Article
Chemistry, Applied
Jun Young Kim, Zezhong John Li, Naoko Ellis, C. Jim Lim, John R. Grace
Summary: A jet attrition model has been developed to predict the evolution of particle size distribution in fluidized beds, showing good agreement with experimental results. The model considers fragmentation, abrasion, and material fatigue, with fitting parameters determined based on nonlinear least squares regression.
FUEL PROCESSING TECHNOLOGY
(2021)
Article
Energy & Fuels
Tobias Proell, Anders Lyngfelt
Summary: The combination of chemical-looping combustion (CLC) and steam methane reforming (SMR) is a promising method for CO(2) capture and hydrogen production. By optimizing the dimensions of the SMR tube, it is possible to improve the performance and reduce the necessary tube length. Simulation results show that using smaller tube diameters can significantly decrease the required tube length for equivalent gas conversion.
Article
Engineering, Chemical
F. Miccio, E. Landi, A. Natali Murri, M. Minelli, F. Doghieri, A. Storione
Summary: Methane reforming is an industrial process for hydrogen production, with a high CO2 footprint that can be mitigated by using renewable methane or recycling carbon dioxide. The research investigated methane reforming assisted by an oxygen carrier, which shows potential for hydrogen and carbon monoxide production. The study developed three different granular materials based on CeO2 for fluidized beds, with different calcination temperatures. The materials calcined at the highest temperature showed the best attrition resistance, while those sintered at lower temperature exhibited the best oxygen supply capacity.
CHEMICAL ENGINEERING RESEARCH & DESIGN
(2023)
Article
Chemistry, Applied
Xinfei Chen, Luwen Wang, Yan Lin, Tao Zeng, Zhen Huang, Yongqi Zhang, Ya Xiong, Jun Li, Lisheng Deng, Hongyu Huang
Summary: Ca2Fe2O5/Zr0.5Ce0.5O2 exhibited excellent reactivity in chemical looping dry reforming of methane. The migration of lattice oxygen during redox process was explored, revealing the release of lattice oxygen, structural change, and crystalline phase transformation. The understanding of oxygen migration provides a reference for improving the cyclic stability of Ca2Fe2O5/Zr0.5Ce0.5O2.
FUEL PROCESSING TECHNOLOGY
(2023)
Article
Chemistry, Applied
Jinchen Ma, Xue Zhang, Peng Peng, Xin Tian, Mengshuang Li, Ying Li, Zuwei Xu, Haibo Zhao
Summary: In this study, LaFeO3 perovskite with an ordered porous structure was synthesized via the sol-gel method and used as an oxygen carrier for chemical looping dry reforming (CLDR) of ethane. The performance and characteristics of the oxygen carrier and the CLDR process were comprehensively investigated. Results showed that LaFeO3 efficiently converted ethane into syngas (H2 and CO), and the deposited carbon on the oxygen carrier could be effectively removed by CO2. The highest C2H6 conversion, CO yield, and CO selectivity were achieved at 800 degrees C and 12,000 L/(kg center dot h).
FUEL PROCESSING TECHNOLOGY
(2023)
Article
Energy & Fuels
Ratnakumar V. Kappagantula, Gordon D. Ingram, Hari B. Vuthaluru
Summary: Chemical Looping Combustion technologies have the ability to capture carbon dioxide and are modeled using a specialized Fluidized Bed Reactor block in Aspen Plus. Sensitivity studies showed that solid volume fraction decreases with bed height and superficial velocity, while the height to diameter ratio of the fluidized bed is an important variable in reactor design.
Article
Energy & Fuels
Jingchun Yan, Tianxu Shen, Peng Wang, Xianglei Yin, Xiao Zhu, Shouxi Jiang, Laihong Shen
Summary: An innovative fluidized bed thermogravimetric analyzer was designed to study the performance of oxygen carriers in chemical looping combustion processes, revealing that high-grade manganese ore with less silicon content is more suitable for industrial CLC pilots.
Article
Green & Sustainable Science & Technology
Giuseppe Cristian Piso, Piero Bareschino, Paola Brachi, Claudio Tregambi, Giovanna Ruoppolo, Francesco Pepe, Erasmo Mancusi
Summary: In this study, the Chemical Looping Reforming of biogas was proposed and numerically investigated to achieve the clean, efficient, and cost-effective utilization of renewable carbonaceous fuels. The effects of biogas composition and process parameters on the reaction performances were assessed and discussed, including the conversion degree, syngas yield, and syngas composition.
Article
Chemistry, Multidisciplinary
Xiao Zhang, Yao Xu, Yang Liu, Liang Niu, Yanan Diao, Zirui Gao, Bingbing Chen, Jinglin Xie, Mingshu Bi, Meng Wang, Dequan Xiao, Ding Ma, Chuan Shi
Summary: In this study, researchers propose a novel MoCxOy oxygen carrier for syngas production through the chemical looping CH4-CO2 reforming reaction. The combination of molybdenum carbide and nickel particles enables high-selectivity CH4 activation at low temperatures. This is the first study to utilize molybdenum carbide as an oxygen storage material, paving the way for the use of transition metal carbides in chemical looping processes.
Article
Engineering, Environmental
Jing Yang, Yujie Ren, Jinsuo Lu, Hongpan Liu, Zhiqiang Zhang, Heliang Pang, Keomounlath Bounkhong
Summary: The study investigated a new PG-CuFe2O4 oxygen carrier for reducing lignite in Chemical Looping Gasification (CLG) process, successfully capturing H2S and producing syngas with high proportions of CO and H2. Experimental results showed that PG-CuFe2O4 had excellent H2S capture ability, with Fe3O4, Cu, and FeS playing important roles in the H2S capture during the reduction process.
CHEMICAL ENGINEERING JOURNAL
(2021)
Article
Energy & Fuels
Anders Lyngfelt, David Pallares, Carl Linderholm, Fredrik Lind, Henrik Thunman, Bo Leckner
Summary: Chemical looping combustion (CLC) has the potential to avoid the high costs and energy penalties of existing CO2 capture technologies. It transfers oxygen to the fuel using an oxygen carrier, separating air and fuel. This results in separate streams of CO2 and H2O, with relatively pure CO obtained after condensation of H2O. The circulation of oxygen and heat to the fuel reactor is crucial in CLC, which is typically a dual fluidized bed process. While many oxygen carriers have been successfully used in pilot operation, little consideration has been given to achieving sufficient circulation in an industrial-scale system.
Article
Energy & Fuels
Luwen Wang, Yan Lin, Zhen Huang, Kuo Zeng, Hongyu Huang
Summary: In this study, Zr0.5Ce0.5O2 was used to enhance the reactivity of Ca2Fe2O5 oxygen carriers and alleviate sintering issues. The addition of Zr0.5Ce0.5O2 led to improved carbon monoxide yield and cyclic performance of the modified oxygen carriers.
Article
Green & Sustainable Science & Technology
Birgitta Narindri Rara Winayu, Chun-Ta Li, Hsin Chu
Summary: Calcined ilmenite was used as an oxygen carrier in chemical looping combustion (CLC) and achieved high conversion rates. Increasing syngas concentration, operating temperature, and superficial velocity improved the reaction rate and oxygen carrier utilization, but the application of CO and CH4 caused carbon deposition and surface blocking. High redox cycles had a negative effect on the performance of the oxygen carrier.
JOURNAL OF CLEANER PRODUCTION
(2022)
Article
Energy & Fuels
Ambrose Ugwu, Mogahid Osman, Abdelghafour Zaabout, Shahriar Amini
Summary: Gas switching dry reforming (GSDR) efficiently converts CO2 and CH4 into syngas for GTL syntheses through redox cycles with alternating supply of reducing and oxidizing gases. Experimental demonstrations show achievable H-2/CO molar ratios suitable for methanol production.
Article
Chemistry, Applied
Shiwei Ma, Fang Cheng, Junguang Meng, Huijun Ge, Ping Lu, Tao Song
Summary: The feasibility of using Ni-enhanced red mud in chemical looping steam methane reforming (CL-SMR) was evaluated. It was found that the Ni-enhanced red mud displayed desirable reactivity and cyclic stability, with CO selectivity reaching 94.1% and H-2/CO ratio of 2.01 at the most suitable temperature of 900 C. The Ni species effectively activated the C-H bond of methane and facilitated the transfer of lattice oxygen.
FUEL PROCESSING TECHNOLOGY
(2022)
Article
Chemistry, Physical
Zhuoqun Yang, Xirui Yan, Zhaoyu Tang, Wencai Peng, Jianshu Zhang, Yanbin Tong, Jun Li, Jinli Zhang
Summary: This study presents an efficient and environmentally friendly method for preparing carbon materials with high catalytic activity by intercalating hemin into layered double hydroxides. The material exhibits a two-dimensional porous network structure and a large specific surface area, providing numerous active sites for the ORR reaction. Characterization showed that the material has better ORR catalysis than Pt/C, with higher half-wave potential, limiting current density, and lower Tafel slope.
APPLIED SURFACE SCIENCE
(2022)
Article
Engineering, Environmental
Jie Wang, Xiao Du, Xiaoqiong Hao, Jinhua Luo, Xiaogang Hao, Qing Cao, Guoqing Guan, Jun Li, Zhong Liu, Yongguo Li, Abuliti Abudula
Summary: Utilizing the synergy between light and electric fields, the novel photo-assisted electrochemically switched ion exchange (P-ESIX) strategy has shown improved capture and recovery efficiency for bromide ions, achieving higher selectivity and stability. This innovative technology provides a new direction for achieving higher capture efficiency for target ions in the separation field.
CHEMICAL ENGINEERING JOURNAL
(2022)
Article
Engineering, Chemical
Mengfang Jiang, Xuefeng Zhang, Xiao Du, Xiaowei An, Fengfeng Gao, Xiaogang Hao, Guoqing Guan, Zhong Liu, Jun Li, Abuliti Abudula
Summary: An electrode with dual adsorption sites for bromide ion was obtained through electrodeposition and solvothermal methods. The electrode exhibited excellent bromide ion selectivity and high extraction capacity.
SEPARATION AND PURIFICATION TECHNOLOGY
(2022)
Article
Chemistry, Physical
Katharina Wussow, Andrea Abram, Klaus Koehler, Chun-Ran Chang, Alexander Genest, Jun Li, Notker Roesch
Summary: The relevant parameters for leaching palladium atoms from small Pd clusters during Heck reactions have been studied computationally and experimentally. The results show that bromide ions and other factors make the leaching process notably exergonic.
CATALYSIS COMMUNICATIONS
(2022)
Article
Engineering, Chemical
Xu Zhang, Zhan Du, Qingshan Zhu, Jun Li, Zhaohui Xie
Summary: The promotion effect of pre-oxidation on the reduction of ilmenite was revealed through the formation of a porous structure, resulting in enhanced reduction process.
Article
Engineering, Environmental
Xu Zhang, Jun Li, Zheng Zou, Huigang Zhang, Dong Yan, Zhan Du, Zhaohui Xie, Qingshan Zhu
Summary: We propose a novel force balance model to predict the defluidization phenomena of ilmenite particles in a fluidized bed reactor. The model is based on the cohesion forces of iron nuclei on the particle surface, which increase with the extent of reduction and eventually trigger defluidization. The predicted surface coverage of particles agrees well with experimental results.
CHEMICAL ENGINEERING JOURNAL
(2023)
Article
Engineering, Environmental
Bing Zhao, Zhiqiang Qian, Yinjun Qiao, Jun Li, Zhijian Wu, Zhong Liu
Summary: In this study, two different morphologies of Li4Ti5O12 materials were synthesized and their adsorption behaviors were studied through experiments and calculations. The results showed that the material with the (01-1) facet exhibited higher adsorption capacity and faster adsorption rate. The analysis of the adsorption mechanism revealed the importance of dehydration processes and ion exchange reactions in the adsorption behavior.
CHEMICAL ENGINEERING JOURNAL
(2023)
Article
Engineering, Chemical
X. Liu, X. Zhang, J. Li, Q. Zhu, N. G. Deen, Y. Tang
Summary: Direct reduction of combusted iron powders using renewable energy is crucial for a carbon-neutral iron fuel cycle. Lab-scale reduction experiments show that a temperature of 500 degrees C achieves a reduction degree higher than 90%, while higher temperatures result in particle sintering and lower reduction degree due to quick defluidization. The study highlights the significance of temperature on sintering and reduction behavior, with negligible impact from gas velocity. The findings offer insights for the design of hydrogen-based iron fuel regeneration processes.
Article
Engineering, Chemical
X. Liu, X. Zhang, J. Li, Q. Zhu, N. G. Deen, Y. Tang
Summary: Hydrogen-based direct reduction of iron oxide powder in gas-fluidized beds is a developing technology, but the agglomeration of fine powder at high temperatures is a key issue. This study experimentally investigates the (de-)fluidization behavior of micron-sized combusted iron particles to understand the high-temperature agglomeration mechanism. The effects of various operating and material variables on the fluidization and agglomeration behavior are examined, and a theoretical model is developed to predict the boundaries of fluidization regimes. The obtained knowledge is then applied for experimental design of the hydrogen-based iron direct reduction process.
Article
Engineering, Environmental
Hebang Shi, He Zhang, Rui Wang, Ming Liu, Zihan Shen, Jingbo Chen, Binbin Wu, Maoqiao Xiang, Jun Li, Huigang Zhang, Pengpeng Lv, Qingshan Zhu
Summary: The performance of SiO anodes depends on the characteristics of the solid-electrolyte interface (SEI), which are difficult to control due to complex generation mechanisms. The electrode interface property is a neglected but crucial factor influencing SEI formation. This study investigates the influence of electrode interface on SEI by using TiN as a coating to isolate HF from SiO. Different interface properties were achieved by modifying the dominant exposed crystalline planes of the TiN coatings. The mechanical properties of SEI under different interface properties were discussed and analyzed, revealing the preference for a rigid-flexible SEI on SiO/TiN-{1 0 0} electrode. The effect of electrode interfacial property on SEI was further revealed through the calculation and analysis of LiF adsorption on different TiN crystal planes using the first-principle method. Electrochemical tests showed that the SiO/TiN-{1 0 0} electrode had significantly better performance compared to others. Differential capacity analyses provided insights into the electrochemical-mechanical coupled correlation between SEI and cycling performance.
CHEMICAL ENGINEERING JOURNAL
(2023)
Article
Engineering, Chemical
Xue Xue, Xu Zhang, Da Li, Jun Li, Qingshan Zhu, Hongzhong Li
Summary: The reduction behaviors of ultrafine CuO powders in a fluidized bed were investigated. Enhanced fluidization quality of the powders was achieved by adding SiO2 microspheres for adhesion. The reaction resulted in the production of ultrafine Cu powders which detached from the microspheres due to changes in cohesive and breaking forces. This finding enriches the theories of fluidization process strengthening and can be applied to other ultrafine/nano metal powders production.
CHEMICAL ENGINEERING SCIENCE
(2023)
Article
Instruments & Instrumentation
Xiuxia Li, Yulan Li, Weiyou Tang, Yidong Fu, Shasha Lv, Jianping Chang, Li He, Yang Tian
Summary: In this study, a method combining chemical treatment (methanol passivation) with thin film deposition (SiOx films passivation) has been applied to the HPGe detector intercontact surface. As a result, the leakage current of the bare detector stabilized at the level of 1 pA (applied voltage up to 3600 V, depletion voltage of 1800 V) while it had been immersed in LN2 for more than six months. It shows that the surface passivation technology raised by this work can reliably protect the HPGe detector from environmental impact, which is very helpful to obtaining a stable HPGe detector with ultra-low leakage current.
NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT
(2023)
Article
Engineering, Chemical
Ming Liu, Guoqiang Shao, Pengpeng Lv, Jun Li, Qingshan Zhu
Summary: The fluidization quality has a significant impact on mass transfer and deposition reactions, which are crucial for achieving uniform deposition of TiO2 thin films on fluorophlogopite particles. It was found that an effective addition ratio of nano-TiO2 particles above 0.2 wt% is needed to achieve fluidization of the fluorophlogopite particles. The addition of nano-TiO2 particles leads to competition between free TiO2 particles and fluorophlogopite particles, resulting in a decreased coating rate of TiO2 on fluorophlogopite particles.
Article
Chemistry, Multidisciplinary
Qing Zheng, Huhu Wang, Wencai Peng, Jianshu Zhang, Jinli Zhang, Yanbin Tong, Jun Li
Summary: This paper investigates the mechanism of deoxygenation of lignite model compounds in the aqueous phase under a CO atmosphere catalyzed by OH- ions. The results reveal that H- is the dominating active species and deoxygenation proceeds via substitution to form benzene.
NEW JOURNAL OF CHEMISTRY
(2022)
Article
Engineering, Environmental
Xinping Zhang, Yuxin Guo, Xiaoyang Liu, Shun-Yu Wu, Ya-Xuan Zhu, Shao-Zhe Wang, Qiu-Yi Duan, Ke-Fei Xu, Zi-Heng Li, Xiao-Yu Zhu, Guang-Yu Pan, Fu-Gen Wu
Summary: This study develops a nanotrigger HCFT for simultaneous photodynamic therapy and light-triggered ferroptosis therapy. The nanotrigger can relieve tumor hypoxia, induce enhanced photodynamic reaction, and facilitate the continuation of Fenton reaction, ultimately leading to lethal ferroptosis in tumor cells.
CHEMICAL ENGINEERING JOURNAL
(2024)
Article
Engineering, Environmental
Olumide Bolarinwa Ayodele, Toyin Daniel Shittu, Olayinka S. Togunwa, Dan Yu, Zhen-Yu Tian
Summary: This study focused on the semihydrogenation of acetylene in an ethylene-rich stream using two alloyed Pt catalysts PtCu and PtCo. The PtCu catalyst showed higher activity and ethylene yield compared to PtCo due to its higher unoccupied Pt d-orbital density. This indicates that alloying Pt with Cu is more promising for industrial relevant SHA catalyst.
CHEMICAL ENGINEERING JOURNAL
(2024)
Article
Engineering, Environmental
Guowei Chen, Wen-Cheng Chen, Yaozu Su, Ruicheng Wang, Jia-Ming Jin, Hui Liang, Bingxue Tan, Dehua Hu, Shaomin Ji, Hao-Li Zhang, Yanping Huo, Yuguang Ma
Summary: This study proposes an intramolecular dual-locking design for organic luminescent materials, achieving high luminescence efficiency and performance for deep-blue organic light-emitting diodes. The material also exhibits unique mechanochromic luminescence behavior and strong fatigue resistance.
CHEMICAL ENGINEERING JOURNAL
(2024)
Article
Engineering, Environmental
Joren van Stee, Gregory Hermans, Jinu Joseph John, Koen Binnemans, Tom Van Gerven
Summary: This work presents a continuous solvent extraction method for the separation of cobalt and nickel in a millifluidic system using Cyphos IL 101 (C101) as the extractant. The optimal conditions for extraction performance and solvent properties were determined by investigating the effects of channel length, flow rate, and temperature. The performance of a developed manifold structure was compared to a single-channel system, and excellent separation results were achieved. The continuous separation process using the manifold structure resulted in high purity cobalt and nickel products.
CHEMICAL ENGINEERING JOURNAL
(2024)
Article
Engineering, Environmental
Yan Xu, Jingai Jiang, Xinyi Lv, Hui Li, Dongliang Yang, Wenjun Wang, Yanling Hu, Longcai Liu, Xiaochen Dong, Yu Cai
Summary: A programmed gas release nanoparticle was developed to address the challenges in treating diabetic infected wounds. It effectively removes drug-resistant pathogens and remodels the wound microenvironment using NO and H2S. The nanoparticle can eliminate bacteria and promote wound healing through antibacterial and anti-inflammatory effects.
CHEMICAL ENGINEERING JOURNAL
(2024)
Article
Engineering, Environmental
Tong Xia, Zhilin Xi, Lianquan Suo, Chen Wang
Summary: This study investigated a highly efficient coal dust suppressant with low initial viscosity and high adhesion-solidification properties. The results demonstrated that the dust suppressant formed a network of multiple hydrogen bonding cross-linking and achieved effective adhesion and solidification of coal dust through various chemical reactions.
CHEMICAL ENGINEERING JOURNAL
(2024)
Article
Engineering, Environmental
Jinzhi Cai, Zhenshan Li
Summary: A density functional theory-based rate equation was developed to predict the gas-solid reaction kinetics of CaO carbonation with CO2 in calcium looping. The negative activation energy of CaO carbonation close to equilibrium was accurately predicted through experimental validation.
CHEMICAL ENGINEERING JOURNAL
(2024)
Article
Engineering, Environmental
Jianxiong Chen, Fuhao Ren, Ningning Yin, Jie Mao
Summary: This study presents an economically efficient and easily implementable surface modification approach to enhance the high-temperature electrical insulation and energy storage performance of polymer dielectrics. The self-assembly of high-insulation-performance boron nitride nanosheets (BNNS) on the film surface through electrostatic interactions effectively impedes charge injection from electrodes while promoting charge dissipation and heat transfer.
CHEMICAL ENGINEERING JOURNAL
(2024)
Article
Engineering, Environmental
Zijian Li, Zhaohui Yang, Shao Wang, Hongxia Luo, Zhimin Xue, Zhenghui Liu, Tiancheng Mu
Summary: This study reports a strategy for upgrading polyester plastics into value-added chemicals using electrocatalytic methods. By inducing the targeted transfer of *OH species, polyethylene terephthalate was successfully upgraded into potassium diformate with high purity. This work not only develops an excellent electrocatalyst, but also provides guidance for the design of medium entropy metal oxides.
CHEMICAL ENGINEERING JOURNAL
(2024)
Article
Engineering, Environmental
Navneet Singh Shekhawat, Surendra Kumar Patra, Ashok Kumar Patra, Bamaprasad Bag
Summary: This study primarily focuses on developing a sulphur dyeing process at room temperature using bacterial Lysate, which is environmentally friendly, energy and cost effective, and sustainable. The process shows promising improvements in dye uptake and fastness properties.
CHEMICAL ENGINEERING JOURNAL
(2024)
Article
Engineering, Environmental
Dengjia Shen, Hongyang Ma, Madani Khan, Benjamin S. Hsiao
Summary: This study developed cationic PVC nanofibrous membranes with high filtration and adsorption capability for the removal of bacteria and hexavalent chromium ions from wastewater. The membranes demonstrated remarkable performance in terms of filtration efficiency and maximum adsorption capacity. Additionally, modified nanofibrous membranes were produced using recycled materials and showed excellent retention rates in dynamic adsorption processes.
CHEMICAL ENGINEERING JOURNAL
(2024)
Article
Engineering, Environmental
Xiaoyan Wang, Zhikun Wang, Ben Jia, Chunling Li, Shuangqing Sun, Songqing Hu
Summary: Inspired by photosystem II, self-supported Fe-doped NiCoP nanowire arrays modified with carboxylate were constructed to boost industrial-level overall water splitting by employing the concerted proton-coupled electron transfer mechanism. The introduction of Fe and carboxyl ligand led to improved catalytic activity for HER and OER, and NCFCP@NF exhibited long-term durability for overall water splitting.
CHEMICAL ENGINEERING JOURNAL
(2024)
Article
Engineering, Environmental
Pengyao Yu, Ge Yang, Yongming Chai, Lubomira Tosheva, Chunzheng Wang, Heqing Jiang, Chenguang Liu, Hailing Guo
Summary: Thin LTA zeolite membranes were prepared through secondary growth of nano LTA seeds in a highly reactive gel, resulting in membranes with superior permeability and selectivity in gas separation applications.
CHEMICAL ENGINEERING JOURNAL
(2024)
Article
Engineering, Environmental
Baiqin Zhou, Huiping Li, Ziyu Wang, Hui Huang, Yujun Wang, Ruichun Yang, Ranran Huo, Xiaoyan Xu, Ting Zhou, Xiaochen Dong
Summary: The use of machine learning to predict the performance of specific adsorbents in phosphate adsorption shows great promise in saving time and revealing underlying mechanisms. However, the small size of the dataset and insufficient detailed information limits the model training process and the accuracy of results. To address this, the study employs a fuzzing strategy that replaces detailed numeric information with descriptive text messages on the physiochemical properties of adsorbents. This strategy allows the recovery of discarded samples with limited information, leading to accurate prediction of adsorption amount, capacity, and kinetics. The study also finds that phosphate uptake by adsorbents is generally through physisorption, with some involvement of chemisorption. The framework established in this study provides a practical approach for quickly predicting phosphate adsorption performance in urgent scenarios, using easily accessible information.
CHEMICAL ENGINEERING JOURNAL
(2024)
Article
Engineering, Environmental
Paula Alejandra Lamprea Pineda, Joren Bruneel, Kristof Demeestere, Lisa Deraedt, Tex Goetschalckx, Herman Van Langenhove, Christophe Walgraeve
Summary: This study evaluates the use of four esterified fatty acids and three vegetable oils as absorption liquids for hydrophobic VOCs. The experimental results show that isopropyl myristate is the most efficient liquid for absorbing the target VOCs.
CHEMICAL ENGINEERING JOURNAL
(2024)
