Article
Chemistry, Applied
Doki Yamaguchi, Liangguang Tang, Jose Orellana, Trevor D. Hadley, Sankar Bhattacharya, Kok-Seng Lim
Summary: The study developed a compact fully looped chemical looping reactor and found that the CLC performance increased with increasing operation time over 36 hours, as indicated by the increase in the CO2/CO molar ratio. The morphology changes and ash interaction of the Australian ilmenite did not noticeably affect the CLC performance or operation during continuous operation.
FUEL PROCESSING TECHNOLOGY
(2021)
Article
Chemistry, Multidisciplinary
Qiuqi Liu, Dunyu Liu, Mingguo Ni, Kailong Xu, Jingjing Ma, Zhuang Liu, Jing Jin, Huancong Shi
Summary: This paper investigates the effects of different flue gas components on the transformation of mercury during the combustion of coal. The results show that HCl, NO, and CO2 promote the oxidation of elemental mercury (Hg-0) while SO2 inhibits its oxidation. The study also compares the oxidation efficiency of Hg-0 by eight commonly used oxygen carriers in chemical looping combustion (CLC). The findings indicate that the oxygen release capacity of the oxygen carriers influences the oxidation efficiency of Hg-0. O2 is identified as the core species affecting mercury transformation in CLC.
Article
Energy & Fuels
Ivana Stanicic, Joakim Brorsson, Anders Hellman, Tobias Mattisson, Rainer Backman
Summary: Chemical looping combustion (CLC) enables efficient combustion of hydrocarbon fuels while producing a gas stream with high CO2 concentrations. This paper investigates the fate of ash elements in a system using iron-based oxygen carriers and provides a comprehensive comparison with previous experimental data. The study finds that the choice of oxygen carriers significantly influences the behavior of ash elements.
Article
Energy & Fuels
A. Cabello, A. Abad, M. de las Obras Loscertales, P. Bartocci, F. Garcia-Labiano, L. F. de Diego
Summary: The aim of this study was to investigate the effect of increased operating pressure on the fuel conversion in chemical looping combustion systems using ilmenite as the oxygen carrier. Fluid dynamics and reaction kinetics were considered to determine suitable design parameters. The results showed that incomplete combustion occurred at atmospheric conditions, while some improvement was achieved at pressurized conditions, leading to higher energy efficiency.
Article
Engineering, Environmental
Ming Luo, Yanjun Qin, Jianjun Cai, Lili Qian, Shuxiang Wang, Haiyan Zhang, Lunzheng Zhou, Peng Liu
Summary: This study investigated the release and migration characteristics of sulfur in the chemical looping combustion of coal with two different synthetic oxygen carriers. The results showed that sulfur behavior varied under different conditions, with sulfur mainly migrating to metal sulfides at lower temperatures and peroxide coefficients.
PROCESS SAFETY AND ENVIRONMENTAL PROTECTION
(2021)
Article
Energy & Fuels
Yanan Wang, Hengfeng Bu, Haibo Zhao, Kunlei Liu
Summary: Solid fuel chemical looping gasification technology requires the development of low-cost, easily available oxygen carrier particles, with Cu/Fe-based OCs from waste ore particles and bauxite residues showing promise for coal gasification. Among these OCs, red mud and Cu20Fe80@C exhibit better gasification performance and potential for Fischer-Tropsch synthesis and H-2-rich chemical synthesis. The study also reveals the importance of lattice oxygen donation capacity and alkali metal content in determining coal and char gasification rates.
Article
Thermodynamics
Ying-jie Zhao, Yu-ke Zhang, Yang Cui, Yuan-yuan Duan, Yi Huang, Guo-qiang Wei, Usama Mohamed, Li-juan Shi, Qun Yi, William Nimmo
Summary: A coal chemical looping combustion (CLC) power plant with CO2 capture was established and validated, showing higher net energy efficiency, lower cost of electricity, and less coal consumption compared to a traditional MEA-based ultra-supercritical coal power plant. This was achieved through optimizing operation parameters and heat exchange networks, as well as utilizing in-situ CO2 capture, lower exergy destruction, and efficient energy integration and recovery.
Article
Energy & Fuels
Pietro Bartocci, Alberto Abad, Arturo Cabello Flores, Margarita de las Obras Loscertales
Summary: To address the scale-up challenges of Chemical Looping Processes, the development of efficient and affordable oxygen carriers is crucial. Ilmenite, an ore-derived oxygen carrier, has been identified as an abundant and low-cost option. This paper provides insights into its preparation, reactivity, and performance compared to other carriers, along with its thermodynamic properties and kinetics. The paper also explores its compatibility with various fuels (solid, liquid, gaseous, including biofuels) and discusses important considerations such as cost, environmental sustainability, oxygen transport capacity, as well as issues related to fluidized bed reactors, such as agglomeration and attrition behavior. Furthermore, the paper investigates the interaction between ilmenite and fuels, including the impact of impurities and coke deposition on the gasification rate of solid fuels.
Article
Chemistry, Applied
Ivan Gogolev, Toni Pikkarainen, Juho Kauppinen, Markus Hurskainen, Anders Lyngfelt
Summary: The chemical looping combustion of wood pellets, wood char, and straw pellets with different oxygen carriers was studied to investigate alkali emissions. Different fuel types and oxygen carriers had varying impacts on the particle size distributions and stable alkali species compositions. Thermodynamic modeling predicted the stability of different alkali species at 800 degrees Celsius for each fuel type.
FUEL PROCESSING TECHNOLOGY
(2022)
Article
Chemistry, Applied
Jinchen Ma, Xin Tian, Chaoquan Wang, Haibo Zhao, Zhaohui Liu, Chuguang Zheng
Summary: The study focused on the nitrogen conversion and distribution characteristics in the two elementary stages of coal conversion during the iG-CLC process. It was found that HCN was the dominant precursor of NOx in iG-CLC, and most NOx precursors were released during coal pyrolysis. The high CO2 concentration and reducing reaction atmosphere in the fuel reactor were found to inhibit the formation of NO.
FUEL PROCESSING TECHNOLOGY
(2021)
Article
Energy & Fuels
Giovanny S. de Oliveira, Ciro E. S. Lobo, Carlos E. A. Padilha, Domingos F. S. Souza, Juan A. C. Ruiz
Summary: Brazil aims to reduce its CO2 emissions by utilizing glycerin in Chemical Looping Combustion (CLC). The study evaluates the feasibility of using glycerin in CLC and finds that the addition of ethanol improves combustion efficiency, while the addition of methanol reduces efficiency.
Article
Thermodynamics
Fatih Gulec, Jude A. Okolie, Ahmet Erdogan
Summary: Oil refineries contribute 4-6% of global CO2 emissions, mainly due to the FCC unit's regenerator. Chemical looping combustion (CLC) is a promising CO2 capture process for FCC units, but its economic feasibility has not been studied. This research presents the first techno-economic feasibility analysis of a CLC-FCC unit, demonstrating lower energy penalties and capture costs compared to conventional CCS technologies.
Review
Energy & Fuels
Jian Chen, Lunbo Duan, Yuxin Ma, Yuxin Jiang, Anqi Huang, Hongyu Zhu, Hongyu Jiao, Mingdi Li, Yanbin Hu, Hui Zhou, Yongqing Xu, Felix Donat, Muhammad Awais Naeem, Oliver Krocher
Summary: CaL-CLC is an efficient and cost-effective CO2 capture technology that uses the heat generated by chemical looping combustion. Many studies have been carried out on the CaL-CLC process, and it is important to summarize recent progress and provide future research directions.
Article
Energy & Fuels
Oscar Condori, Alberto Abad, Maria T. Izquierdo, Luis F. de Diego, Francisco Garcia-Labiano, Juan Adanez
Summary: In this study, the Biomass Chemical Looping Gasification (BCLG) process was evaluated using wheat straw pellets and ilmenite as the fuel feedstock and oxygen carrier respectively. The effect of different operational variables on process performance and syngas yield was analyzed, and no agglomeration issues were observed during the smooth operation of the CLG unit. The oxygen transference rate in the fuel reactor was found to be the main factor affecting syngas yield and cold gas efficiency.
Review
Environmental Sciences
Siddig Abuelgasim, Wenju Wang, Atif Abdalazeez
Summary: Chemical looping combustion (CLC) is a promising CO2 capture technology that utilizes metal particles to transport oxygen and avoid nitrogen in combustion exhaust. Oxygen carrier is a key parameter in CLC, and tests have shown its feasibility worldwide.
SCIENCE OF THE TOTAL ENVIRONMENT
(2021)
Article
Energy & Fuels
Alberto Abad, Pilar Gayan, Francisco Garcia-Labiano, Luis F. de Diego, Maria T. Izquierdo, Teresa Mendiara, Juan Adanez
Summary: Chemical looping combustion (CLC) is an innovative technology that combines fuel combustion with CO2 capture using oxygen carriers. This study investigated the performance of CuO/Al2O3 and Fe2O3/Al2O3 particles as oxygen carriers in a CLC unit, and developed a mathematical model to simulate their behavior. The model successfully predicted the combustion performance of these materials in both a smaller-scale unit and a larger-scale unit.
GREENHOUSE GASES-SCIENCE AND TECHNOLOGY
(2023)
Article
Chemistry, Multidisciplinary
Kagan Benzesik, Ahmet Turan, Seref Sonmez, Maria Teresa Izquierdo, Onuralp Yucel
Summary: In this study, Li4SiO4 powders were successfully synthesized by Solution Combustion Synthesis (SCS) technique, and their CO2 sorption performance was tested. The synthesized sample showed high CO2 uptake value in thermobalance test and exhibited good CO2 adsorption capability under simulated industrial off-gas conditions. Additionally, the sample demonstrated good cyclic durability during the sorption/desorption tests.
SEPARATION SCIENCE AND TECHNOLOGY
(2023)
Article
Chemistry, Multidisciplinary
Javier Quilez-Bermejo, Sergio Garcia-Dali, Ayoub Daouli, Andrea Zitolo, Rafael L. S. Canevesi, Melanie Emo, Maria T. Izquierdo, Michael Badawi, Alain Celzard, Vanessa Fierro
Summary: In this study, single atoms and nanoclusters of Fe, Ni, Co, Cu, and Mn were embedded in a well-defined C1N1-type material with internal cavities of approximately 0.6 nm. The nucleation of different metal nanoclusters was achieved by forming metal-nitrogen bonds on four N atoms. After pyrolysis, TM@CNx-type structures were obtained, where TM represents the transition metal and x<1. Fe@CNx and Co@CNx showed promising performance in oxygen reduction reaction and hydrogen evolution reaction respectively, with a Pt-like performance, while Ni@CNx exhibited the highest activity in oxygen evolution reaction (OER) with an E-OER of 1.59 V versus RHE, surpassing the commercial IrO2 (E-OER = 1.72 V). This systematic and benchmarking study provides a basis for the future design of advanced multi-functional electrocatalysts by modulating and combining the metallic nature of nanoclusters and single atoms.
ADVANCED FUNCTIONAL MATERIALS
(2023)
Article
Energy & Fuels
Inaki Adanez-Rubio, Tobias Mattisson, Marijke Jacobs, Juan Adanez
Summary: Chemical Looping with Oxygen Uncoupling (CLOU) is a technology that separates the oxygen for fuel combustion using an oxygen carrier in a fuel reactor. This study investigates the behavior of Mn/Mg/Si system as oxygen carriers for CLOU. The most reactive oxygen carriers without Si in the structure were found to be M24Mg76 and M48Mg51. These carriers showed good reactivity and mechanical stability in a batch fluidized bed reactor.
Article
Chemistry, Applied
Amirhossein Filsouf, Inaki Adanez-Rubio, Teresa Mendiara, Alberto Abad, Juan Adanez
Summary: Chemical looping with oxygen uncoupling (CLOU) process utilizes two interconnected fluidized bed reactors, where Cu-based oxygen carriers containing a kaolin-reinforced MnFe mixed oxide as a magnetic support were prepared to improve their properties. The effects of kaolin concentration and calcination temperature on the carriers' magnetic permeability, crushing strength, attrition, agglomeration resistance, and reactivity were studied. Two oxygen carriers containing 28.5 wt% CuO-5 wt% kaolin and 30 wt% CuO-7.5 wt% kaolin, respectively, both calcined at 1100 degrees C, showed improved mechanical resistance and maintained their magnetic properties and reactivity.
FUEL PROCESSING TECHNOLOGY
(2023)
Article
Chemistry, Physical
Sergio Garcia-Dali, Javier Quilez-Bermejo, Raj Karthik, Rafael Luan Sehn Canevesi, Maria T. Izquierdo, Melanie Emo, Alain Celzard, Vanessa Fierro
Summary: The sluggish kinetics of the oxygen evolution reaction (OER) is a major limitation for green electrochemical devices. Expensive ruthenium and iridium oxide electrodes have been used as advanced electrocatalysts, but their rarity limits their global implementation. Transition metal and boron compounds show promise as alternatives due to their high catalytic properties and stability. However, their synthesis routes often involve expensive supports, increasing the cost. This study presents an easy and support-free synthesis of bimetallic borates, showing improved electrocatalytic properties for OER, particularly with nickel as the transition metal. A support-free synthesis route achieved an overpotential of 230 mV, comparable to commercial and state-of-the-art electrocatalysts.
ACS APPLIED ENERGY MATERIALS
(2023)
Article
Chemistry, Physical
Sergio Garcia-Dali, Javier Quilez-Bermejo, Jimena Castro-Gutierrez, Niki Baccile, Maria T. Izquierdo, Alain Celzard, Vanessa Fierro
Summary: This study presents efficient electrodes for the hydrogen evolution reaction (HER) based on low-cost and metal-free carbon catalysts. Phytic acid, a biosourced molecule containing carbon (C) and phosphorus (P), is used as a precursor to produce P-doped carbon materials. The conversion of P-O-type groups into P-C-type species is crucial for the catalytic activity of P-doped carbon materials, with P-C-type groups being the key factor in the electrocatalytic activity.
Article
Energy & Fuels
Arturo Cabello, Teresa Mendiara, M. Teresa Izquierdo, Francisco Garcia-Labiano, Alberto Abad
Summary: This study investigated the use of a low-cost Fe-based residue as an oxygen carrier in the Chemical Looping Combustion (CLC) and Chemical Looping Reforming (CLR) processes with biogas. The results showed that the methane combustion efficiency in the CLC process was higher (around 86%) compared to other low-cost Fe-based materials. The dry reforming of biogas in the CLR process achieved about 55% methane conversion and a yield of 1.3 mol (CO + H2)/mol CH4 for syngas production.
Article
Energy & Fuels
Margarita de las Obras Loscertales, Alberto Abad, Francisco Garcia-Labiano, Juan A. C. Ruiz, Juan Adanez
Summary: The use of bio-ethanol in chemical looping combustion and reforming has the potential to produce energy and/or hydrogen, as well as remove CO2 from the atmosphere. This study examines the kinetics of ethanol conversion using a NiO-based material as the oxygen carrier. Experiment results suggest that ethanol decomposition products, rather than direct reduction with ethanol, are responsible for NiO reduction. The high temperature kinetics of ethanol conversion processes were determined, and a reaction pathway was proposed for detailed fuel reactor models.
Article
Energy & Fuels
Oscar Condori, Alberto Abad, Maria T. Izquierdo, Luis F. de Diego, Francisco Garcia-Labiano, Juan Adanez
Summary: In this study, the Biomass Chemical Looping Gasification (BCLG) process was evaluated using wheat straw pellets and ilmenite as the fuel feedstock and oxygen carrier respectively. The effect of different operational variables on process performance and syngas yield was analyzed, and no agglomeration issues were observed during the smooth operation of the CLG unit. The oxygen transference rate in the fuel reactor was found to be the main factor affecting syngas yield and cold gas efficiency.
Article
Engineering, Chemical
Inaki Adanez-Rubio, Amirhossein Filsouf, Merve Durmaz, Teresa Mendiara, Pilar Gayan, Juan Adanez
Summary: This study focuses on testing a Cu-based oxygen carrier with enhanced mechanical properties due to the addition of kaolin in the combustion of different biomass types in a continuous CLOU unit. Complete combustion of the biomass types was achieved and higher CO2 capture efficiencies were observed at 800-950 degrees C compared to without kaolin doping. The oxygen carrier retained its magnetic properties without any agglomeration problems after 80 hours of hot circulation operation.