安东竹叶中介孔生物二氧化硅催化剂的直接热解反应

IF 0.5 Q4 EDUCATION & EDUCATIONAL RESEARCH

Rasayan Journal of Chemistry Pub Date : 2023-01-01 DOI:10.31788/rjc.2023.1618126

L. Efiyanti, N. Saputra, D. A. Indrawan, I. Winarni, B. Pranoto, N. Hastuti, Z. Fadhlulloh, Y. Rahayuningsih, S. Wibowo, S. Darmawan, Yuniawati, Gusmailina, S. Komarayati, D. Hendra, G. Pari

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引用次数: 0

摘要

二氧化硅是一种具有广泛用途的功能材料，包括用作催化剂。用天然二氧化硅替代合成二氧化硅是支持绿色科技和经济发展的必要条件。采用酸碱溶液和十六烷基三甲基溴化铵(CTAB)模板结构从竹叶废料中提取二氧化硅，得到介孔生物二氧化硅。然后将该介孔生物二氧化硅作为α-纤维素直接热解的生物催化剂。采用傅里叶变换红外光谱(FTIR)、表面积分析仪(SAA)、扫描电镜(SEM)、重量分析等方法对生物二氧化硅进行了表征，并利用热解气相色谱质谱法(Py-GCMS)在裂解过程中的应用进行了表征。CTAB添加量分为0.05:1、0.1:1和0.2:1三种变化。数据发现，以0.2:1的CTAB生物二氧化硅收率最高，竹灰和CTAB生物二氧化硅样品中二氧化硅含量分别为60%和90.5 ~ 93.6%。生物二氧化硅的表面酸度在1.97 ~ 2.1 mmol/g之间。形成的生物二氧化硅的基本基团是羟基、硅醇和硅氧烷基团，观察到二氧化硅的形态不规则，形成像珊瑚一样的聚集体。比例为0.05:1、0.1:1和0.2:1的生物二氧化硅比表面积分别为177.068 m2 /g、661.166 m2 /g和684.852 m2 /g，孔径分布服从中孔类。在CTAB值分别为0.05:1、0.1:1和0.2:1的条件下，生物硅催化剂对α-纤维素进行py-GCMS裂解，得到的烃含量为44.88%;61.6%;和30.4%。

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THE MESOPOROUS BIOSILICA CATALYST FROM ANDONG BAMBOO LEAF FOR DIRECT-PYROLYSIS REACTION

Silica is a functional material with broad benefits, including as a catalyst. It is essential to substitute synthetic silica with natural silica to support green technology and economic development. The silica extraction process from bamboo leaf waste was carried out using an acid-base solution and a cetyltrimethylammonium bromide (CTAB) template structure to get mesoporous biosilica. This mesoporous biosilica was then applied as a biocatalyst for α-cellulose direct pyrolysis. Biosilica was characterized using various analyses including Fourier Transform Infrared Spectroscopy (FTIR), Surface Area Analyzer (SAA), Scanning Electron Microscope (SEM), gravimetric methods, and applications to the cracking process using Pyrolysis Gas Chromatography Mass Spectrometry (Py-GCMS). The CTAB addition is divided into three variations, namely 0.05:1, 0.1:1, and 0.2:1. The data found that the highest yield was produced in the CTAB biosilica 0.2:1, and the silica content in the bamboo ash and CTAB biosilica sample was 60% and 90.5- 93.6%, respectively. The surface acidity of the biosilica ranged from 1.97 and 2.1 mmol/g. The essential groups in the biosilica formed are hydroxyl, silanol, and siloxane groups, with the morphology of the silica being observed to be irregular in shape, forming aggregates like coral. The surface area of biosilica with the ratio of 0.05:1, 0.1:1, and 0.2:1 was 177.068 m2 /g, 661.166 m2 /g, and 684.852 m2 /g, respectively, with a pore size distribution following the mesoporous class. The α-cellulose cracking using py-GCMS with a biosilica catalyst at CTAB variations of 0.05:1, 0.1:1, and 0.2:1 yielded a hydrocarbon content of 44.88%; 61.6%; and 30.4%.

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来源期刊

Rasayan Journal of Chemistry Energy-Energy (all)

CiteScore

1.90

自引率

0.00%

发文量

196

期刊介绍： RASĀYAN Journal of Chemistry [RJC] signifies a confluence of diverse streams of chemistry to stir up the cerebral powers of its contributors and readers. By introducing the journal by this name, we humbly intent to provide an open platform to all researchers, academicians and readers to showcase their ideas and research findings among the people of their own fraternity and to share their vast repository of knowledge and information. The journal seeks to embody the spirit of enquiry and innovation to augment the richness of existing chemistry literature and theories. We also aim towards making this journal an unparalleled reservoir of information and in process aspire to inculcate and expand the research aptitude.