The hydrogen evolution reaction(HER) through electrocatalysis is promising for the production of clean hydrogen fuel. However,designing the structure of catalysts,controlling their electronic properties,and manipulati...The hydrogen evolution reaction(HER) through electrocatalysis is promising for the production of clean hydrogen fuel. However,designing the structure of catalysts,controlling their electronic properties,and manipulating their catalytic sites are a significant challenge in this field. Here,we propose an electrochemical surface restructuring strategy to design synergistically interactive phosphorus-doped carbon@MoP electrocatalysts for the HER. A simple electrochemical cycling method is developed to tune the thickness of the carbon layers that cover on MoP core,which significantly influences HER performance. Experimental investigations and theoretical calculations indicate that the inactive surface carbon layers can be removed through electrochemical cycling,leading to a close bond between the MoP and a few layers of coated graphene. The electronsdonated by the MoP core enhance the adhesion and electronegativity of the carbon layers;the negatively charged carbon layers act as an active surface. The electrochemically induced optimization of the surface/interface electronic structures in the electrocatalysts significantly promotes the HER. Using this strategy endows the catalyst with excellent activity in terms of the HER in both acidic and alkaline environments(current density of 10 mA cm^(-2) at low overpotentials,of 68 mV in 0.5 M H_(2)SO_(4) and 67 mV in 1.0 M KOH).展开更多
氨是一种很有前途的能源载体,由于其高氢含量和无碳的特点,可用于燃料电池,并可作为电解水制氢装置中水的替代氧化底物.然而,人们对氨电氧化反应(AOR)的机理认识不足,且缺乏廉价、高效的AOR催化剂,因而阻碍了氨基能源系统的发展.在这项...氨是一种很有前途的能源载体,由于其高氢含量和无碳的特点,可用于燃料电池,并可作为电解水制氢装置中水的替代氧化底物.然而,人们对氨电氧化反应(AOR)的机理认识不足,且缺乏廉价、高效的AOR催化剂,因而阻碍了氨基能源系统的发展.在这项工作中,我们通过光诱导化学沉淀法合成的新型Ni和Cu共掺杂的多孔FeOOH纳米棒(NiCu-FeOOH)可以作为AOR催化剂,其具有高效的催化活性(阳极电流密度达到10 mA cm^(-2)时执行电压为1.41 V)和在氨碱溶液中优异的稳定性.实验数据和理论计算结果表明,异质的Ni和Cu原子的协同作用使得NiCu-FeOOH表面的Ni和Fe位点表现出更合适的电子结构,他们可以共同吸附含氮中间产物和羟基,并使其吸附自由能位于火山形曲线的顶部,从而加速AOR脱氢.决速步骤的后移(*NH_(2)+*OH形成步骤移至*N_(2)H_(3)+*OH形成步骤)和决速步骤较低的能垒(0.86 eV)揭示了Ni和Cu的共掺策略使FeOOH晶体对催化AOR更具活性.本文创新地提出了涉及含氮中间物和羟基的共吸附反应途径,以更好地描述和模拟AOR过程,这为设计低成本和稳定的AOR催化剂开辟了新的路径.展开更多
Zirconium metal-organic frameworks(Zr-MOFs) represent the most promising candidates among MOFs for industrial utilizations owing to their high porosity and excellent stability. However, the efficient synthesis of Zr...Zirconium metal-organic frameworks(Zr-MOFs) represent the most promising candidates among MOFs for industrial utilizations owing to their high porosity and excellent stability. However, the efficient synthesis of Zr-MOFs combining with continuous production, high productivity and good product quality still remains a critical issue for practical applications. Herein, we report an efficient method of synthesizing a series of Zr-MOFs through a microdroplet flow reaction, which is more accommodate the requirements of industrial production. Four types of Zr-based MOFs with different ligands and topologies(MOF-801, MOF-804, DUT-67 and MOF-808) were produced as a pure phase of high quality crystalline with uniform morphologies. Furthermore, this series of Zr-MOFs were obtained in a continuous way and at a space-time yield(STY) highly up to 367.2 kg m-3 d-1. These MOFs exhibit the similar pore structure and thermal stability with that prepared from conventional solvothermal synthesis. CO2 sorption studies on these MOFs demonstrate that the hydroxyl groups on ligand can render MOFs with high CO2/N2 selectivity.展开更多
基金supported by the National Natural Science Foundation of China (Grant Nos. 21975286 and 21473254)the Special Project Fund of “Taishan Scholar” of Shandong Province (Grant No. ts201511017)+2 种基金the QLUT Special Funding for Distinguished Scholars (Grant No. 2419010420)the project ZR2020QE058 supported by Shandong Provincial Natural Science Foundationthe Fundamental Research Funds for the Central Universities (Grant Nos. YCX2020050,18CX06030A,and 17CX02039A)。
文摘The hydrogen evolution reaction(HER) through electrocatalysis is promising for the production of clean hydrogen fuel. However,designing the structure of catalysts,controlling their electronic properties,and manipulating their catalytic sites are a significant challenge in this field. Here,we propose an electrochemical surface restructuring strategy to design synergistically interactive phosphorus-doped carbon@MoP electrocatalysts for the HER. A simple electrochemical cycling method is developed to tune the thickness of the carbon layers that cover on MoP core,which significantly influences HER performance. Experimental investigations and theoretical calculations indicate that the inactive surface carbon layers can be removed through electrochemical cycling,leading to a close bond between the MoP and a few layers of coated graphene. The electronsdonated by the MoP core enhance the adhesion and electronegativity of the carbon layers;the negatively charged carbon layers act as an active surface. The electrochemically induced optimization of the surface/interface electronic structures in the electrocatalysts significantly promotes the HER. Using this strategy endows the catalyst with excellent activity in terms of the HER in both acidic and alkaline environments(current density of 10 mA cm^(-2) at low overpotentials,of 68 mV in 0.5 M H_(2)SO_(4) and 67 mV in 1.0 M KOH).
基金supported by the National Natural Science Foundation of China(21975286)Shandong Provincial Natural Science Foundation(ZR2020QE058)+1 种基金the Colleges and Universities Twenty Terms Foundation of Jinan(202228053)the QLUT Special Funding for Distinguished Scholars(2419010420)。
文摘氨是一种很有前途的能源载体,由于其高氢含量和无碳的特点,可用于燃料电池,并可作为电解水制氢装置中水的替代氧化底物.然而,人们对氨电氧化反应(AOR)的机理认识不足,且缺乏廉价、高效的AOR催化剂,因而阻碍了氨基能源系统的发展.在这项工作中,我们通过光诱导化学沉淀法合成的新型Ni和Cu共掺杂的多孔FeOOH纳米棒(NiCu-FeOOH)可以作为AOR催化剂,其具有高效的催化活性(阳极电流密度达到10 mA cm^(-2)时执行电压为1.41 V)和在氨碱溶液中优异的稳定性.实验数据和理论计算结果表明,异质的Ni和Cu原子的协同作用使得NiCu-FeOOH表面的Ni和Fe位点表现出更合适的电子结构,他们可以共同吸附含氮中间产物和羟基,并使其吸附自由能位于火山形曲线的顶部,从而加速AOR脱氢.决速步骤的后移(*NH_(2)+*OH形成步骤移至*N_(2)H_(3)+*OH形成步骤)和决速步骤较低的能垒(0.86 eV)揭示了Ni和Cu的共掺策略使FeOOH晶体对催化AOR更具活性.本文创新地提出了涉及含氮中间物和羟基的共吸附反应途径,以更好地描述和模拟AOR过程,这为设计低成本和稳定的AOR催化剂开辟了新的路径.
基金supported by grants from the National Natural Science Foundation of China (Nos. 21401215, 21473254)the Special Project Fund of "Taishan Scholars" of Shandong Province (No. ts201511017)
文摘Zirconium metal-organic frameworks(Zr-MOFs) represent the most promising candidates among MOFs for industrial utilizations owing to their high porosity and excellent stability. However, the efficient synthesis of Zr-MOFs combining with continuous production, high productivity and good product quality still remains a critical issue for practical applications. Herein, we report an efficient method of synthesizing a series of Zr-MOFs through a microdroplet flow reaction, which is more accommodate the requirements of industrial production. Four types of Zr-based MOFs with different ligands and topologies(MOF-801, MOF-804, DUT-67 and MOF-808) were produced as a pure phase of high quality crystalline with uniform morphologies. Furthermore, this series of Zr-MOFs were obtained in a continuous way and at a space-time yield(STY) highly up to 367.2 kg m-3 d-1. These MOFs exhibit the similar pore structure and thermal stability with that prepared from conventional solvothermal synthesis. CO2 sorption studies on these MOFs demonstrate that the hydroxyl groups on ligand can render MOFs with high CO2/N2 selectivity.
