Synthesis of Hydroxy-Sodalite from Rice Husk Silica and Food-Grade Aluminum Foil as A Catalyst for Biomass Pyrolysis

Authors

  • Kamisah Delilawati Pandiangan Department of Chemistry, Faculty of Mathematics and Natural Science, Lampung University, Lampung 35141, Indonesia
  • Wasinton Simanjuntak Department of Chemistry, Faculty of Mathematics and Natural Science, Lampung University, Lampung 35141, Indonesia
  • Dira Avista Department of Chemistry, Faculty of Mathematics and Natural Science, Lampung University, Lampung 35141, Indonesia
  • Ahmad Gilang Arinanda Department of Chemistry, Faculty of Mathematics and Natural Science, Lampung University, Lampung 35141, Indonesia
  • Sutopo Hadi Department of Chemistry, Faculty of Mathematics and Natural Science, Lampung University, Lampung 35141, Indonesia
  • Hanif Amrulloh Department of Islamic Primary School Teacher Education, Faculty of Tarbiya, Institut Agama Islam Ma’arif NU (IAIMNU) Metro Lampung, Lampung 34114, Indonesia

DOI:

https://doi.org/10.48048/tis.2022.6252

Keywords:

Hydroxy sodalite, Hydrothermal, Pyrolysis, Water hyacinth, Cassava solid waste, Rice husk, BCO

Abstract

In this research, food-grade aluminum foil (FGAF), rice husk silica (RHS), and sodium hydroxide were needed to synthesize hydroxy-sodalite (HS) using hydrothermal method. The raw materials were exposed to crystallization at 100 °C for 72, 96 and 120 h, and followed by calcination for 6 h at 550 °C.  The products obtained were identified using X-ray diffraction (XRD) and scanning electron microscope (SEM) technique, and it applied as catalysts for pyrolysis of biomass. The bio-crude oils (BCO) produced were investigated adopting gas chromatography-mass spectrometry (GC-MS). The XRD results reveal that the products obtained with the crystallization time of 72 and 96 h are a mixture of zeolite A and HS and practically pure HS with a crystallization time of 120 h. The shapes of particles as displayed by SEM are in good agreement with the results of others. The main components of the BCO produced are hydrocarbons, with the biogasoline contents in the range of 81.67 - 96.24 % was resulted from the mixture of water hyacinth and palm oil, and 72.92 - 92.58 % from the mixture of cassava solid waste and palm oil.  In this respect, it can be concluded HS is a prospective catalyst for the pyrolysis of biomass.

HIGHLIGHTS

  • Hydroxy sodalite zeolites were synthesized from rice husk silica and food-grade aluminum foil using hydrothermal method at different temperatures
  • Formation of hydroxy sodalite was confirmed by characterizations using XRD and SEM techniques
  • Hydroxy sodalite zeolites produced were applied as catalyst for pyrolysis of a mixture of cassava solid waste with palm oil and a mixture of water hyacinth with palm oil
  • The bio crude oils produced from the pyrolysis experiments were characterized using GC-MS technique to identify their chemical components

GRAPHICAL ABSTRACT

Downloads

Download data is not yet available.

Metrics

Metrics Loading ...

References

J Luo, H Zhang and J Yang. Hydrothermal synthesis of sodalite on alkali-activated coal fly ash for removal of lead ions. Procedia Environ. Sci. 2016; 31, 605-14.

S Golbad, P Khoshnoud and N Abu-Zahra. Hydrothermal synthesis of hydroxy sodalite from fly ash for the removal of lead ions from water. Int. J. Environ. Sci. Tech. 2017; 14, 135-42.

M Esaifan, LN Warr, G Grathoff, T Meyer, MT Schafmeister, A Kruth and H Testrich. Synthesis of hydroxy-sodalite/cancrinite zeolites from calcite-bearing kaolin for the removal of heavy metal ions in aqueous media. Minerals 2019; 9, 484.

LT Nanganoa, KJ Mbadcam and S Kang. Synthesis of hydroxy-sodalite from fine fractions of sandy clay loam soil (Natural aluminosilicate). Int. J. Chem. Tech. Res. 2016; 9, 725-32.

F Teimouri, SH Khezri and J Azizian. Hydroxy sodalite zeolite as a recyclable catalyst for the green synthesis of tetrahydrobenzo[b]pyrans via one-pot three-component condensation reaction. Iranian J. Catal. 2015; 5, 253-9.

TC Aniokete, M Ozonoh and MO Daramola. Synthesis of pure and high surface area sodalite catalyst from waste industrial brine and coal fly ash for conversion of waste cooking oil (WCO) to biodiesel. Int. J. Renew. Energ. Res. 2019; 9, 1924-37.

JM Shabani, O Babajide, O Oyekola and L Petrik. Synthesis of hydroxy sodalite from coal fly ash for biodiesel production from waste-derived maggot oil. Catalysts 2019; 9, 1052.

N Kalantari, MJ Vaezi, M Yadollahi, AA Babaluo, B Bayati and A Kazemzadeh. Synthesis of nanostructure hydroxy sodalite composite membranes via hydrothermal method: Support surface modification and synthesis method effects. Asia Pac. J. Chem. Eng. 2015; 10, 45-55.

J Yu, C Qi, J Zhang, C Bao and H Xu. Synthesis of a zeolite membrane as a protective layer on a metallic Pd composite membrane for hydrogen purification. J. Mater. Chem. A 2015; 3, 5000-6.

M Matsukata and E Kikuchi. Zeolitic Membranes: Synthesis, properties, and prospects. Bull. Chem. Soc. Jpn. 1997; 70, 2341-56.

J Hedlund, J Sterte, M Anthonis, AJ Bons, B Carstensen, N Corcoran, D Cox, H Deckman, WD Gijnst, PPD Moor, F Lai, J Mchenry, W Mortier, J Reinoso and J Peters. High-flux MFI membranes. Microporous Mesoporous Mater. 2002; 52, 179-89.

JE Lewis, GR Gavalas and ME Davis. Permeation studies on oriented single-crystal ferrierite Membranes. AIChE J. 1997; 43, 83-90.

A Adeleke, P Ikubanni, J Odusote, T Orhadahwe, O Lasode, S Adegoke and O Adesina. Evaluation of non-isothermal kinetic parameters for pyrolysis of teak wood using model-fitting techniques. Trends Sci. 2021; 18, 1432.

B Liu, H Sun, T Peng and Q He. One-step synthesis of hydroxysodalite using natural bentonite at moderate temperatures. Minerals 2018; 8, 521.

W Franus, M Wdowin and M Franus. Synthesis and characterization of zeolites prepared from industrial fly ash. Environ. Monit. Assess. 2014; 186, 5721-9.

HC Ong, WH Chen, A Farooq, YY Gan, KT Lee and V Ashokkumar. Catalytic thermochemical conversion of biomass for biofuel production: A comprehensive review. Renew. Sustain. Energ. Rev. 2019; 113, 109266.

N Nishu, R Liu, M M Rahman, M Sarker, M Chai, C Li and J Cai. A review on the catalytic pyrolysis of biomass for the bio-oil production with ZSM-5: Focus on structure. Fuel Process. Tech. 2020; 199, 106301.

T Ennaert, JV Aelest, J Dijkmans, RD Clercq, W Schutyser, M Dusselier, D Verboekend and BF Sels. Potential and challenges of zeolite chemistry in the catalytic conversion of biomass. Chem. Soc. Rev. 2016; 45, 584-611.

X Chen, Q Che, S Li, Z Liu, H Yang, Y Chen, X Wang, J Shao and H Chen. Recent developments in lignocellulosic biomass catalytic fast pyrolysis: Strategies for the optimization of bio-oil quality and yield. Fuel Process. Tech. 2019; 196, 106180.

PR Bhoi, AS Ouedraogo, V Soloiu and R Quirino. Recent advances on catalysts for improving hydrocarbon compounds in bio-oil of biomass catalytic pyrolysis. Renew. Sustain. Energ. Rev. 2020; 121, 109676.

PS Rezaei, H Shafaghat and WMAW Daud. Production of green aromatics and olefins by catalytic cracking of oxygenate compounds derived from biomass pyrolysis: A review. Appl. Catal. Gen. 2014; 469, 490-511.

J Liang, G Shan and Y Sun. Catalytic fast pyrolysis of lignocellulosic biomass: Critical role of zeolite catalysts. Renew. Sustain. Energ. Rev. 2021; 139, 110707.

W Simanjuntak, H Satria and N Utami. Production of reducing sugar from cassava solid waste by simultaneous ultrasonication and acid hydrolysis. Indonesian J. Chem. 2014; 14, 233-8.

RA Wahyuono, MN Hakim and SA Santoso. Feasibility study on the production of bioethanol from tapioca solid waste to meet the national demand of biofuel. Energ. Procedia 2015; 65, 324-30.

B Tabah, IN Pulidindi, VR Chitturi, LMR Arava, AVarvak, E Foran and A Gedanken. Solar-energy-driven conversion of biomass to bioethanol: A sustainable approach. J. Mater. Chem. A 2017; 5, 15486-506.

DG Martinez, A Feiden, R Bariccatti and KRDF Zara. Ethanol production from waste of cassava processing. Appl. Sci. 2018; 8, 2158.

YS Kurniawan, KTA Priyangga, PA Krisbiantoro and AC Imawan. Green chemistry influences in organic synthesis : A review. J. Multidiscip Appl. Nat. Sci. 2021; 1, 1-12.

SH Yan, W Song and JY Guo. Advances in management and utilization of invasive water hyacinth (Eichhornia crassipes) in aquatic ecosystems-a review. Crit. Rev. Biotechnol. 2017; 37, 218-28.

JA Mukarugwiro, SW Newete, E Adam, F Nsanganwimana, K Abutaleb and MJ Byrne. Mapping spatio-temporal variations in water hyacinth (Eichhornia crassipes) coverage on Rwandan water bodies using multispectral imageries. Int. J. Environ. Sci. Tech. 18, 275-86.

LS Buller, E Ortega, I Bergier, JM Mesa-Pérez, SM Salis and CA Luengo. Sustainability assessment of water hyacinth fast pyrolysis in the upper Paraguay River basin, Brazil. Sci. Total Environ. 2015; 532, 281-91.

LO Santos, FF Silva, LC Santos, ISC Carregosa and A Wisniewski. Potential bio-oil production from invasive aquatic plants by microscale pyrolysis studies. J. Braz. Chem. Soc. 2018; 29, 151-8.

H Gulab, K Hussain, S Malik and M Hussain. Effect of process conditions on Bio-oil composition and production from catalytic pyrolysis of water hyacinth biomaѕѕ. Waste Biomass Valorization 2019; 10, 2595-609.

MK Naskar, D Kundu and M Chatterjee. Coral-like hydroxy sodalite particles from rice husk ash as silica source. Mater. Lett. 2011; 65, 3408-10.

H Yu, J Shen, J Li, X Sun, W Han, X Liu and L Wang. Preparation, characterization and adsorption properties of sodalite pellets. Mater. Lett. 2014; 132, 259-62.

C Belviso, A Lettino and F Cavalcante. Influence of synthesis method on LTA time-dependent stability. Molecules 2018; 23, 2122.

B Biswas, R Singh, BB Krishna, J Kumar and T Bhaskar. Pyrolysis of azolla, sargassum tenerrimum and water hyacinth for production of bio-oil. Bioresource Tech. 2017; 242, 139-45.

H Huang, J Liu, H Liu, F Evrendilek and M Buyukada. Pyrolysis of water hyacinth biomass parts: Bioenergy, gas emissions, and by-products using TG-FTIR and Py-GC/MS analyses. Energ. Convers. Manag. 2020; 207, 112552.

F Li, D Feng, H Deng, H Yu and C Ge. Effects of biochars prepared from cassava dregs on sorption behavior of ciprofloxacin. Procedia Environ. Sci. 2016; 31, 795-803.

SF Billa, TE Angwafo and AF Ngome. Agro-environmental characterization of biochar issued from crop wastes in the humid forest zone of Cameroon. Int. J. Recycl. Org. Waste Agr. 2019; 8, 1-13.

S Wijitkosum and P Jiwnok. Elemental composition of biochar obtained from agriculturalwaste for soil amendment and carbon sequestration. Appl. Sci. 2019; 9, 3980.

SY Foong, NSA Latiff, RK Liew, PNY Yek and SS Lam. Production of biochar for potential catalytic and energy applications via microwave vacuum pyrolysis conversion of cassava stem. Mater. Sci. Energ. Tech. 2020; 3, 728-33.

A Pattiya, S Sukkasi and V Goodwin. Fast pyrolysis of sugarcane and cassava residues in a free-fall reactor. Energy 2012; 44, 1067-77.

J Zhang, J Gu, H Yuan and Y Chen. Thermal behaviors and kinetics for fast pyrolysis of chemical pretreated waste cassava residues. Energy 2020; 208, 118192.

T Nonchana and K Pianthong. Bio-oil synthesis from cassava pulp via hydrothermal liquefaction: Effects of catalysts and operating conditions. Int. J. Renew. Energ. Dev. 2020; 9, 329-37.

Downloads

Published

2022-10-14

How to Cite

Pandiangan, K. D. ., Simanjuntak, W. ., Avista, D. ., Arinanda, A. G. ., Hadi, S. ., & Amrulloh, H. . (2022). Synthesis of Hydroxy-Sodalite from Rice Husk Silica and Food-Grade Aluminum Foil as A Catalyst for Biomass Pyrolysis. Trends in Sciences, 19(20), 6252. https://doi.org/10.48048/tis.2022.6252

Issue

Vol. 19 No. 20 (2022): Trends in Sciences, Volume 19, Number 20, 15 October 2022

Section

Research Articles

License

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

Most read articles by the same author(s)