2D Hybrid Superlattice-Based On-Chip Electrocatalytic Microdevice for in Situ Revealing Enhanced Catalytic Activity

Guo Yabin; Chen Qiao; Nie Anmin; Yang Huan; Wang Wenbin; Su Jianwei; Wang Shuzhe; Liu Youwen; Wang Shun; Li Huiqiao; Liu Zhongyuan; Zhai Tianyou

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2D Hybrid Superlattice-Based On-Chip Electrocatalytic Microdevice for in Situ Revealing Enhanced Catalytic Activity

机译：基于杂交超晶格的芯片上电催化微催化微催化微催化微催化微透露率提高了催化活性

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摘要

A molecule-confined two-dimensional (2D) hybrid superlattice is emerging for uncovering the chemical properties as well as distinctive physical phenomenon arising from the interface electronic states. An efficient and convenient synthetic method represents an important precondition to implementing the superlattice in terminal applications and functional devices. Herein, we develop an approach of spontaneous molecular intercalation to obtain a TaS2-N2H4 hybrid superlattice through simple solution immersion processing at room temperature. A cross-sectional high-angle annular dark field image verifies that the INT,H, molecules intercalate into the TaS2 lattice, and the interlayer spacing expands approximately 1.5 times. Combining electrical transport testing and theoretical calculations, electron transfer from N2H4 to the S-Ta-S lattice induces enhanced superconductivity and the suppression of the order of charge density waves. Moreover, electrical and Kelvin probe force microscope measurements reveal that intercalary N2H4 molecules ensure that the superlattice has higher conductivity and a lower surface work function at room temperature. A 2D hybrid superlattice-based on-chip electrocatalytic microdevice was fabricated through in situ molecular intercalation to directly evaluate the catalytic performance. Benefiting from electronic state regulation, the hybrid superlattice is more active. The presented intercalation method would aid in exploring efficient catalysts and discovering fundamental 2D physics.

机译：揭示了分子限制的二维（2D）杂种超晶格，用于揭示界面电子状态产生的化学性质以及不同的物理现象。高效且方便的合成方法代表了在终端应用和功能设备中实现超晶格的重要前提。在此，我们通过在室温下通过简单的溶液浸入处理产生自发分子嵌入的方法，得到TAS2-N2H4杂交超晶格。横截面高角度环形暗场图像验证int，h，分子嵌入Tas2晶格中，并且中间间距扩展约1.5倍。结合电气运输测试和理论计算，从N2H4到S-TA-S晶格的电子传递引起增强的超导性和抑制电荷密度波的抑制。此外，电气和开尔文探针力显微镜测量显示，间位N2H4分子确保超晶格在室温下具有更高的导电性和较低的表面工作功能。通过原位分子嵌入制造基于2D杂交超晶格的片上电催化微量，以直接评估催化性能。从电子国家监管中受益，混合超级晶格更活跃。呈现的嵌入方法有助于探索有效的催化剂并发现基本的2D物理学。

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来源
《ACS nano》 |2020年第2期|共10页
作者
Guo Yabin; Chen Qiao; Nie Anmin; Yang Huan; Wang Wenbin; Su Jianwei; Wang Shuzhe; Liu Youwen; Wang Shun; Li Huiqiao; Liu Zhongyuan; Zhai Tianyou;
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作者单位

Huazhong Univ Sci &

Technol State Key Lab Mat Proc &

Die &

Mould Technol Sch Mat Sci &

Engn Wuhan 430074 Peoples R China;

Huazhong Univ Sci &

Technol MOE Key Lab Fundamental Phys Quant Measurement Wuhan 430074 Peoples R China;

Yanshan Univ Ctr High Pressure Sci State Key Lab Metastable Mat Sci &

Technol Qinhuangdao 066004 Hebei Peoples R China;

Huazhong Univ Sci &

Technol State Key Lab Mat Proc &

Die &

Mould Technol Sch Mat Sci &

Engn Wuhan 430074 Peoples R China;

Huazhong Univ Sci &

Technol State Key Lab Mat Proc &

Die &

Mould Technol Sch Mat Sci &

Engn Wuhan 430074 Peoples R China;

Huazhong Univ Sci &

Technol State Key Lab Mat Proc &

Die &

Mould Technol Sch Mat Sci &

Engn Wuhan 430074 Peoples R China;

Huazhong Univ Sci &

Technol State Key Lab Mat Proc &

Die &

Mould Technol Sch Mat Sci &

Engn Wuhan 430074 Peoples R China;

Huazhong Univ Sci &

Technol State Key Lab Mat Proc &

Die &

Mould Technol Sch Mat Sci &

Engn Wuhan 430074 Peoples R China;

Huazhong Univ Sci &

Technol MOE Key Lab Fundamental Phys Quant Measurement Wuhan 430074 Peoples R China;

Huazhong Univ Sci &

Technol State Key Lab Mat Proc &

Die &

Mould Technol Sch Mat Sci &

Engn Wuhan 430074 Peoples R China;

Yanshan Univ Ctr High Pressure Sci State Key Lab Metastable Mat Sci &

Technol Qinhuangdao 066004 Hebei Peoples R China;

Huazhong Univ Sci &

Technol State Key Lab Mat Proc &

Die &

Mould Technol Sch Mat Sci &

Engn Wuhan 430074 Peoples R China;

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原文格式 PDF
正文语种 eng
中图分类分子物理学、原子物理学;
关键词
hybrid superlattice; TaS2; on-chip electrocatalytic microdevice; electrocatalysis; interfacial charge injection;

机译：杂交超晶格;TAS2;片上电催化微生物;电催化;界面电荷注射;

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1. 2D Hybrid Superlattice-Based On-Chip Electrocatalytic Microdevice for in Situ Revealing Enhanced Catalytic Activity [J] . Guo Yabin, Chen Qiao, Nie Anmin, ACS nano . 2020,第2期

机译：基于杂交超晶格的芯片上电催化微催化微催化微催化微催化微透露率提高了催化活性
2. Effect of ethylenediamine on morphology of 2D Co-Mo-S@NG hybrids and their enhanced electrocatalytic activity for DSSCs application [J] . Ganesh R. Sankar, Durgadevi E., Silambarasan K., Materials science in semiconductor processing . 2020,第期

机译：乙二胺对2D Co-Mo-S @ Ng杂种形态的影响及其对DSSCS应用的增强电催化活性
3. On-chip electrocatalytic microdevice: an emerging platform for expanding the insight into electrochemical processes [J] . Yang Huan, He Qiyuan, Liu Youwen, Chemical Society Reviews . 2020,第10期

机译：片上电催化微量微型：用于将洞察力扩展到电化学过程的新兴平台
4. ON-CHIP WESTERN BLOTTING: IN-SITU RENATURATION OF SDS-PROTEIN COMPLEXES UNIFIES SODIUM DODECYL SULFATE (SDS) SIZING BLOTTING IN ONE MICRODEVICE [C] . Chenlu Hou, Amy E. Herr International Conference on Miniaturized Systems for Chemistry and Life Sciences . 2011

机译：片上蛋白质印迹：原位复合SDS-蛋白质复合物统一在一个微型内部的十二烷基硫酸钠（SDS）尺寸和印迹
5. Revealing the Molecular Details of Metal Oxide Nanoparticle Surface Hydroxyl Chemistry and Reactivity Using In Situ Drifts [D] . Kipreos, Maria Dimitra 2018

机译：使用原位漂移揭示金属氧化物纳米颗粒表面羟基化学和反应性的分子细节
6. Carbon Supported Engineering NiCo2O4 Hybrid Nanofibers with Enhanced Electrocatalytic Activity for Oxygen Reduction Reaction [O] . Diab Hassan, Sherif El-safty, Khalil Abdelrazek Khalil, 2016

机译：具有增强的氧还原反应电催化活性的碳载工程NiCo2O4杂化纳米纤维
7. Single WTe2 Sheet-Based Electrocatalytic Microdevice for Directly Detecting Enhanced Activity of Doped Electronegative Anions [O] . -1

机译：用于直接检测掺杂电负阴离子的增强活性的单个WTE2薄层电催化微催化

2D Hybrid Superlattice-Based On-Chip Electrocatalytic Microdevice for in Situ Revealing Enhanced Catalytic Activity

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