Review
Chemistry, Applied
Pranav Kulkarni, Hyunyoung Jung, Debasis Ghosh, Mohammed Jalalah, Mabkhoot Alsaiari, Farid A. Harraz, R. Geetha Balakrishna
Summary: Lithium/Sodium-ion batteries have attracted attention due to their high energy density and long cycle life. One major challenge is the initial irreversible capacity loss, which can be overcome by pre-lithiation/sodiation. Pre-lithiation/sodiation additives are preferred due to their easy adaptability and compatibility with the current battery manufacturing process. This review consolidates recent developments in using pre-lithiation/sodiation additives to improve the energy density and cycle life of lithium/sodium-ion batteries.
JOURNAL OF ENERGY CHEMISTRY
(2023)
Review
Chemistry, Physical
Wesley M. Dose, Christopher S. Johnson
Summary: Electrochemical energy storage plays a crucial role in the global pursuit of clean and sustainable energy. Higher energy densities and a more diverse battery landscape are needed to meet future energy requirements. Pre-lithiation/sodiation technology can mitigate active ion loss and enhance the energy density of next-generation LIBs and sodium-ion batteries.
CURRENT OPINION IN ELECTROCHEMISTRY
(2022)
Article
Electrochemistry
Mika Fukunishi, Shunya Ishii, Yusuke Himata, Atsushi Kondo, Fumisato Ozawa, Morihiro Saito
Summary: In this study, four ethers were compared as solvents for lithium naphthalenide (Li-NTL) solutions for pre-doping lithium into silicon electrodes. The results showed that the solvents have an impact on the stability and equilibrium potential of Li-NTL solutions, which in turn affects the doping capacity.
JOURNAL OF THE ELECTROCHEMICAL SOCIETY
(2022)
Article
Electrochemistry
Liming Jin, Junsheng Zheng, Jim P. Zheng
Summary: Research on the mathematical formulas describing the effect of pre-lithiation on LIBs' energy density helps illustrate the impact of important parameters on energy density and predict possible energy density improvements in practical LIB systems with pre-lithiation.
JOURNAL OF THE ELECTROCHEMICAL SOCIETY
(2021)
Article
Chemistry, Multidisciplinary
Yan Liu, Xiangkun Li, Fengling Zhang, Leqing Zhang, Tao Zhang, Changshuan Li, Zhicheng Jin, Yueying Wu, Zhongyu Du, Huiwen Jiao, Ying Jiang, Yuliang Yan, Qiang Li, Weijin Kong
Summary: Alkali ion batteries are widely used in various fields as a new generation of energy storage devices. The focus of research has been on developing universal anodes for these batteries. In this study, a hollow structure CoS/C derived from ZIF was designed as an excellent anode for alkali ion batteries. The anode exhibited a reversible capacity after 100 cycles and can be applied to Li, Na, and K ion batteries.
FRONTIERS IN CHEMISTRY
(2022)
Article
Engineering, Environmental
Xieji Lin, Yue Dong, Xuewei Liu, Xiaohong Chen, Ang Li, Huaihe Song
Summary: In-situ chemical pre-lithiation strategy was used to fabricate onion-like SiOC/C spheres with high initial coulombic efficiency. The uniform generation of LixSiOy inside the spheres effectively reduces the irreversible consumption of Li ions and simplifies the pre-lithiation process. The structures of SiOC/C spheres also provide superior structural integrity, showing potential for high energy density and cycling stability in LIB applications.
CHEMICAL ENGINEERING JOURNAL
(2022)
Review
Chemistry, Physical
V Palomares, N. Nieto, T. Rojo
Summary: The fabrication of new high-energy batteries is essential for the advancement of electric transportation and grid storage, with current research focusing on negative electrodes and materials such as C, Si, and P. While Si and hard carbons are closer to industrial deployment, phosphorus-based materials require more thorough study before practical application.
CURRENT OPINION IN ELECTROCHEMISTRY
(2022)
Review
Materials Science, Multidisciplinary
Muhammad Mominur Rahman, Feng Lin
Summary: Oxide electrodes in alkali-ion batteries involve redox reactions of both transition metal cations and oxygen ions, enabling increased capacity and energy density. However, challenges such as oxygen evolution, voltage hysteresis, and structural transformations still exist and require further investigation. Understanding and mitigating these challenges will be crucial for the development of next-generation batteries utilizing oxygen redox.
Review
Electrochemistry
Yao Liu, Wei Li, Yongyao Xia
Summary: While carbon, oxide, and silicon-based materials have limitations in current LIB applications, polyanionic compounds have gained attention for their ability to stabilize structures, adjust redox couples, and provide migration channels for guest ions, leading to electrode materials with long-term cycling, high energy density, and outstanding rate capability.
ELECTROCHEMICAL ENERGY REVIEWS
(2021)
Review
Green & Sustainable Science & Technology
Q. Li, M. Yuan, Y. Wang, M. Yao, Z. Zhong, F. Su
Summary: Alkali ion batteries have gained significant attention due to their high power and energy density. However, there is a need for novel electrode materials with higher capacity and longer cycle life. Carbon-supported single-atom metal (CSAM) materials show promise in increasing the anode capacity and extending its lifespan, but more research is required. This mini-review summarizes the application and work mechanisms of CSAM materials in alkali ion batteries, discusses their disadvantages, and proposes solution strategies.
MATERIALS TODAY SUSTAINABILITY
(2023)
Article
Chemistry, Physical
Zhicong Luo, Yongkang Jin, Zhi Chen, Xin Wang, Tianyi Ding, Zhijun Feng, Xibao Li, Kun Guo, Sinong Wang, Juntong Huang
Summary: In this study, Cr/S co-doped carbon nanofibers (Cr/S@CNFs) were successfully synthesized via electrospinning technique combined with high temperature treatment. As the anode material for lithium ion batteries (LIBs), the Cr/S@CNFs electrode exhibited excellent cycle stability and high rate performance, and it also showed good ion storage capacity for sodium ion batteries (SIBs). Such outstanding electrochemical performances were attributed to the co-doping of Cr and S elements, presenting a reliable and efficient approach for the synthesis of high-performance anode materials.
JOURNAL OF ALLOYS AND COMPOUNDS
(2023)
Article
Materials Science, Multidisciplinary
Jie Liu, Yanan Gao, Chenjie Lou, Yongjin Chen, Xiang Gao, Ligang Xu, Qi Wei, Guangcan Bai, Guoquan Liu, Mingxue Tang
Summary: Hybrid architectures integrating Fe7S8@NC@MoS2 with a three-dimensional heterostructure are designed in this study. The adjustable voids of the material can buffer the volume change during intercalation of metal ions. Additionally, the presence of MoS2 enhances electronic conductivity and metal ion transfer, resulting in improved battery performance.
ACS MATERIALS LETTERS
(2022)
Article
Green & Sustainable Science & Technology
Fathima Ali Kayakool, Binitha Gangaja, Shantikumar Nair, Dhamodaran Santhanagopalan
Summary: The recycling and regeneration of graphite from spent Li-ion batteries can be utilized for the fabrication of Li-ion based all-carbon dual-ion batteries, achieving promising electrochemical performance.
SUSTAINABLE MATERIALS AND TECHNOLOGIES
(2021)
Article
Chemistry, Physical
Ngoc Hung Vu, Hang T. T. Le, Van Hien Hoang, Van-Duong Dao, Ha Tran Huu, Young-Si Jun, Won Bin Im
Summary: A series of N-doped mesoporous carbon materials were synthesized using a modified nanocasting method, showing high discharge capacities and excellent cycling performance in both Li-ion and Na-ion batteries. By manipulating the physicochemical properties, the materials were tailored for specific applications, demonstrating superior characteristics compared to most state-of-the-art porous carbon materials.
JOURNAL OF ALLOYS AND COMPOUNDS
(2021)
Article
Chemistry, Physical
Jia Liu, Wei Sun, Yuzhu Ran, Shuyu Zhou, Linfeng Zhang, Aimin Wu, Hao Huang, Man Yao
Summary: The study verifies the lithiation process of Sn4P3 as an anode material for Li-ion batteries through experimental and computational analysis, showing its excellent cycling stability and progressive lithiation mechanism.
APPLIED SURFACE SCIENCE
(2021)
Article
Energy & Fuels
Ki-Hun Nam, Vinoth Ganesan, Do-Hyeon Kim, Jeong-Hee Choi, Cheol-Min Park
Summary: This study analyzes the Na reaction pathway of bismuth and creates rational designs for Bi-based nanocomposite materials to improve their Na storage performance. The metal-organic framework-derived polyhedral Bi nanocomposite exhibits superior Na storage performance with high reversible capacity and rate capability.
INTERNATIONAL JOURNAL OF ENERGY RESEARCH
(2022)
Article
Chemistry, Multidisciplinary
Ki-Hun Nam, Sangmin Jeong, Byeong-Chul Yu, Jeong-Hee Choi, Ki-Joon Jeon, Cheol-Min Park
Summary: The study suggests that Li-compound anodes are a promising category of high-performance LIB anodes, capable of simultaneously meeting the requirements for high reversibility and safety.
Article
Engineering, Multidisciplinary
In-Su Hwang, Young-Han Lee, Jeong-Myeong Yoon, Yoon Hwa, Cheol-Min Park
Summary: Sodium-ion batteries and potassium-ion batteries are potential candidates for achieving zero-carbon emission as next-generation secondary battery systems. A versatile GaSb nanocomposite anode is introduced, which shows highly reversible initial capacities and superior high-rate capabilities. The nanostructure of the GaSb nanocomposite promotes the electrochemical reaction kinetics and enhances the stability of the electrodes.
COMPOSITES PART B-ENGINEERING
(2022)
Article
Chemistry, Physical
Yunjung Kim, Kyungbae Kim, Hyungeun Seo, Sung-Min Lee, Cheol-Min Park, Jae-Hun Kim
Summary: The study introduces a porous Sn2Nb2O7-graphene oxide composite material as an anode material for both lithium-ion and sodium-ion batteries, showing high reversible capacity and cycling stability. The enhanced electrode performance is attributed to the combination of porous structure and graphene oxide.
JOURNAL OF ALLOYS AND COMPOUNDS
(2022)
Article
Chemistry, Organic
Jeongwoo Sim, Bokyeong Ryou, Minyeong Choi, Changju Lee, Cheol-Min Park
Summary: We describe the electrochemical alpha-amidoalkylation of gamma-lactams based on transition-metal-free cross-coupling via hydrogen atom transfer. The highly selective hydrogen atom transfer process allows for a broad substrate scope and the construction of quaternary centers. Detailed mechanistic studies including experimental and computational studies are provided to support the reaction pathway.
Article
Chemistry, Physical
In-Su Hwang, Young-Han Lee, Vinoth Ganesan, Yoon Hwa, Cheol-Min Park
Summary: This study introduces a new type of GaSb compound anode and optimized nanocomposite fabrication route for improving the performance of lithium-ion batteries. The reaction mechanism of GaSb with Li ions is analyzed using advanced analysis tools, and the electrochemical performance of different nanocomposites is compared. The results show that the GaSb/a-C nanocomposite exhibits superior performance, surpassing conventional graphite anodes.
ACS APPLIED ENERGY MATERIALS
(2022)
Article
Chemistry, Applied
Eunsoo Yu, Hyungguk Kim, Cheol-Min Park
Summary: The synthesis of heterocycles from 1,2-diarylalkene derivatives through electrosynthesis under metal- and oxidant-free conditions has been discovered. Reactive radical intermediates formed through cathodic reduction or anodic oxidation of specific compounds lead to the formation of various heterocyclic products with good functional group tolerance and high yields. Solvent-dependent chemoselectivity was observed, and mechanistic investigations helped elucidate the reaction mechanisms.
ADVANCED SYNTHESIS & CATALYSIS
(2022)
Article
Engineering, Environmental
Dong-Hun Lee, Do-Hyeon Kim, Heechul Jung, Cheol-Min Park
Summary: Germanium is a highly researched anode material for Li-ion batteries due to its high Li storage capacity and electrical conductivity. The Li reaction pathways in germanium have been demonstrated through the analysis of nanocrystalline germanium. The electrochemical performance of a germanium-based nanocomposite, Ge/Al2O3/C, has been enhanced for better Li storage characteristics.
CHEMICAL ENGINEERING JOURNAL
(2023)
Article
Ecology
Sang-Hee Lee, Cheol-Min Park, Sang-Bin Lee
Summary: This article discusses the search and transport efficiency of tunneling patterns in termites from an evolutionary perspective. Using an individual-based model, the study explores the impact of four variables on food transport efficiency and discusses potential optimization strategies and improvements for the model.
ECOLOGICAL MODELLING
(2022)
Article
Chemistry, Organic
Venkatesh Murugesh, Bokyeong Ryou, Cheol-Min Park
Summary: This paper describes the synthesis of unsymmetrical dithioacetals based on gold catalysis. While many methods have been developed for the preparation of symmetrical dithioacetals, methods for accessing unsymmetrical ones are still limited. The authors report a mild synthetic method with a broad substrate scope. Screening of various gold catalysts identified a catalyst that allows for efficient hydrothiolation of both activated and unactivated vinyl sulfides, and the reaction is compatible with both aryl and aliphatic thiols.
ORGANIC & BIOMOLECULAR CHEMISTRY
(2023)
Article
Chemistry, Physical
Ki-Hun Nam, Do-Hyeon Kim, Young-Han Lee, Su Choel Han, Jeong-Hee Choi, Yoon-Cheol Ha, Cheol-Min Park
Summary: Layered materials, especially silicon disulfide (SiS2), have received significant attention due to their diverse properties and potential applications. This study demonstrates a simple large-scale synthesis method for layered SiS2 and evaluates its performance as an anode material for Li-ion batteries. The SiS2 nanocomposite exhibits high Li-storage capacity, excellent cycling stability, and good rate capability. Furthermore, when incorporated into a Li-argyrodite solid-state electrolyte, SiS2 shows commendable air/moisture stability and high ionic conductivity. These findings suggest that layered SiS2 has great potential for various applications.
JOURNAL OF MATERIALS CHEMISTRY A
(2023)
Article
Chemistry, Physical
Hien Duy Mai, Sangmin Jeong, Gi-Nam Bae, Ngoc Minh Tran, Jong-Sang Youn, Cheol-Min Park, Ki-Joon Jeon
Summary: Sulfidation of Pd species on monolayer MoS2 enhances the 1T-phase degree, leading to maximized metal utilization efficiency and exposure of active surface atoms. The resulting PdxSy/1T-MoS2 catalyst exhibits unprecedented high mass activity (-3444 A mg(Pd)(-1)) and turnover frequency (1892 s(-1)), three orders of magnitude higher than commercial Pt/C 10 wt%. The sulfidation-assisted 1T-phase enrichment has significant implications for the design of efficient electrocatalysts through MoS2 phase engineering.
ADVANCED ENERGY MATERIALS
(2023)
Article
Chemistry, Multidisciplinary
Vinoth Ganesan, Young-Han Lee, Heechul Jung, Cheol-Min Park
Summary: In this study, a nanostructured porous polyhedral carbon (PPC) was synthesized as a carbon matrix for high-capacity Li/Na/K-alloy-based anode materials. The PPC matrix exhibited large initial reversible capacity, fast rate capability, better cyclic performance, high ionic diffusivity, and excellent structural robustness in Li/Na/K-ion batteries, indicating its potential usage in high-capacity alloy-based anode materials.
Article
Energy & Fuels
Young-Han Lee, In-Su Hwang, Jeong-Hee Choi, Cheol-Min Park
Summary: The electrochemical Li/Na/K-ion reaction pathways in Ga for high-performance Ga anodes in alkali-ion batteries are thoroughly elucidated using ex situ analytical tools. Ga exhibits a high Li-ion storage reaction, forming Li2Ga, but poor Na- and K-ion storage reactions, forming NaGa4 and K3Ga13, respectively. An amorphous Ga composite (Ga/C) is fabricated, showing high reversible capacity, long-term Li-ion storage stability, and high rate capability. Three-step confinement of amorphous Ga in the composite during cycling is demonstrated as an enhancement mechanism for high-performance Ga/C anodes for LIBs.
JOURNAL OF ENERGY STORAGE
(2023)
Article
Chemistry, Physical
Jeong-Myeong Yoon, Young-Han Lee, Cheol-Min Park
Summary: This study investigates the use of two structural types of Ga as anodes for Li-ion batteries (LIBs) and develops an optimized Ga-based nanocomposite using a solid-state alloying-dealloying process. The nanocomposite effectively addresses the melting and agglomeration issues of Ga, improving the cycling stability and electrochemical performance of LIBs.
MATERIALS TODAY ENERGY
(2023)
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)