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高阳炼焦煤碳、氧结构研究与光谱学表征 被引量:7
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作者 葛涛 WANG Meng +2 位作者 李芬 闵凡飞 张明旭 《煤炭学报》 EI CAS CSCD 北大核心 2021年第3期1024-1031,共8页
通过对山西高阳炼焦煤煤质分析及^(13)C交叉极化/魔角旋转-核磁共振(^(13)C CP/MASNMR)、傅里叶红外光谱(FTIR)、X射线光电子能谱(XPS)的联合解析,获取煤中芳香结构、脂肪结构、羟基基团、含氧官能团结构特征,以及芳碳率、芳氢率、芳核... 通过对山西高阳炼焦煤煤质分析及^(13)C交叉极化/魔角旋转-核磁共振(^(13)C CP/MASNMR)、傅里叶红外光谱(FTIR)、X射线光电子能谱(XPS)的联合解析,获取煤中芳香结构、脂肪结构、羟基基团、含氧官能团结构特征,以及芳碳率、芳氢率、芳核平均结构尺寸(Xb)等煤结构单元基本参数。研究结果表明,高阳炼焦煤中芳碳率为0.73~0.77,芳核平均结构尺寸Xb为0.43。苯环五取代、苯环四取代和苯环三取代是高阳煤中主要的芳香烃结构,占比分别为41.42%,30.65%和19.82%。亚甲基是高阳煤中最主要的脂肪烃结构,占比达到41.85%,甲基和次甲基含量分别为29.86%,28.29%,说明煤中含有较多的烷基侧链和环状脂肪烃。羰基和酚羟基是煤中最主要的含氧官能团,与芳环上π电子形成的羟基π氢键占煤中羟基结构的73.20%。在芳香烃碳原子个数为118的高阳炼焦煤分子模型中,脂肪烃碳原子个数为25~32,其中,甲基碳、亚甲基碳、次甲基碳、羰基和羧基的个数分别为7~8,9~11,6~8,5。氧原子个数为7,其中,羰基和酚羟基为6个,醚氧键和有机硫中的砜或者亚砜结构共用1个氧原子。构建高阳炼焦煤精准大分子模型需要更多的碳、氧原子个数,因此,必须对煤中硫、氮等杂原子结构做进一步的分析。 展开更多
关键词 碳、氧结构 炼焦煤 光谱学 ^13C交叉极化/魔角旋转-核磁共振 傅里叶红外光谱 X射线光电子能谱
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Red-blood-cell-like nitrogen-doped porous carbon as an efficient metal-free catalyst for oxygen reduction reaction 被引量:2
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作者 WANG Li-ping TIAN Jing +5 位作者 LI Jing-sha ZENG Xian-guang PENG Zhi-guang HUANG Xiao-bing TANG You-gen WANG Hai-yan 《Journal of Central South University》 SCIE EI CAS CSCD 2019年第6期1458-1468,共11页
A red-blood-cell-like nitrogen-doped porous carbon catalyst with a high nitrogen content(9.81%)and specific surface area(631.46 m^2/g)was prepared by using melamine cyanuric acid and glucose as sacrificial template an... A red-blood-cell-like nitrogen-doped porous carbon catalyst with a high nitrogen content(9.81%)and specific surface area(631.46 m^2/g)was prepared by using melamine cyanuric acid and glucose as sacrificial template and carbon source,respectively.This catalyst has a comparable onset potential and a higher diffusion-limiting current density than the commercial 20 wt%Pt/C catalyst in alkaline electrolyte.The oxygen reduction reaction mechanism catalyzed by this catalyst is mainly through a 4e pathway process.The excellent catalytic activity could origin from the synergistic effect of the in-situ doped nitrogen(up to 9.81%)and three-dimensional(3D)porous network structure with high specific surface area,which is conducive to the exposure of more active sites.It is interesting to note that the catalytic activity of oxygen reduction strongly depends on the proportion of graphic N rather than the total N content. 展开更多
关键词 oxygen reduction reaction nitrogen-doped carbon porous structure red-blood-cell-like morphology
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Influence of thermal ageing on oxidation performance and nanostructures of dry soot in diesel engine
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作者 MENG Zhong-wei LI Jian +5 位作者 ZHANG Qian HUANG Jun-feng JIANG Yuan QIN Yuan G G CHASE FANG Jia 《Journal of Central South University》 SCIE EI CAS CSCD 2021年第7期2206-2220,共15页
Diesel soot subjected to high exhaust temperature suffers from thermal ageing,which is difficult to be removed by regeneration process.Based on the thermogravimetric(TG)analysis and images by high resolution transmiss... Diesel soot subjected to high exhaust temperature suffers from thermal ageing,which is difficult to be removed by regeneration process.Based on the thermogravimetric(TG)analysis and images by high resolution transmission electron microscope(HRTEM),effects of thermal ageing temperature,ageing time and oxygen concentration on oxidation characteristic of soot are investigated.The activation energy of soot increases with the increase of ageing temperature and oxygen concentration.The activation energy increases rapidly when the ageing time is less than 45 min,and then it keeps in a value of 157 kJ/mol when the ageing time is between 45 and 60 min.Compared to the soot without thermal ageing,the shape of ageing soot particles presents shorter diameter and more regular circle by observing soot nanostructure.With the increase of ageing temperature,ageing time and oxygen concentration,the more stable structure of“shell and core”is shown in the basic carbon.The soot has an increased fringe length,decreased tortuosity and separation distance after thermal ageing process,which leads to the deepening of the disorder degree of soot nanostructures and reduction of soot oxidation activity.Consequently,the thermal ageing process should be avoided in order to optimize the active regeneration strategy. 展开更多
关键词 thermal ageing oxidation performance soot nanostructure activation energy
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