氨热解纤维素生成甲烷的同时得到氮掺杂纳米多孔碳。

Pyrolysis of cellulose under ammonia leads to nitrogen-doped nanoporous carbon generated through methane formation.

机构信息

Department of Chemistry, Oregon State University , Corvallis, Oregon 97331, United States.

出版信息

Nano Lett. 2014;14(4):2225-9. doi: 10.1021/nl500859p. Epub 2014 Apr 1.

Abstract

Here, we present a simple one-step fabrication methodology for nitrogen-doped (N-doped) nanoporous carbon membranes via annealing cellulose filter paper under NH3. We found that nitrogen doping (up to 10.3 at %) occurs during cellulose pyrolysis under NH3 at as low as 550 °C. At 700 °C or above, N-doped carbon further reacts with NH3, resulting in a large surface area (up to 1973.3 m(2)/g). We discovered that the doped nitrogen, in fact, plays an important role in the reaction, leading to carbon gasification. CH4 was experimentally detected by mass spectrometry as a product in the reaction between N-doped carbon and NH3. When compared to conventional activated carbon (1533.6 m(2)/g), the N-doped nanoporous carbon (1326.5 m(2)/g) exhibits more than double the unit area capacitance (90 vs 41 mF/m(2)).

摘要

在这里，我们提出了一种简单的一步法制备氮掺杂（N 掺杂）纳米多孔碳膜的方法，即在 NH3 下对纤维素滤纸进行退火处理。我们发现，在 NH3 下，纤维素的热解过程中会发生氮掺杂（高达 10.3 at%），其温度低至 550°C。在 700°C 或更高温度下，N 掺杂的碳与 NH3 进一步反应，导致比表面积增大（高达 1973.3 m2/g）。我们发现，掺杂的氮实际上在反应中起着重要作用，导致碳的气化。通过质谱法实验检测到了掺杂氮碳和 NH3 反应的产物 CH4。与传统活性炭（1533.6 m2/g）相比，N 掺杂纳米多孔碳（1326.5 m2/g）的单位面积电容高出一倍以上（90 与 41 mF/m2）。

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氨热解纤维素生成甲烷的同时得到氮掺杂纳米多孔碳。

Pyrolysis of cellulose under ammonia leads to nitrogen-doped nanoporous carbon generated through methane formation.

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