Article
Chemistry, Physical
Hua Pang, Haoran Xu, Anwei Sun, Gang Xiao
Summary: In this study, MgO-Na2CO3-KNO3 sorbents with fast sorption kinetics, high capture capacity, and good cyclic stability at elevated conditions were reported. The results showed that KNO3 is the nitrate species with the highest MgO conversion, and Na2CO3 plays a key role in the initial fast sorption rate. The sorbent with 60 mol% Na2CO3 doping amount achieved the highest MgO conversion.
APPLIED SURFACE SCIENCE
(2022)
Article
Engineering, Environmental
Gina Bang, Kyung-Min Kim, Seongmin Jin, Chang-Ha Lee
Summary: The presence of other gas species in practical conditions complicates sorption-based processes. This study focuses on understanding the dynamic CO2 sorption behavior of MgO-based sorbent under practical conditions. It was found that elevated pressures significantly enhance sorption performance, while temperature has no significant influence. H2O enhances CO2 sorption kinetics and initial CO2 sorption, while CO hinders them.
CHEMICAL ENGINEERING JOURNAL
(2022)
Article
Chemistry, Physical
Hua Pang, Feng Mao, Shishun Zhang, Peng Sun, Anwei Sun, Gang Xiao
Summary: This study investigates the use of eutectic carbonates as promoters for MgO-based sorbents operating at elevated temperature and pressure. The results show that MgO doped with eutectic ternary LiNaK carbonate exhibits the highest MgO conversion and CO2 capture capacity. The incorporation of alkali metal ions lowers the energy barrier for oxygen ion migration. This research provides guidance for the design of high-performance CO2 sorbents at wider application conditions.
APPLIED SURFACE SCIENCE
(2023)
Article
Chemistry, Multidisciplinary
Theodoros Papalas, Andy N. Antzaras, Angeliki A. Lemonidou
Summary: This study investigated the CO2 capture performance of MgO derived from mineral magnesite doped with limestone and molten Li, Na, and K nitrates, showing that increasing the molten promoter loading can enhance CO2 sorption rate, while higher CaCO3 content impedes CO2 diffusion. Despite morphological transformations during cyclic operation, redistribution of alkali salts contributes to the stability and promising performance of the sorbent.
JOURNAL OF CO2 UTILIZATION
(2021)
Article
Engineering, Chemical
Guangfan Tan, Liang Cai, Haifeng Xue, Xin Hu, Xiaoxu Dong, Hangyu Jiang, Xiuhong Yang, Yasuhisa Oya, Yingchun Zhang
Summary: This paper presents a simple method combining the wet method and freeze-drying method to fabricate Li4SiO4 sorbent with rich porosity and direction arrangement channels, which overcomes the limitations of previous literature. The freeze-drying Li4SiO4 cylinder (FSC) green sorbents have columnar ice crystals in the interior, and the unidirectional alignment of pore channels can be obtained after vacuum drying, improving CO2 capture capacity. The FSC sorbent shows superior CO2 sorption capacities and outstanding stability, making it a promising candidate for CO2 removal.
SEPARATION AND PURIFICATION TECHNOLOGY
(2023)
Article
Chemistry, Physical
Liji Zhang, Yuhang Zheng, Yafei Guo, Shengbin Bai, Meishan Song, Pu Huang, Xinzheng Wei, Jian Sun, Changhai Li, Jiaqing Zhang, Chuanwen Zhao
Summary: The study investigated the effects of operating parameters on TCES performance and the long-term cycling stability of alkali metal nitrate promoted MgO composites. It was found that the heat storage density is significantly influenced by the nitrate content, and the 10(Li-Na)NO3-MgO composite exhibited good stability.
ACS APPLIED ENERGY MATERIALS
(2021)
Article
Engineering, Environmental
Ehsan Hassani, Jinwon Cho, Farshad Feyzbar-Khalkhali-Nejad, Ali Rashti, Seung Soon Jang, Tae-Sik Oh
Summary: Three different calcium-based ternary oxide sorbents were characterized and compared with CaO for CO2 capture. Ca2CuO3 showed faster regeneration and a narrower operational temperature range, indicating its potential as a better CO2 sorbent.
JOURNAL OF ENVIRONMENTAL CHEMICAL ENGINEERING
(2022)
Article
Thermodynamics
Supriya Nair, Rajeev Raghavan
Summary: Lithium zirconates synthesized through precipitation method followed by calcination exhibit high CO2 sorption capacity at elevated temperatures and good regenerability. The CO2 sorption capacity increases with the calcination temperature.
THERMOCHIMICA ACTA
(2021)
Article
Chemistry, Physical
Zhiyuan Li, Weiquan Cai, Chengxiong Dang
Summary: This study reports a general template-based approach using carbon microspheres and alkali modification to synthesize highly effective bi-functional catalyst, which exhibits excellent stability and high performance.
INTERNATIONAL JOURNAL OF HYDROGEN ENERGY
(2022)
Article
Chemistry, Multidisciplinary
Vyacheslav V. Rodaev, Svetlana S. Razlivalova, Alexander I. Tyurin, Vladimir M. Vasyukov
Summary: A Zr-doped CaO sorbent with an average filament diameter of about 160 nm was fabricated using electrospinning. The sorbent showed an initial CO2 uptake capacity of 12.1 mmol/g, a specific surface area of 79 m(2)/g, an indentation Young's modulus of 520 MPa, and a hardness of 1.6 MPa. After 50 carbonation/decarbonation cycles, the sorbent still exhibited a decent CO2 uptake capacity of 9.7 mmol/g due to the uniform distribution of CaZrO3 in the CaO nanofibers.
Article
Engineering, Environmental
Seongbin Jo, Han Dong Son, Tae-Young Kim, Jin Hyeok Woo, Do Yeong Ryu, Jae Chang Kim, Soo Chool Lee, Kandis Leslie Gilliard-AbdulAziz
Summary: In this study, a Ru/K2CO3-MgO (Ru/KMg) catal-sorbent was developed for integrated CO2 capture and methanation (ICCM) at low temperatures. The Ru primarily existed as a K2RuO3 phase, and the crystallite size of Ru0 was smaller than Ru/MgO due to better dispersion throughout the MgO support material. The optimal carbonation temperature for achieving 100% CO2 conversion to CH4 was found to be 150 degrees C. The ICCM experiments conducted at 150 degrees C for carbonation (10 vol% CO2 and 10 vol% H2O) and 320 degrees C for methanation (90 vol% H2) showed stable CH4 productivities with 100% selectivity and 96.2%-101.3% yield.
CHEMICAL ENGINEERING JOURNAL
(2023)
Article
Engineering, Environmental
Wanlin Gao, Michalis A. Vasiliades, Constantinos M. Damaskinos, Meng Zhao, Wenqi Fan, Qiang Wang, Tomas Ramirez Reina, Angelos M. Efstathiou
Summary: By adding molten salt modifiers, the CO2 uptake of MgO-based CO2 adsorbents can be increased, with three different processes identified for the interaction of molten salt-promoted MgO with CO2 at 300 degrees C. Transient kinetic studies coupled with mass spectrometry provided a thorough understanding of the CO2-capturing performance and its significant implications for future practical designs of precombustion CO2 capture.
ENVIRONMENTAL SCIENCE & TECHNOLOGY
(2021)
Article
Engineering, Chemical
Zhihong Xu, Tao Jiang, Hao Zhang, Yujun Zhao, Xinbin Ma, Shengping Wang
Summary: Novel MgO-doped CaO sorbent pellets exhibit excellent CO2 adsorption capacity and adsorption rate due to the homogeneous dispersion of MgO and its effects on the physical structure of sorbents, effectively inhibiting sintering of CaO and retaining adsorption capacity during multiple cycles. Mesopores and macropores contribute to significant volume changes during operation cycles. Ca2Mg1 sorbent pellets show favorable CO2 capture capacity, average adsorption rate, and conversion rate of CaO after 30 cycles.
FRONTIERS OF CHEMICAL SCIENCE AND ENGINEERING
(2021)
Article
Energy & Fuels
Yuzhuo Wang, Yingjie Li, Liguo Yang, Xiaoxu Fan, Leizhe Chu
Summary: Co-gasification of cellulose and polyethylene using bi-functional materials was studied for hydrogen production. The results show that polyethylene improves the effectiveness of cellulose sorption-enhanced steam gasification for hydrogen production. Ni-CaO-Ca12Al14O33 exhibits higher cyclic stability and catalytic activity compared to Ni-CaO-MgO. Ca12Al14O33 is a better framework for Ni-CaO-based bifunctional material in the sorption-enhanced steam gasification process.
Article
Engineering, Environmental
Haiming Gu, Guohui Song, Miaomiao Niu, Shanhui Zhao, Yunfei Gao, Fanxing Li
Summary: In this study, high temperature sorbent SrO was prepared with sol-gel method and the effect of different support materials on the reactivity stability was evaluated. It was found that CeO2 supported sorbent exhibited super stable CO2 capture performance, enabling carbonation/calcination at a lower temperature and improving microstructure and sintering resistance.
CHEMICAL ENGINEERING JOURNAL
(2022)
Article
Thermodynamics
Zhen Wu, Pengfei Zhu, Jing Yao, Sandra Kurko, Jianwei Ren, Peng Tan, Haoran Xu, Zaoxiao Zhang, Meng Ni
Summary: The novel methanol utilization technology proposed in this work, based on a hybrid fuel cell system, shows higher energy conversion efficiency and good economic viability. Through thermodynamic analysis, it is shown to have a lower specific electric energy cost compared to traditional methanol steam reforming-PEMFC power plants in the case of Northwest China.
ENERGY CONVERSION AND MANAGEMENT
(2021)
Article
Thermodynamics
Haoran Xu, Jingbo Ma, Peng Tan, Zhen Wu, Yanxiang Zhang, Meng Ni, Jin Xuan
Summary: A hybrid simulation method is proposed for the accurate and fast optimization of the co-electrolysis process in SOECs, with a focus on thermal-neutral condition as the target. The smallest peak-temperature-gradients inside the SOEC are found to be crucial for preventing thermal failure in operation at the thermal-neutral condition.
ENERGY CONVERSION AND MANAGEMENT
(2021)
Review
Green & Sustainable Science & Technology
Zheng Li, Hao Zhang, Haoran Xu, Jin Xuan
Summary: Solid oxide electrolysis cell (SOEC) is a promising technology for hydrogen production, carbon dioxide utilization and nitrogen reduction, but faces challenges such as performance descending. Multiscale modelling is expected to maintain more information and generate a systematic understanding of the working mechanism.
RENEWABLE & SUSTAINABLE ENERGY REVIEWS
(2021)
Article
Energy & Fuels
Lingchao Xia, Meng Ni, Qidong Xu, Haoran Xu, Keqing Zheng
Summary: This study investigates the impact of catalyst layer (CL) thickness on the performance and cost of high temperature proton exchange membrane fuel cells (HT-PEMFC) by developing a non-isothermal 3D model. The results show that the effective reaction thickness (ERT) of both anode and cathode increases with temperature.
Article
Chemistry, Multidisciplinary
Duo Xiang, Changdong Gu, Haoran Xu, Gang Xiao
Summary: Research successfully synthesized bixbyite-type (Mn0.8Fe0.2)(2)O-3 and extruded it into honeycomb units, which maintained 85% of initial capacity after 100 redox cycles. A self-assembled core-shell MnFe2O4@Mn2.7Fe0.3O4 structure was found during the reduction step, transforming into a homogeneous solid solution of (Mn0.8Fe0.2)(2)O-3 during oxidation step. Through density functional theory calculations, it was revealed that the lower formation energy of oxygen vacancies in the shell contributes to the improvement of oxygen diffusion rate.
Article
Energy & Fuels
Wentao Yu, Wenxu Shang, Xu Xiao, Yanyi Ma, Ziqi Chen, Bin Chen, Haoran Xu, Meng Ni, Peng Tan
Summary: This study systematically investigates the mechanism of discharge performance improvement in zinc-air flow batteries by flowing electrolyte, revealing that it enhances discharge polarization performance and transport of hydroxide and zincate ions. The specific discharge capacity is improved due to the alleviation of zinc oxide passivation. The revealed mechanism can guide the design of flow field and battery structure for practical applications.
JOURNAL OF ENERGY STORAGE
(2021)
Article
Multidisciplinary Sciences
Peng Yuan, Changdong Gu, Haoran Xu, Zeyu Ning, Kefa Cen, Gang Xiao
Summary: A strategy of oxygen defect engineering is proposed to regulate the thermochemical redox temperatures of perovskites, resulting in an active coating with a tunable temperature range. The designed coating can effectively relieve the thermal shock of the receiver by slowing down the temperature rising rate under strong solar radiation.
Article
Nanoscience & Nanotechnology
Duo Xiang, Changdong Gu, Haoran Xu, Jiali Deng, Peiwang Zhu, Gang Xiao
Summary: Aluminum-doped copper oxides demonstrate high reversibility and stability in high-temperature energy storage, with the introduction of Al improving the oxidation rate of copper vacancies and providing a guideline for optimizing high-performance materials in thermochemical energy storage.
ACS APPLIED MATERIALS & INTERFACES
(2021)
Article
Thermodynamics
Xin Zhou, Haoran Xu, Duo Xiang, Jinli Chen, Gang Xiao
Summary: This study designed a high-efficiency thermal energy storage system for a solar thermal air-Brayton cycle system and validated its performance through experiments; found that gas leakage affects system temperature; and simulated a stand-alone operation strategy for the system based on a one-dimensional transient model.
Article
Green & Sustainable Science & Technology
Xiangyu Xie, Haoran Xu, Di Gan, Mingjiang Ni, Jianhua Yan, Kefa Cen, Gang Xiao
Summary: A novel impeded flow particle receiver, named sliding-bed receiver, was introduced in this study, utilizing friction and gate valves as obstacles. Experimental results showed that the outlet particle temperature and efficiency reached 847 degrees C and 77.2% under a 4kW solar simulator. Through an optical and thermal coupling model, higher particle temperature and efficiency can be achieved under higher incident power.
Article
Chemistry, Multidisciplinary
Kaixiang Xing, Yuxuan Ji, Zheng Wang, Mingxuan Wang, Yafei Liu, Haoran Xu, Gang Xiao
Summary: A non-contact measurement method using an infrared spectrometer was proposed to monitor the transient state of carbon dioxide (CO2) in a supercritical CO2 Brayton cycle. Experimental investigations showed that the density change of CO2 fluid can impact the absorption spectrum near 3400 nm, serving as a signal of CO2 state changes. The method can quickly detect abnormal conditions in dynamic processes and has the potential for application in the sCO2 Brayton cycle or other areas.
JOURNAL OF CO2 UTILIZATION
(2022)
Article
Thermodynamics
Yi Sun, Jiong Lu, Qiuhua Liu, Wei Shuai, Anwei Sun, Nan Zheng, Yu Han, Gang Xiao, Jin Xuan, Meng Ni, Haoran Xu
Summary: Solid oxide electrolysis cell (SOEC) is a novel approach to utilize excess renewable power to produce fuels and chemicals. This study proposes a hybrid model based on multi-physics simulation and deep learning algorithm for the optimization of the co-electrolysis process in the SOEC.
ENERGY CONVERSION AND MANAGEMENT
(2022)
Article
Green & Sustainable Science & Technology
Yi Sun, Wenjin Zheng, Shiyu Ji, Anwei Sun, Wei Shuai, Nan Zheng, Yu Han, Gang Xiao, Meng Ni, Haoran Xu
Summary: A multi-physics SOEC model was established to investigate the dynamic characteristics of SOECs using a real photovoltaic power supply for co-electrolysis of H2O and CO2. The study found that a high CO2 mole fraction can help inhibit average temperature fluctuation, and the output H-2/CO ratio is closely related to the gas utilization rate and inlet gas temperature.
SUSTAINABLE ENERGY TECHNOLOGIES AND ASSESSMENTS
(2022)
Article
Chemistry, Physical
Hua Pang, Haoran Xu, Anwei Sun, Gang Xiao
Summary: In this study, MgO-Na2CO3-KNO3 sorbents with fast sorption kinetics, high capture capacity, and good cyclic stability at elevated conditions were reported. The results showed that KNO3 is the nitrate species with the highest MgO conversion, and Na2CO3 plays a key role in the initial fast sorption rate. The sorbent with 60 mol% Na2CO3 doping amount achieved the highest MgO conversion.
APPLIED SURFACE SCIENCE
(2022)
Article
Thermodynamics
Zheng Wang, Gang Xiao, Yafei Liu, Yuxuan Ji, Haoran Xu
Summary: Researchers have studied convective heat transfer of fluids with varying properties in tubes and found that existing heat transfer correlations are often limited due to inaccurately defined reference temperatures and incorrect understanding of dimensionless parameters. This study numerically investigates the cooling heat transfer of sCO2 in horizontal tubes near the pseudo-critical point and proposes new definitions for reference temperature and dimensionless numbers in order to improve the accuracy. The results show promising agreement with experimental data and the derived correlation can be extrapolated to different tube sizes and constant property cases.
INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER
(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)