![Membrane Separation Process Design and Intensification | Industrial & Engineering Chemistry Research Membrane Separation Process Design and Intensification | Industrial & Engineering Chemistry Research](https://pubs.acs.org/cms/10.1021/acs.iecr.0c05072/asset/images/medium/ie0c05072_0011.gif)
Membrane Separation Process Design and Intensification | Industrial & Engineering Chemistry Research
Hydrogen Recovery from Coke Oven Gas. Comparative Analysis of Technical Alternatives | Industrial & Engineering Chemistry Research
Highly CO2-Selective Gas Separation Membranes Based on Segmented Copolymers of Poly(Ethylene oxide) Reinforced with Pentiptycene-Containing Polyimide Hard Segments | ACS Applied Materials & Interfaces
![Hybrid Separation Process of Refinery Off-gas toward Near-Zero Hydrogen Emission: Conceptual Design and Techno-economic Analysis | Industrial & Engineering Chemistry Research Hybrid Separation Process of Refinery Off-gas toward Near-Zero Hydrogen Emission: Conceptual Design and Techno-economic Analysis | Industrial & Engineering Chemistry Research](https://pubs.acs.org/cms/10.1021/acs.iecr.0c00143/asset/images/medium/ie0c00143_0012.gif)
Hybrid Separation Process of Refinery Off-gas toward Near-Zero Hydrogen Emission: Conceptual Design and Techno-economic Analysis | Industrial & Engineering Chemistry Research
![Hybrid Separation Process of Refinery Off-gas toward Near-Zero Hydrogen Emission: Conceptual Design and Techno-economic Analysis | Industrial & Engineering Chemistry Research Hybrid Separation Process of Refinery Off-gas toward Near-Zero Hydrogen Emission: Conceptual Design and Techno-economic Analysis | Industrial & Engineering Chemistry Research](https://pubs.acs.org/cms/10.1021/acs.iecr.0c00143/asset/images/large/ie0c00143_0005.jpeg)
Hybrid Separation Process of Refinery Off-gas toward Near-Zero Hydrogen Emission: Conceptual Design and Techno-economic Analysis | Industrial & Engineering Chemistry Research
![Processes | Free Full-Text | Optimal Design of a Two-Stage Membrane System for Hydrogen Separation in Refining Processes Processes | Free Full-Text | Optimal Design of a Two-Stage Membrane System for Hydrogen Separation in Refining Processes](https://www.mdpi.com/processes/processes-06-00208/article_deploy/html/images/processes-06-00208-g001.png)
Processes | Free Full-Text | Optimal Design of a Two-Stage Membrane System for Hydrogen Separation in Refining Processes
![Experimental analysis of membrane and pressure swing adsorption (PSA) for the hydrogen separation from natural gas - ScienceDirect Experimental analysis of membrane and pressure swing adsorption (PSA) for the hydrogen separation from natural gas - ScienceDirect](https://ars.els-cdn.com/content/image/1-s2.0-S0959652617317274-fx1.jpg)
Experimental analysis of membrane and pressure swing adsorption (PSA) for the hydrogen separation from natural gas - ScienceDirect
![Frontiers | Membrane Processes for Direct Carbon Dioxide Capture From Air: Possibilities and Limitations Frontiers | Membrane Processes for Direct Carbon Dioxide Capture From Air: Possibilities and Limitations](https://www.frontiersin.org/files/MyHome%20Article%20Library/668867/668867_Thumb_400.jpg)
Frontiers | Membrane Processes for Direct Carbon Dioxide Capture From Air: Possibilities and Limitations
![Membranes | Free Full-Text | Hydrogen Separation and Purification from Various Gas Mixtures by Means of Electrochemical Membrane Technology in the Temperature Range 100–160 °C Membranes | Free Full-Text | Hydrogen Separation and Purification from Various Gas Mixtures by Means of Electrochemical Membrane Technology in the Temperature Range 100–160 °C](https://pub.mdpi-res.com/membranes/membranes-11-00282/article_deploy/html/images/membranes-11-00282-g002.png?1628114556)
Membranes | Free Full-Text | Hydrogen Separation and Purification from Various Gas Mixtures by Means of Electrochemical Membrane Technology in the Temperature Range 100–160 °C
![Designing energy-efficient separation membranes: Knowledge from nature for a sustainable future - ScienceDirect Designing energy-efficient separation membranes: Knowledge from nature for a sustainable future - ScienceDirect](https://ars.els-cdn.com/content/image/1-s2.0-S2772823422000070-ga1.jpg)
Designing energy-efficient separation membranes: Knowledge from nature for a sustainable future - ScienceDirect
![Membranes | Free Full-Text | Hydrogen Separation and Purification from Various Gas Mixtures by Means of Electrochemical Membrane Technology in the Temperature Range 100–160 °C Membranes | Free Full-Text | Hydrogen Separation and Purification from Various Gas Mixtures by Means of Electrochemical Membrane Technology in the Temperature Range 100–160 °C](https://pub.mdpi-res.com/membranes/membranes-11-00282/article_deploy/html/images/membranes-11-00282-g015.png?1628114556)
Membranes | Free Full-Text | Hydrogen Separation and Purification from Various Gas Mixtures by Means of Electrochemical Membrane Technology in the Temperature Range 100–160 °C
Methane Pyrolysis for Zero-Emission Hydrogen Production: A Potential Bridge Technology from Fossil Fuels to a Renewable and Sustainable Hydrogen Economy | Industrial & Engineering Chemistry Research
![Current and future trends in polymer membrane-based gas separation technology: A comprehensive review - ScienceDirect Current and future trends in polymer membrane-based gas separation technology: A comprehensive review - ScienceDirect](https://ars.els-cdn.com/content/image/1-s2.0-S1226086X21001532-fx1.jpg)
Current and future trends in polymer membrane-based gas separation technology: A comprehensive review - ScienceDirect
![Membranes | Free Full-Text | Hydrogen Separation and Purification from Various Gas Mixtures by Means of Electrochemical Membrane Technology in the Temperature Range 100–160 °C Membranes | Free Full-Text | Hydrogen Separation and Purification from Various Gas Mixtures by Means of Electrochemical Membrane Technology in the Temperature Range 100–160 °C](https://pub.mdpi-res.com/membranes/membranes-11-00282/article_deploy/html/images/membranes-11-00282-g011.png?1628114557)
Membranes | Free Full-Text | Hydrogen Separation and Purification from Various Gas Mixtures by Means of Electrochemical Membrane Technology in the Temperature Range 100–160 °C
![Analysis of hydrogen production costs in Steam-Methane Reforming considering integration with electrolysis and CO2 capture - ScienceDirect Analysis of hydrogen production costs in Steam-Methane Reforming considering integration with electrolysis and CO2 capture - ScienceDirect](https://ars.els-cdn.com/content/image/1-s2.0-S2666790822001574-ga1.jpg)