Chemical looping gasification characteristics of biomass pyrolysis volatiles with Cu/Ni/olivine oxygen carrier for hydrogen-rich gas

Hairat Abduhani; Yalkunjan Tursun; Zhenghua Dai; Mei Zhong; Xueli Huang; Noritatsu Tsubaki; Jian Li; Yang Liu; Lijun Jin

doi:10.1016/j.energy.2024.134209

Chemical looping gasification characteristics of biomass pyrolysis volatiles with Cu/Ni/olivine oxygen carrier for hydrogen-rich gas

Hairat Abduhani, Yalkunjan Tursun^*, Zhenghua Dai, Mei Zhong, Xueli Huang, Noritatsu Tsubaki, Jian Li, Yang Liu, Lijun Jin

^*Corresponding author for this work

Applied Chemistry

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

This work systematically investigated the reaction characteristics of cotton stalk pyrolysis volatiles with CuO and NiO loaded on olivine (Cu/Ni/O) aiming to produce hydrogen-rich gas. The effect of pyrolysis temperature, gasification temperature, and oxygen carrier to biomass ratio (OC/B) on tar content, gas yield, carbon conversion has been investigated. Lattice oxygen donation capability and catalytic performance of OC was evaluated by comparing the Biomass Chemical Looping Gasification (BCLG) and catalytic gasification. Furthermore, the distribution of oxygen in the pyrolysis products and the distribution of lattice oxygen in the gasification products were investigated. The results indicate that cotton stalk pyrolysis tar is mainly composed of phenolic compounds. The OC can not only decompose most of cyclic compounds but also further reduce the content of monocyclic compounds to hydrogen-rich gas. The release of lattice oxygen from Cu/Ni/O was 56.2 %, which decreased to 47.7 % when steam was introduced at 800 °C. A H₂ concentration of 50.4 % and a H₂ yield of 0.57 Nm³/kg were achieved by both the reaction of tar reforming and the reaction of steam with reduced Fe in Cu/Ni/O. These findings offer new insights and a theoretical foundation for a detailed understanding of the BCLG.

Original language	English
Article number	134209
Journal	Energy
Volume	314
DOIs	https://doi.org/10.1016/j.energy.2024.134209
State	Published - 2025/01/01

Keywords

Biomass chemical looping gasification
Biomass volatiles
Cu/Ni/olivine
Lattice oxygen
Tar

ASJC Scopus subject areas

Civil and Structural Engineering
Modeling and Simulation
Renewable Energy, Sustainability and the Environment
Building and Construction
Fuel Technology
Energy Engineering and Power Technology
Pollution
Mechanical Engineering
General Energy
Management, Monitoring, Policy and Law
Industrial and Manufacturing Engineering
Electrical and Electronic Engineering

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.energy.2024.134209

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@article{30f6c2cd8e8e493a81aa82dd5c4804be,

title = "Chemical looping gasification characteristics of biomass pyrolysis volatiles with Cu/Ni/olivine oxygen carrier for hydrogen-rich gas",

abstract = "This work systematically investigated the reaction characteristics of cotton stalk pyrolysis volatiles with CuO and NiO loaded on olivine (Cu/Ni/O) aiming to produce hydrogen-rich gas. The effect of pyrolysis temperature, gasification temperature, and oxygen carrier to biomass ratio (OC/B) on tar content, gas yield, carbon conversion has been investigated. Lattice oxygen donation capability and catalytic performance of OC was evaluated by comparing the Biomass Chemical Looping Gasification (BCLG) and catalytic gasification. Furthermore, the distribution of oxygen in the pyrolysis products and the distribution of lattice oxygen in the gasification products were investigated. The results indicate that cotton stalk pyrolysis tar is mainly composed of phenolic compounds. The OC can not only decompose most of cyclic compounds but also further reduce the content of monocyclic compounds to hydrogen-rich gas. The release of lattice oxygen from Cu/Ni/O was 56.2 %, which decreased to 47.7 % when steam was introduced at 800 °C. A H2 concentration of 50.4 % and a H2 yield of 0.57 Nm3/kg were achieved by both the reaction of tar reforming and the reaction of steam with reduced Fe in Cu/Ni/O. These findings offer new insights and a theoretical foundation for a detailed understanding of the BCLG.",

keywords = "Biomass chemical looping gasification, Biomass volatiles, Cu/Ni/olivine, Lattice oxygen, Tar",

author = "Hairat Abduhani and Yalkunjan Tursun and Zhenghua Dai and Mei Zhong and Xueli Huang and Noritatsu Tsubaki and Jian Li and Yang Liu and Lijun Jin",

note = "Publisher Copyright: {\textcopyright} 2024 Elsevier Ltd",

year = "2025",

month = jan,

day = "1",

doi = "10.1016/j.energy.2024.134209",

language = "英語",

volume = "314",

journal = "Energy",

issn = "0360-5442",

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TY - JOUR

T1 - Chemical looping gasification characteristics of biomass pyrolysis volatiles with Cu/Ni/olivine oxygen carrier for hydrogen-rich gas

AU - Abduhani, Hairat

AU - Tursun, Yalkunjan

AU - Dai, Zhenghua

AU - Zhong, Mei

AU - Huang, Xueli

AU - Tsubaki, Noritatsu

AU - Li, Jian

AU - Liu, Yang

AU - Jin, Lijun

PY - 2025/1/1

Y1 - 2025/1/1

N2 - This work systematically investigated the reaction characteristics of cotton stalk pyrolysis volatiles with CuO and NiO loaded on olivine (Cu/Ni/O) aiming to produce hydrogen-rich gas. The effect of pyrolysis temperature, gasification temperature, and oxygen carrier to biomass ratio (OC/B) on tar content, gas yield, carbon conversion has been investigated. Lattice oxygen donation capability and catalytic performance of OC was evaluated by comparing the Biomass Chemical Looping Gasification (BCLG) and catalytic gasification. Furthermore, the distribution of oxygen in the pyrolysis products and the distribution of lattice oxygen in the gasification products were investigated. The results indicate that cotton stalk pyrolysis tar is mainly composed of phenolic compounds. The OC can not only decompose most of cyclic compounds but also further reduce the content of monocyclic compounds to hydrogen-rich gas. The release of lattice oxygen from Cu/Ni/O was 56.2 %, which decreased to 47.7 % when steam was introduced at 800 °C. A H2 concentration of 50.4 % and a H2 yield of 0.57 Nm3/kg were achieved by both the reaction of tar reforming and the reaction of steam with reduced Fe in Cu/Ni/O. These findings offer new insights and a theoretical foundation for a detailed understanding of the BCLG.

AB - This work systematically investigated the reaction characteristics of cotton stalk pyrolysis volatiles with CuO and NiO loaded on olivine (Cu/Ni/O) aiming to produce hydrogen-rich gas. The effect of pyrolysis temperature, gasification temperature, and oxygen carrier to biomass ratio (OC/B) on tar content, gas yield, carbon conversion has been investigated. Lattice oxygen donation capability and catalytic performance of OC was evaluated by comparing the Biomass Chemical Looping Gasification (BCLG) and catalytic gasification. Furthermore, the distribution of oxygen in the pyrolysis products and the distribution of lattice oxygen in the gasification products were investigated. The results indicate that cotton stalk pyrolysis tar is mainly composed of phenolic compounds. The OC can not only decompose most of cyclic compounds but also further reduce the content of monocyclic compounds to hydrogen-rich gas. The release of lattice oxygen from Cu/Ni/O was 56.2 %, which decreased to 47.7 % when steam was introduced at 800 °C. A H2 concentration of 50.4 % and a H2 yield of 0.57 Nm3/kg were achieved by both the reaction of tar reforming and the reaction of steam with reduced Fe in Cu/Ni/O. These findings offer new insights and a theoretical foundation for a detailed understanding of the BCLG.

KW - Biomass chemical looping gasification

KW - Biomass volatiles

KW - Cu/Ni/olivine

KW - Lattice oxygen

KW - Tar

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DO - 10.1016/j.energy.2024.134209

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SN - 0360-5442

VL - 314

JO - Energy

JF - Energy

M1 - 134209

ER -

Chemical looping gasification characteristics of biomass pyrolysis volatiles with Cu/Ni/olivine oxygen carrier for hydrogen-rich gas

Abstract

Keywords

ASJC Scopus subject areas

UN SDGs

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