ref. [74]. Copyright 2022, John Wiley & Sons Australia. (E) Schematic of a solid-state rechargeable zinc-air battery utilizing a functionalized nanocellulose membrane. (F) Schematic of an FZAB device integrated with a band-aid, demonstrating the flexible device wrapped around the index finger in a bent state, successfully powering a red LED. Also provided is the power density versus current density curve of a single flexible battery, along with the Nyquist plot measured at various bending angles [75]. Reprinted with permission from Ref. [75]. Copyright 2016, Royal Society of Chemistry. (G) Biomass-based ICNF/WCNF SSEs fabricated by weaving ICNF and WCNF into a mesh structure. (H) Wet biomass ICNF/WCNF SSEs. (I) Schematic of a sandwich-structured FZAB. (J) Comparison of the cycling life and discharge voltage with previously reported biomass-based SSE FZABs in the literature [76]. Reprinted with permission from Ref. [76]. Copyright 2024, John Wiley and Sons.

Fig. 6. (A) Configuration of cable-type flexible ZABs utilizing PVAA-GO GPE. (B) Galvanostatic discharge and charge curves of the cable-type flexible ZAB under various conditions. (C) Three cable-type ZABs connected in series to power a commercial smartwatch [89]. Reprinted with permission from Ref. [89]. Copyright 2020, John Wiley and Sons. (D) Schematic of the one-dimensional FZAB structure. (E) Continuous power supply to a smartwatch achieved by integrating FZABs into a custom-woven wristband. (F) Illustration of the jumping motion and corresponding EMG signals. (G) Schematic diagram of serially connected FZABs powering a sensor patch. Photographs of the dumbbell-lifting process (H) and EMG signal variations recorded during the lifting and lowering movements (I) [90]. Reprinted with permission from Ref. [90]. Copyright 2024, American Chemical Society.

Fig. 7. (A) Fabrication process of the PAR-ZAB. (B) Polarization and power density curves of a single device, along with the performance of serially integrated devices. (C) Polarization and power density curves of the integrated device connected in parallel. (D) Three PAR-ZAB integrated units connected in series exhibit mechanical flexibility and are capable of powering commercial LED lights. (E) A self-designed smartwatch powered by a PAR-ZAB wristband with customized dimensions and voltage output, demonstrating safe and direct skin contact (as shown in the inset). (F) Schematic illustration of a runner wearing a smartwatch powered by an integrated PAR-ZAB wristband [93]. Reprinted with permission from Ref. [93]. Copyright 2019, Royal Society of Chemistry. (G) Optical image, microscopic view, and actual geometric parameters of a single mZAB active unit. (H) Charge-discharge polarization curves of the mZAB based on NdDCF-OIM/Co-800 and Pt/C + RuO2 [94]. Reprinted with permission from Ref. [94]. Copyright 2021, Royal Society of Chemistry.

Fig. 8. (A) HAADF-STEM and EDS mapping images of FCN-TM/NC. B) Bifunctional LSV curves of FCN-TM/NC. (C) Graphical depiction of the solid-state ZABs. (D) Discharge polarization and power density curves of the flexible solid-state ZAB. (E) Charge-discharge cycling test of the FSS-ZAB at -60 °C under a current density of 1 mA cm-2. (F) Performance comparison of the FSS-ZAB with previously reported studies. (G) Smartwatch and smartphone powered by the FSS-ZAB under bending conditions [96]. Reprinted with permission from Ref. [96]. Copyright 2025, John Wiley and Sons.

Table 1 Comparison and development prospects of different flexible ZABs structures.

Structure type	Key features	Advantages	Limitations	Typical applications	Fabrication/ integration method	Commercial potential
1D Cable- type	weavable and shape-adaptable	excellent flexibility, easy integration into textiles	limited structural stability and scalability	smart textiles, wearables	fiber spinning, weaving, winding	moderate, suitable for functional modularization
2D Planar- type	high surface area, good coplanar integration	high compatibility with flexible microelectronics	limited stretchability	flexible sensors, flexible circuits	thin-film deposition, planar assembly	moderate, suitable for customized applications
Sandwich Layered- type	laminated assembly, roll-to-roll production	high structural stability, easy standardization, low cost	flexibility slightly lower	portable energy storage, mass packaging	laminated assembly, roll-to-roll fabrication	high, suitable for large-scale commercial applications

Fig. 9. (A) Structural model diagram of a PEMFC. (B) Schematic diagram of the ORR mechanism in acidic media [108]. Reprinted with permission from Ref. [108]. Copyright 2016, Advancement of Science.

Fig. 10. (A) Fabrication process of the novel and commercial GDL. (B) MEA prepared using commercial GDL and carbon paper after hot pressing. (C) MEA prepared with the novel GDL. (D) Flexible air-breathing PEMFC based on the novel GDL and its structural schematic (inset). (E) Polarization curves of PEMFCs assembled with commercial and novel GDLs. [113]. Reprinted with permission from Ref. [113]. Copyright 2020, Royal Society of Chemistry. (F) Schematic diagram of flexible PEMFCs. (G) Polarization curves of flexible PEMFCs with different GDLs under bending conditions [114]. Reprinted with permission from Ref. [114]. Copyright 2023, Springer Nature. (H) Application demonstrations of flexible PEMFC stacks [115]. Reprinted with permission from Ref. [115]. Copyright 2017, American Chemical Society.

Fig. 11. (A) Digital camera images of the foldable PEMFC in flat, 90° bent, and 180° folded states. (B) Polarization curves (solid symbols, left axis) and power density curves (hollow symbols, right axis) of the foldable fuel cell in flat, bent, and folded states. (C) Demonstration of the foldable fuel cell powering an electric motor; the motor remains inoperative without hydrogen supply. (D) Polarization and power density curves of the foldable fuel cell after 100, 200, and 300 folding cycles [119]. Reprinted with permission from Ref. [119]. Copyright 2024, Elsevier. (E) Schematic diagram of the bent PEMFC structure, showing the reaction zone and process under bending. (F) 3D-printed flexible flow-field plates. (G) Performance comparison of the bent PEMFC under different bending states. (H) Finite element analysis showing the compressive stress generated during the bending process of the bent PEMFC [2]. Reprinted with permission from Ref. [2]. Copyright 2022, Elsevier.

Fig. 12. (A) Digital image showing the weight and thickness of the air-breathing RUFC. (B) Photographs of RUFCs in different configurations (rolled and S-shaped). (C) Portable 10-cell RUFC stack used for smartphone charging and LED fan operation, including outdoor application with a hydrogen storage metal hydride cartridge. (D) Polarization curves of the stacked RUFCs [121]. Reprinted with permission from Ref. [121]. Copyright 2017, Springer Nature. (E) Integrated micro fuel cell with three cells connected in series. (F) Micro fuel cell powering an LED in a bent configuration. (G) Design features of PEM micro fuel cells: Design 1 with serpentine anode flow field and Design 2 with parallel flow channels [122]. Reprinted with permission from Ref. [122]. Copyright 2004, Elsevier. (H) Schematic illustration of the tubular PEMFC fabrication process. (I) Optical image of a two-cell stacked flexible t-PEMFC. (J) Polarization curves of the two-cell stacked flexible t-PEMFC [123]. Reprinted with permission from Ref. [123]. Copyright 2021, American Chemical Society.

Fig. 13. (A) HAADF-STEM image of Pt1-MoS2-def. (B,C) Dynamic response curves of MoS2, Pt1-MoS2, and Pt1-MoS2-def at SO2 concentrations of 0.5-5 ppm and 20-40 ppm, respectively. (D) Comparison of response values for the three materials under different SO2 concentrations. (E) Gas selectivity results for MoS2, Pt1-MoS2, and Pt1-MoS2-def. (F) Schematic of real-time SO2 concentration monitoring in a greenhouse environment. (G) Modular block diagram of the detection system. (H) Presentation of measured SO2 concentration data [138]. Reprinted with permission from Ref. [138]. Copyright 2024, Springer Nature. (I) Schematic of the sensor device structure. (J), (K) Dynamic gas sensing performance of rGO, N@rGO, Co-rGO, and M SACs-N@rGO (M = Co, Ni, Pt) under 0.1-20 ppm NO2 [139]. Reprinted with permission from Ref. [139]. Copyright 2023, American Chemical Society. (L) Transient response curves of five sensors under 5 ppm NH3 exposure at room temperature. (M) Response comparison of the MNPE-Ni-N-C/Ti3C2Tx sensor to 5 ppm NH3 under varying relative humidity conditions (room temperature). (N) Optical image of the MNPE-Ni-N-C/Ti3C2Tx flexible sensor under bending. (O) Resistance response curves of the MNPE-Ni-N-C/ Ti3C2TxTx sensor to 5 ppm NH3 over different weeks [140]. Reprinted with permission from Ref. [140]. Copyright 2024, Springer Nature.

Fig. 14. (A) Synthesis of Pt-loaded Fe2O3 nanosheets (Pt-Fe2O3-Vo). (B) Dynamic response curves of the sensor under various H2 concentrations. (C) Response performance of the sensor to 50 ppm H2 at different temperatures. (D) Selectivity test results of the sensor against various gases. (E) Long-term stability of the sensor under 50 ppm H2 [143]. Reprinted with permission from Ref. [143]. Copyright 2024, American Chemical Society. (F) Schematic illustration of the synthesis of Fe2O3, Pt1-Fe2O3, and Pt1-Fe2O3-ox. (G) Comparison of the response of the three materials to 100 ppm C2H5OH across a temperature range of 200-320 °C. (H) Response performance of Pt1-Fe2O3-ox to 10-200 ppm C2H5OH at 280 °C. (I) Response and recovery time curve of Pt1-Fe2O3-ox under 100 ppm C2H5OH at 280 °C. (J) Selectivity comparison of Fe2O3, Pt1-Fe2O3, and Pt1-Fe2O3-ox to various gases (100 ppm) [144]. Reprinted with permission from Ref. [144]. Copyright 2020, Springer Nature.

Fig. 15. (A) Schematic illustration of the experimental setup for humidity sensing. (B) Frequency shifts of four modified QCM-based humidity sensors under different RH conditions. (C) Sensitivity curves of four samples within the RH range of 33% to 97%. (D) Comparison of response and recovery times at 97% RH. (E) Analysis of humidity hysteresis characteristics [151]. Reprinted with permission from Ref. [151]. Copyright 2022, American Chemical Society. (F) Resistance variation and linear fitting results of the ZDC800-AL sensor in the RH range of 11%-98%. (G) High-resolution linear fitting curve of the ZDC800-AL sensor in the RH range of 50%-60%. (H) Dynamic response and recovery behavior of the ZDC800-AL sensor in the RH range of 0.3%-90%. (I) Schematic diagram of the humidity sensing mechanism for ZDC-AL-based sensors. (J) Diagram of six-digit binary password recognition and sensor operation workflow. (K) Real-time images of a fingertip approaching and moving away from the humidity sensor array. (L) Dynamic response curves of the humidity sensor array to the approaching fingertip. (M) Real-time humidity sensing signals recorded on the back and palm of a human subject's hand. (N) Sensor responses before and after applying moisturizer on the back of the hand [154]. Reprinted with permission from Ref. [154]. Copyright 2025, Elsevier.

Fig. 16. (A) Schematic illustration of inflammation-free in vivo electrochemical sensing enabled by Fe1/NC-900 catalyst. (B) Histological comparison of NAc brain tissue from untreated rats and those implanted with bare or Fe1/NC-900-modified carbon fiber electrodes (CFEs) for 8 h (n = 3 per group), with astrocytes (green), microglia (magenta), and nuclei (blue) fluorescently labeled (scale bar: 50 μm). The fluorescence intensity variation of astrocytes is also shown. (C) Quantitative ELISA analysis of IL-6, TNF-α, and IL-1β levels in brain tissues from untreated rats (blue columns) and rats implanted with bare (gray) or Fe1/NC-900-modified (red) CFEs (n = 3 for each group). Data are presented as mean ± SEM, and p-values are indicated in the figures via one-way ANOVA. Source data are provided with the article [20]. Reprinted with permission from Ref. [20]. Copyright 2024, Springer Nature. (D) Schematic illustration of the Fe-SAs configuration. (E) CPT curves in standard buffer solutions of different pH. (F) Correlation between open-circuit potential (OCP) and pH (n = 3). (G) Stability test of the pH sensor (n = 3) [155]. Reprinted with permission from Ref. [155]. Copyright 2023, American Chemical Society. (H) Relative resistance variation of Ru-ALD engineered DM-V2CTx MXene-based temperature sensor with respect to temperature. (I) Durability testing of the temperature sensor under repeated heating and water droplet cooling cycles. (J) Continuous response performance under external temperature variations of 30-50 °C. (K) Real-time human skin temperature monitoring and corresponding infrared thermal imaging [156]. Reprinted with permission from Ref. [156]. Copyright 2023, John Wiley and Sons.

Fig. 17. Advantages and disadvantages of single-atom catalysts in portable ZABs, PEMFCs, and sensor systems.

Fig. 18. Opportunities and challenges associated with single-atom catalysts and their integration into portable ZABs, PEMFCs, and sensors across materials, structural design, packaging, and system integration.

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单原子催化剂在便携式能源与传感器技术中的未来发展

Future development of single-atom catalysts in portable energy and sensor technologies

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