Co-production of biochar and carbon nanotube from sewage sludge in a two-stage process coupling pyrolysis and catalytic chemical vapor deposition

Waste Disposal & Sustainable Energy Pub Date : 2024-03-26 DOI:10.1007/s42768-024-00194-2

Mohd Syazwan Mohd Ghazali, Mohd Saufi Md Zaini, Muhammad Arshad, Syed Shatir A. Syed-Hassan

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Abstract

This study explores the potential of valorizing sewage sludge as a carbon source for the co-production of biochar and carbon nanomaterial via a two-stage thermal-catalytic process. In the first stage, sewage sludge underwent slow pyrolysis, resulting in a biochar yield of 66% (in weight) at 550 °C. The resulting pyrolysis vapor was then introduced into a second reactor, where catalytic chemical vapor deposition (CCVD) took place in the presence of a cobalt catalyst, leading to the production of carbon nanotubes (CNTs). It was found that CNTs with an inner diameter of ~ 3.2 nm and an outer diameter of 20–40 nm can be formed in the second stage reactor at temperatures between 650 °C and 950 °C with a maximum yield of 30% (in weight) under the employed experimental conditions. The obtained CNTs displayed a multiwall structure, exhibited a lack of crystallinity, and demonstrated a high level of disorder. The research findings also indicate that temperature exerts a significant influence on both the yield and properties of the CNTs synthesized.

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通过热解和催化化学气相沉积两阶段工艺从污水污泥中联合生产生物炭和碳纳米管

本研究探讨了通过两阶段热催化工艺将污水污泥作为碳源用于联合生产生物炭和碳纳米材料的潜力。在第一阶段，污水污泥经过缓慢热解，在 550 °C 的温度下产生了 66% 的生物炭（按重量计）。然后将热解产生的蒸汽引入第二个反应器，在钴催化剂的作用下进行催化化学气相沉积（CCVD），从而产生碳纳米管（CNTs）。研究发现，在采用的实验条件下，第二阶段反应器的温度介于 650 ℃ 和 950 ℃ 之间，可形成内径约为 3.2 nm、外径为 20-40 nm 的碳纳米管，最大产率为 30%（按重量计）。所获得的 CNT 具有多壁结构，缺乏结晶性，并表现出高度的无序性。研究结果还表明，温度对合成的碳纳米管的产率和性能都有显著影响。

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Waste Disposal & Sustainable Energy

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