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Chemical Engineering Journal
基本信息
期刊名称 Chemical Engineering Journal
CHEM ENG J
期刊ISSN 0300-9467
期刊官方网站 https://www.sciencedirect.com/journal/chemical-engineering-journal
是否OA No
出版商 Elsevier B.V.
出版周期 Semimonthly
文章处理费 登录后查看
始发年份 1996
年文章数 7288
影响因子 13.3(2023)  scijournal影响因子  greensci影响因子
中科院SCI期刊分区
大类学科 小类学科 Top 综述
工程技术1区 ENGINEERING, CHEMICAL 工程:化工1区
ENGINEERING, ENVIRONMENTAL 工程:环境1区
CiteScore
CiteScore排名 CiteScore SJR SNIP
学科 排名 百分位 8.47 0.125 1.941
Engineering
Industrial and Manufacturing Engineering
5 / 323 98%
Environmental Science
Environmental Chemistry
5 / 100 95%
Chemical Engineering
General Chemical Engineering
8 / 272 97%
Chemistry
General Chemistry
22 / 371 94%
补充信息
自引率 9%
H-index 172
SCI收录状况 Science Citation Index Expanded
官方审稿时间 登录后查看
网友分享审稿时间 数据统计中,敬请期待。
接受率 登录后查看
PubMed Central (PMC) http://www.ncbi.nlm.nih.gov/nlmcatalog?term=1385-8947%5BISSN%5D
投稿指南
期刊投稿网址 https://www.editorialmanager.com/CEJ/default.aspx
收稿范围
An International Journal of Research and Development

The Chemical Engineering Journal focuses upon five aspects of chemical engineering: catalysis, chemical reaction engineering, environmental chemical engineering, green and sustainable science and engineering, and novel materials.

The Chemical Engineering Journal is an international research journal and invites contributions of original and novel fundamental research. The journal aims to provide an international forum for the presentation of original fundamental research, interpretative reviews and discussion of new developments in chemical engineering. Papers which describe novel theory and its application to practice are welcome, as are those which illustrate the transfer of techniques from other disciplines. Reports of carefully executed experimental work, which is soundly interpreted are also welcome. The overall focus is on original and rigorous research results that have generic significance.

Within the Chemical Engineering Journal, the Catalysis section presents Experimental and Theoretical studies in the fields of heterogeneous catalysis, molecular catalysis, and biocatalysis with industrial impact on chemicals, energy, materials, foods, healthcare, and environmental protection

Within the Chemical Engineering Journal, the Environmental Chemical Engineering section presents papers dealing with emerging topics in environmental chemical and process engineering, including pollution control, separation processes, advanced oxidation processes, adsorption of contaminants, resources recovery, waste-to-energy, environmental nanotechnology and bioprocesses, CO2 capture and utilization, and micro(nano) plastic detection and remediation.

Within the Chemical Engineering Journal, the Chemical Reaction Engineering section presents papers on a wide range of topics including reaction kinetics, simulation and optimization of different types of reactors, unsteady-state reactors, multiphase reactors, and process intensification including fundamental investigations of the processes of heat, mass and momentum transfer that take place along with chemical reactions. Innovative research works addressing critical areas of reactor engineering (e.g. novel reactor designs and materials, reactor safety and environmental issues), and emerging reactor technologies (e.g. membrane reactors, chromatographic reactors, unconventional fluidized bed reactors, electrochemical reactors, micro-reactors, photoreactors, fuel cells, enzymatic reactors, etc.) are particularly welcome. Submissions based entirely on e.g., numerical simulations with commercial CFD codes without novel experimental validation; novel sensing devices without a component of reaction engineering; theoretical mathematics; combustion in the context of energy conversion; or straightforward bioreactor applications (bacteria or animal cells) are highly discouraged, as these will find better fit in other existent journals.

Within the Chemical Engineering Journal, the Green and Sustainable Science and Engineering section presents papers focusing on innovative scientific and engineering solutions for sustainable future of human beings and nature. Topics in this section include, but are not limited to, the following: 1) Emerging materials and processes for green conversion of resources (including oil, gas, coal, biomass, plastics, and synthesis gas); 2) Green processes and system integration for renewable and clean energy production (including biofuels and H2), advanced treatment of air/water/solids, resource recovery (including nutrients, heavy metals, rare earth elements, and energy), energy-food-water nexus, and minimization of environmental pollution and hazardous materials (including environmental and economic impact assessment); and 3) Innovative separation, purification, and storage technologies for renewable and clean energy, greenhouse gases (e.g., CO2 and CH4), and intermediates/by-products.

The Novel Materials for Energy and Advanced Applications section of Chemical Engineering Journal considers papers describing the development of new functional materials and/or materials processing strategies with demonstrated practical applications. Theoretical calculations can be included, but all papers considered must have an experimental component. Any paper with a demonstrated application will be considered, including:

• Materials for sensors (gas sensors, strain sensors, electrochemical sensors, biosensors, optical sensors, or biomedical sensors provided the emphasis is new materials development)
• Biomedical materials (nanomedicine, photothermal/photodynamic therapy, tissue engineering, drug delivery, wound healing, gene therapy)
• Materials for agriculture (agrochemical delivery vehicles, materials for pest management)
• Functional polymer composites (shape memory or self-healing materials with demonstrated applications, flame-retardant materials, adhesives, sustainable materials, thermal management materials, electromagnetic shielding materials)
• Functional surfaces (superhydrophobic/self-cleaning surfaces, antimicrobial surfaces, anti-icing surfaces, anti-corrosion coatings)
• Materials for photo(electro)catalytic fuel production (water splitting, nitrogen fixation, CO2 reduction)
• Materials for solar cells (dye-sensitized solar cells, perovskite solar cells, organic solar cells)
• Materials for electrochemical energy storage (primary and secondary batteries, flow batteries, supercapacitors, dielectric capacitors)
• Materials for thermal/thermochemical energy storage/conversion (phase change materials, energy storage materials, thermoelectric devices)
• Energetic materials (explosives, propellants)
• Materials for electrocatalytic reactions (water splitting, hydrogen/oxygen evolution)
• Light-emitting and light-filtering materials (LEDs/OLEDs, photodetectors, optical thermometry, electrochromic materials)


The GSSE section does NOT focus on traditional fabrication and modification (processes) of polymers, including membranes and porous materials, metal alloys, and construction materials. Papers pertaining to chemistry with lack of "innovative" engineering aspects, combustion and engines should be submitted to more specialized journals. Otherwise, they will be internally transferred to other journals more suited to their topic.
收录体裁
Original papers
Review articles
Perspectives
Short communications
Letters to Editors
投稿指南 https://www.sciencedirect.com/journal/chemical-engineering-journal/publish/guide-for-authors
投稿模板
参考文献格式
编辑信息
Co-Editors

Stephen Allen

Queen's University Belfast, Belfast, United Kingdom  Liquid and gas phase adsorption processes. Nutrient removal. Removal of metals and persistent organics. Ion exchange. CO2 removal and Carbon capture. Constructed wetlands.
University of Cincinnati, Cincinnati, Ohio, United States Advanced oxidation technologies for water treatment, drinking water treatment and purification, water quality, treatment, reuse, and monitoring, sustainable water processes, physicochemical phenomena on particle-water interfaces, transition-metal oxidation and reverse electron transfer reactions, the use of ionic liquids in environmental applications, destruction of biological toxins in water, environmental nanotechnology (fundamental, fate, transport, and applications of nanomaterials), Remediation, Environmental catalysis. Moderate Experience: Some experience also on separations (membranes, adsorption, solvent extraction). Less experience: biological treatment processes, resource recovery, biofuels/bioenergy, microbial fuel cells.
Ghent University, Gent, Belgium  chemical kinetics; heterogeneous catalysis; (petro)chemical processes, polymerization, reactor design and modelling, reactor scale-up, crude oil refining, natural gas valorisation, renewables
Hong Kong University of Science and Technology, Clear Water Bay, Kowloon, Hong Kong heterogeneous catalysis (including environmental catalysis, photocatalysis and enzyme), novel and hybrid reactor system, miniature flow reactor and microreactor, green and fine chemistry.
Soniya Education Trust's College of Pharmacy, Dharwad, India Membranes and membrane processes (including toxic metal adsorption) for the treatment and/or separation of industrial effluents; Mitigation and biochars for sustainability, toxic metal separations and waste minimization; Biofuels, algal and municipal sludge dewatering (anaerobic and aerobic) processes, membrane bioreactors and microbial fuel cells, polymer membrane fuel cells; Coagulation, VOCs treatment processes, desulfurization, deep eutectic solvent, SO2/NO removal, phosphorus and nitrogen removal, degradation of toxic chemicals by electrochemical methods and sensors; Industrial catalytic processes and activated carbon composites
University of Patras Department of Chemical Engineering, Patras, Greece  Heterogeneous catalysis and photocatalysis. Developmnt and evaluation of catalytic materials and processes for environmental and energy-related applications
McMaster University, Hamilton, Ontario, Canada  Biomaterials, Drug delivery systems, Tissue engineering scaffolds, Encapsulation methods, Hydrogels, Functional polymers and polymer composites, Superhydrophobic/superoleophilic interfaces, oil recovery materials, fire retardant materials, phase change and thermal management materials, antibacterial/antifungal materials and interfaces, anti-corrosion materials, biosensors
Reviews & Perspectives Editor

Jesús Santamaria

University of Zaragoza, Zaragoza, Spain  Nanomaterials synthesis and characterization, nanomedicine, catalysis, advanced reactors (microwave-driven reactors, microreactors, laser pyrolysis reactors)
Associate Editors
Autonomous University of Madrid, Madrid, Spain  Water purification by photocatalysis, Design of novel heterostructures for environmental remediation, Water treatment by adsorption, Advanced oxidation technologies for water treatment, Environmental nanotechnology (fundamental and applications of nanomaterials).

Soryong (Ryan) Chae

University of Cincinnati, Cincinnati, Ohio, United States Biological processes for water and wastewater, resource recovery, membrane technology for water and energy, environmental nanotechnology
University of Florida, Gainesville, Florida, United States  Biochar technology, Environmental nanotechnology, Contaminant fate and transport, Adsorption, Engineered carbon materials, Nutrient removal and reuse, Heavy metal removal, Removal of emerging contaminants, Controlled release fertilizers
Institute of Chemical Engineering Sciences, Patra, Greece catalytic reaction engineering, Functional nanomaterials, ((electro)chemical) energy storage
Sejong University Department of Energy and Environment, Seoul, Korea, Republic of Waste-to-Energy (WtE), Combustion Chemistry, Thermo-Chemical Process (Pyrolysis and Gasification), Catalysis, Biofuels, Biorefinery, CO2 Utilization, Carbon Capture & Storage (CCS), Waste and Biomass Valorization, Green Chemistry, Environmental Sustainability, Air Pollution Controls
 heterogenous photocatalysis in water and air, AOPs, self-cleaning and antifogging surfaces, wet chemistry synthesis of materials, materials characterization
Korea Advanced Institute of Science and Technology, Daejeon, Korea, Republic of 
Aristotle University of Thessaloniki, Thessaloniki, Greece Heterogeneous catalysis, chemical kinetics, reactor design, (petro)chemical processes, carbon capture and utilization processes, process intensification (chemical looping), natural gas valorization, biomass chemo and thermocatalytic conversion.
Nanjing University, Nanjing, China  Nano-enabled water treatment; Environmental functional materials; Nanomaterials for environmental remediation; Industrial wastewater treatment; Municipal wastewater treatment; Drinking water treatment; Adsorption; Advanced oxidation processes (AOPs); Water quality analysis; POPs and PPCPs removal
Institute of Technology Sligo, Nanotechnology and Bio-Engineering Research Group, Sligo, Ireland  Nanomaterials, Advanced Oxidation Process, Energy materials, Photocatalysis, Supercapacitors, Hydrogen, Materials for Energy and Environmental science, Electrocatalysis, Electrochemistry, Photo-fenton process, Aerogels, Microwave chemistry, Sonochemical processing, Batteries and electrode materials.  
University of Bath, Bath, United Kingdom  micro-reactor technology, fluid mechanics, CFDs, gas-liquid mixing, multiphase reactors, process intensification, biological reactors, biofuels
Education University of Hong Kong, New Territories, Hong Kong Biological wastewater treatment, bioremediation, resource recovery from organic waste, microbial CO2 fixation, odour pollution control
Worcester Polytechnic Institute, Worcester, Massachusetts, United States  Carbon Capture, Negative Emissions, Combustion, Adsorption, Membrane Separations
University of Waterloo, Waterloo, Ontario, Canada  Nanomaterials development for polymer composites ( thermal management, corrosion) and energy storage/conversion (supercapacitors, batteries, photocatalysts)
Editorial Board

Bengt Andersson

Chalmers University of Technology, Goteborg, Sweden 

Vemuri Balakotaiah

City University of New York, New York, New York, United States  New sorbents and catalysts, Surface characterization, Adsorption/desorption phenomena, Gas separation, Deep desulfurization of fuels, Catalytic photooxidation, Graphite oxide based composite, Gas sensors, Energy storage
Autonomous University of Madrid, Madrid, Spain 
Polytechnic of Turin, Torino, Italy 
University of Cambridge Department of Chemical Engineering and Biotechnology, Cambridge, United Kingdom  Fluid Mechanics, Environment, Buoyancy, Plumes & Jets, Porous Media

Raf Dewil

KU Leuven Science and Technology Group Department of Chemical Engineering, Heverlee, Belgium 
Ethniko Kentro Ereunas Physikon Epistemon 'Demokritos', Athens, Greece 
University of Wyoming School of Energy Resources, Laramie, Wyoming, United States Integrating multiple methods and processes including (homogenous, heterogeneous and photo as well as bio) catalysis and separation with sorption and membrane for conversion of coal, oil and gases to value-added chemicals and clean fuelsDeveloping new materials (e.g., ionic liquids and nanostructure as well as magnetic materials) for clean and renewable energy production with conventional and unconventional technologies such as supercritical fluids and advanced crystallization as well as chemical vapor depositionUnderstanding the reaction mechanisms associated with chemical and energy generation processes through various theoretical and experimental tools including computation chemistryControlling air pollution (e.g., CO2 and Hg as well as H2S captures), and managing water qualities (e.g., heavy metal and chemical oxygen demand removals)Life cycle assessments of chemical and energy generation processes
King Abdullah University of Science and Technology, Thuwal, Saudi Arabia 
American University of Beirut, Beirut, Lebanon 
Virginia Polytechnic Institute and State University, Blacksburg, Virginia, United States Water pollution and treatment; Environmental biotechnology; Resource recovery from wastes; Bioelectrochemical systems; Bioenergy; Membrane technology; Bioremediation; Desalination
University of Technology Eindhoven Department of Chemical Engineering and Chemistry, Eindhoven, Netherlands  Multiphase Reactors, Multiphase Flow, Computational Fluid Dynamics, Multi-Scale Modelling
Loughborough University Department of Chemical Engineering, Loughborough, United Kingdom 
Harbin Institute of Technology, School of Environment, Harbin, China  Membrane, Drinking water treatment; Water reuse; Advanced oxidation; Desalination
Harbin Institute of Technology School of Municipal and Environmental Engineering, Haerbin, China 
University of Patras Department of Chemical Engineering, Patras, Greece 

Eva Martin Del Valle

University of Salamanca, Salamanca, Spain 
National Risk Management Research Laboratory, Cincinnati, Ohio, United States  Nanotechnology, Green Chemistry, Water Research, Polymer Chemistry, Materials Chemistry
Korea University Division of Environmental Science and Ecological Engineering, Seoul, Korea, Republic of  Biochar, Resilience, Soil remediation, Biomass, Bioenergy
Stony Brook University, Stony Brook, New York, United States 
Dalian University of Technology School of Environmental Science and Technology, Dalian, China  Advanced oxidation technologies(AOTs), Functional materials for environmental application, Electrocatalysis, Photocatalysis, Membrane separation
Princeton University, Princeton, New Jersey, United States Water resource recovery, Wastewater treatment, Microbial electrochemistry, Functional membranes
University of Porto, Porto, Portugal  Cyclic adsorption/reaction processes, Perfume Engineering, Lignin valorization, CO2 capture and utilization, Modeling and simulation
Potosi Institute of Scientific and Technological Research, San Luis Potosi, Mexico  Photo-inactivation, Agricultural photocatalysis, H2 production, Hydrothermal method, Microwave synthesis
The University of Melbourne Department of Chemical Engineering, Parkville, Victoria, Australia  Separation Processes, Solvent Extraction, Ion Exchange
Otto von Guericke University, Magdeburg, Germany Reaction Engineering, Forced Dynamic Operation, Chromatography, Crystallization
Central Leather Research Institute CSIR, Chennai, India  Environmental remediation/degradation of toxic chemicals, Membrane bioreactors for the treatment or separation of toxic/industrial effluents, Chemical process safety, Bioprocess monitoring and control through metabolic heats. 
University of Kansas, Lawrence, Kansas, United States  Process intensification, Liquid-Liquid systems, Ion Exchange, Biocatalysis, Phase transfer catalysis
Central South University, Changsha, China  Advanced oxidation processes, Radical chemistry, Computational chemistry, Environmental modelling
East China University of Science and Technology, Shanghai, China 


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