Effect of Pyrolysis Temperature on the Production of Biochar and Biomethanol from Sugarcane Bagasse

IF 3.1 3区工程技术 Q3 ENERGY & FUELS

BioEnergy Research Pub Date : 2024-02-23 DOI:10.1007/s12155-024-10733-8

Peter Gabriel Almeida Souza, Jaqueline do Carmo Lima Carvalho, Lorrana Zelia Martins de Souza, Evaneide Nascimento Lima, Mariana Guerra de Aguilar, Robson Pereira Lima, Osania Emerenciano Ferreira, Lúcia Pinheiro Santos Pimenta, Alan Rodrigues Teixeira Machado

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Abstract

Biochar is recognized for its potential in mitigating climate change, especially through carbon sequestration and soil improvement. To this end, it is important to use all co-products from pyrolysis in a sustainable and economically viable way. In this study, the conversion of sugarcane bagasse at varying pyrolysis temperatures was investigated using ¹H NMR spectroscopy and Chenomx for liquid fraction analysis. The yield of biochar decreased significantly from 45.3 to 3.5% with a temperature increase of 300 to 1000 °C. The morphological analysis revealed that biochar produced at lower temperatures (300 °C and 400 °C) showed tubular and spongy structures, whereas at higher temperatures (600 °C and 800 °C), the structures morphed into holes and thinned further, ultimately degrading further at 1000 °C. All samples of biochar showed characteristics promising for soil improvement and carbon sequestration (O/C < 0.4). The analysis of liquid fractions revealed that biomethanol reached its highest concentration of 19.28 mM at 800 °C, which coincided with the highest production of acetic and lactic acids. Additionally, the highest concentration of acetone was observed at 600 °C. These findings highlight the importance of optimizing pyrolysis conditions for enhanced yields of biochar and platform compounds, as well as the potential of the NMR and Chenomx in bioenergy research.

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热解温度对利用甘蔗渣生产生物炭和生物甲醇的影响

生物炭被认为具有减缓气候变化的潜力，特别是通过碳固存和土壤改良。为此，必须以可持续和经济可行的方式利用热解产生的所有副产品。本研究使用 1H NMR 光谱法和 Chenomx 液体馏分分析法研究了甘蔗渣在不同热解温度下的转化情况。随着温度升高 300 至 1000 °C，生物炭的产量从 45.3% 显著下降到 3.5%。形态分析表明，在较低温度（300 ℃ 和 400 ℃）下产生的生物炭呈现管状和海绵状结构，而在较高温度（600 ℃ 和 800 ℃）下，这些结构变形为孔洞并进一步变薄，最终在 1000 ℃ 时进一步降解。所有生物炭样品都显示出有望改良土壤和固碳的特性（O/C < 0.4）。对液体馏分的分析表明，生物甲醇在 800 °C 时达到最高浓度 19.28 mM，同时醋酸和乳酸的产量也最高。此外，在 600 °C 时丙酮的浓度最高。这些发现强调了优化热解条件以提高生物炭和平台化合物产量的重要性，以及 NMR 和 Chenomx 在生物能源研究中的潜力。

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来源期刊

BioEnergy Research ENERGY & FUELS-ENVIRONMENTAL SCIENCES

CiteScore

6.70

自引率

8.30%

发文量

174

审稿时长

3 months

期刊介绍： BioEnergy Research fills a void in the rapidly growing area of feedstock biology research related to biomass, biofuels, and bioenergy. The journal publishes a wide range of articles, including peer-reviewed scientific research, reviews, perspectives and commentary, industry news, and government policy updates. Its coverage brings together a uniquely broad combination of disciplines with a common focus on feedstock biology and science, related to biomass, biofeedstock, and bioenergy production.