贵金属气凝胶的可控制备及其电催化与表面增强拉曼散射应用

doi:10.6023/A24030108

化学学报 ›› 2024, Vol. 82 ›› Issue (7): 805-818.DOI: 10.6023/A24030108 上一篇下一篇

研究评论

贵金属气凝胶的可控制备及其电催化与表面增强拉曼散射应用

李一^a, 翁蓓蓓^a, 赵静雯^a, 杜然^a^,^b^,^*()

a 北京理工大学材料学院北京 100081
b 北京理工大学唐山研究院唐山 063000

投稿日期:2024-03-31 发布日期:2024-05-13

作者简介:

杜然, 北京理工大学教授. 2016年毕业于北京大学, 获得物理化学博士学位, 随后先后赴新加坡南洋理工大学、德国德累斯顿工业大学、香港大学等地从事博士后研究. 2021年加盟北京理工大学. 先后获得北京大学优秀博士论文、德国洪堡学者、USERN Prize提名(物理与化学科学领域)等荣誉, 入选2020年度海外高层次人才引进计划青年项目, 任SmartMat、National Science Open青年编委. 主要研究领域为以金属气凝胶为代表的先进气凝胶的可控制备及其在电催化、环境治理、智能材料等领域的应用.

基金资助:
北京市自然科学基金(2232063); 国家自然科学基金(22202009); 大学生创新创业训练项目(BIT2023LH083); 北京理工大学研究生科研水平和创新能力提升专项计划(2023YCXY040)

Controlled Synthesis of Noble Metal Aerogels and Their Applications in Electrocatalysis and Surface-Enhanced Raman Scattering

Yi Li^a, Beibei Weng^a, Jingwen Zhao^a, Ran Du^a^,^b^,^*()

a School of Materials Science and Engineering, Beijing Institute of Technology, Beijing 100081, China
b Tangshan Research Institute, Beijing Institute of Technology, Tangshan 063000, China

Received:2024-03-31 Published:2024-05-13
Contact: *E-mail: rdu@bit.edu.cn
Supported by:
Beijing Natural Science Foundation(2232063); National Natural Science Foundation of China(22202009); College Students’ Innovation and Entrepreneurship Training Program(BIT2023LH083); BIT Research and Innovation Promoting Project(2023YCXY040)

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摘要/Abstract

贵金属气凝胶(NMAs)是一类由纳米结构贵金属构筑的新型气凝胶, 于2009年被首次报道. NMAs拥有大量的催化/光学活性位点、丰富的电子/物质传输通道以及三维多孔网络结构, 在电催化、检测传感等领域表现出极优异的性能. 作为一类新兴材料, NMAs的可控制备存在很大挑战, 制约了应用研究. 在过去数年间, 作者课题组从理论、实验两方面对贵金属体系的溶胶-凝胶原理进行了深入研究. 基于此, 发展了诸如特异性离子效应、过量还原剂、力场扰动、冻融诱导等多种制备策略, 拓展了材料的组成与结构多样性, 获得了多种高性能电催化剂. 借助NMAs的光学性质, 进一步开辟了其光电催化方向及其在表面增强拉曼散射(SERS)领域的应用, 使其潜力得到进一步发挥. 本研究评论将对NMAs的制备原理、可控制备方法及其在电催化与SERS领域的应用研究进行梳理, 并对其未来研究方向进行简要展望.

关键词: 气凝胶, 溶胶-凝胶, 纳米结构, 电催化, 表面增强拉曼散射

Noble metal aerogels (NMAs) are an emerging class of porous materials that are entirely constructed by one or more kinds of nanostructured noble metals including gold (Au), silver (Ag), palladium (Pd), platinum (Pt), ruthenium (Ru), rhodium (Rh), osmium (Os), and iridium (Ir). They feature attributes of both nanostructured noble metals (e.g., high catalytic activity, high electrical conductivity, and special optical properties) and aerogels (e.g., self-standing architecture, large specific surface area, abundant pores, and robust 3D networked structure). Therefore, since their discovery in 2009, NMAs have displayed tremendous potential in fields ranging from (electro)catalysis, battery electrodes, biosensing, plasmonic technologies, and environment remediation. However, as young materials, the investigation of NMAs is far from sufficient. Controlled synthesis is the basis for new materials that dictate how far they can reach. The sol-gel behavior of the metal system is distinct from that of conventional gel systems, thus requiring additional studies. However, the fundamental understanding of the fabrication process and thus the structure/composition control for NMAs are largely overlooked. In this context, our team has been focusing on developing effective fabrication strategies based on an in-depth understanding of the gelation mechanisms as well as the roles played by each component in the reaction. To this end, we have pioneered realizing ligament size control, unveiling the reductant chemistry, unlocking the ligand chemistry, and achieving minute-scale rapid gelation by counter-intuitionally introducing force fields. We aim to eventually realize arbitrary manipulation of the composition and structure of NMAs, which is critical for paving the way for their further development. After gaining sufficient control capacity for NMAs, then we go for exploring their applications. It is crucial to select appropriate scenarios according to their unique attributes, so as to fully exert their potential and eventually find their disruptive application directions. Inheriting features of noble metals and aerogels, NMAs possess abundant catalytic/optical active sites, high electronic/mass transfer channels, and robust and self-supported networks. In this regard, they should be suited for the (photo)electrocatalysis and detection based on surface-enhanced Raman scattering (SERS). Indeed, numerous studies have demonstrated their exceptional electrocatalytic performances towards diverse reactions such as the alcohol oxidation reaction (AOR), hydrogen evolution reaction (HER), oxygen evolution reaction (OER), oxygen reduction reaction (ORR), and carbon dioxide reduction reaction (CO₂RR). We further pioneered incorporating light in the electrocatalytic process, opening the photoelectrocatalysis direction. Additionally, we found that Au aerogels can serve as ideal 3D SERS substrates for they feature hot spots across three dimensions, which enables their outstanding signal enhancement and misfocus tolerance. However, intentionally on-target performance optimi-zation and the exploration of new design perspectives for NMAs are still on the way. In this account, we summarize the representative endeavors made in controlled synthesis and electrocatalysis/SERS applications of NMAs. After a brief introduction of NMAs, we will highlight the state-of-the-art understanding of the sol-gel process of metal systems, and how to achieve structure-controlled synthesis and rapid fabrication of NMAs. After narrating the progress in electrocatalysis and SERS applications, we will conclude the challenges and opportunities for these young materials.

Key words: aerogels, sol-gel, nanostructures, electrocatalysis, surface-enhanced Raman scattering

引用此文

李一, 翁蓓蓓, 赵静雯, 杜然. 贵金属气凝胶的可控制备及其电催化与表面增强拉曼散射应用[J]. 化学学报, 2024, 82(7): 805-818.

Yi Li, Beibei Weng, Jingwen Zhao, Ran Du. Controlled Synthesis of Noble Metal Aerogels and Their Applications in Electrocatalysis and Surface-Enhanced Raman Scattering[J]. Acta Chimica Sinica, 2024, 82(7): 805-818.

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图/表 12

图1. 金气凝胶压缩前后的结构[4]

Figure 1. Au aerogels before and after compression[4]

图2. 金体系中重力驱动的溶胶-凝胶行为. (A, B)金气凝胶的制备过程及其示意图. (C)反应体系不同高度处的紫外可见光谱. (D, E)溶胶-凝胶过程的分时动态光散射与光学显微镜表征[4]

Figure 2. The gravity-driven sol-gel behavior of the Au system. (A, B) The fabrication process of the Au aerogels. (C) The UV-vis spectra of the reaction systems recorded at different heights. (D, E) Time-lapse dynamic light scattering and optical microscopy of the sol-gel process[4]

图3. 金水凝胶的自愈合性质[4]

Figure 3. Self-healing properties of Au hydrogels[4]

图4. 金气凝胶的特征尺寸调控. (A, B)不同盐诱导制备的金气凝胶[4]. (C, D)过量硼氢化钠诱导制备金气凝胶的原理, 以及在反应中引入不同配体后所得金气凝胶的特征尺寸[11]. (E, F)采用金纳米团簇作为前体制备超细金气凝胶, (E)金纳米团簇与(F)金气凝胶[25]

Figure 4. Modulation of the ligament size for Au aerogels. (A, B) Au aerogels prepared by using different salts[4]. (C, D) Mechanisms for synthesizing Au aerogels by applying excessive sodium borohydride and the ligament sizes by including different ligands during synthesis[11]. (E, F) Fabrication of ultrafine Au aerogels by assembling Au nanoclusters, (E) Au nanoclusters, and (F) Au aerogels[25]

图5. NMAs的结构单元维度调控. Pt-Bi气凝胶的结构单元维度可通过改变金属组成以及配体进行调控[15]

Figure 5. Dimensional modulation of the building blocks of noble metal aerogels. The dimension of the building blocks of Pt-Bi aerogels can be manipulated by adjusting the composition and the ligands[15]

图6. NMAs的多级结构控制. (A, B)冻融方法制备金气凝胶[14], (C, D)磁场辅助方法制备镍气凝胶[34]

Figure 6. Hierarchical structure control of noble metal aerogels. Synthesis of (A, B) Au aerogels via a freeze-thaw method[14] and (C, D) Ni aerogels via a magnetic field-assisted method[34]

图7. NMAs的元素分布调控. (A~C) Au-Pd核壳气凝胶及其制备过程[13]. (D) Au-Pt核壳气凝胶以及Au-Pd-Pt核壳气凝胶[4]

Figure 7. Element distribution modulation of noble metal aerogels. (A~C) Au-Pd core-shell aerogels and their preparation process[13]. (D) Au-Pt and Au-Pd-Pt core-shell aerogels[4]

图8. 扰动方法快速制备NMAs. (A)制备过程示意图以及(B, C)多种所得气凝胶[9]

Figure 8. The disturbance-directed rapid fabrication of noble metal aerogels. (A) Fabrication process and (B, C) diverse obtained aerogels[9]

图9. NMAs应用于电催化. 不同pH下(A)贵金属气凝胶的析氢极化曲线, 以及(B) Au-Rh气凝胶作为析氢电催化剂在全水电解中的应用性能[12]. (C) Cu@Fe@Ni核壳气凝胶应用于电催化析氧反应[46]

Figure 9. Application of noble metal aerogels for electrocatalysis. (A) Polarization curves of noble metal aerogels for hydrogen evolution, and (B) water-splitting performances with Au-Rh aerogel-based hydrogen evolution electrocatalysts under different pH values[12]. (C) Cu@Fe@Ni core-shell aerogels for electrocatalytic oxygen evolution[46]

图10. NMAs应用于光电催化. (A)电催化乙醇氧化过程的循环伏安曲线(无光条件), 以及(B)比质量活性与光功率密度的依赖关系[14]

Figure 10. Application of noble metal aerogels for photoelectrocatalysis. (A) The CV curves of the electrocatalytic ethanol oxidation process in dark and (B) the plot of mass activity versus light power density[14]

图11. NMAs应用于表面增强拉曼散射基底. (A, B)不同特征尺寸金气凝胶, 在不同激发波长下对罗丹明6G(R6G)分子的拉曼散射增强因子及其规律. (C) R6G分子在不同基底上的拉曼光谱. (D, E) R6G分子在8 nm金膜与金气凝胶在不同离焦状态下的拉曼光谱[16]

Figure 11. Application of noble metal aerogels for surface-enhanced Raman scattering. (A, B) The Raman enhancement factors of R6G with Au aerogels of different ligament sizes as substrates excited by different laser wavelengths. (C) Raman spectra of R6G recorded on different substrates. (D, E) Raman spectra of R6G recorded on 8 nm Au film and Au aerogels at different defocuses[16]

图12. NMAs的研究方向

Figure 12. Research directions for NMAs

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贵金属气凝胶的可控制备及其电催化与表面增强拉曼散射应用

Controlled Synthesis of Noble Metal Aerogels and Their Applications in Electrocatalysis and Surface-Enhanced Raman Scattering

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