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Update Data 
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lhyeh@mail.ntust.edu.tw |
| Last update: 28/10/2025 | |
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| Name: |
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Institution: |
National Taiwan University of Science and Technology |
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Type of Institution: |
University |
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ORCID number: |
https://orcid.org/0000-0003-2982-5340
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Google Scholar: |
https://scholar.google.com/citations?user=Hb-jD2QAAAAJ&hl=en
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Country: |
Taiwan
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WEB address: |
https://nanofluidicsyehlab.com/ |
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Working groups of interest |
| - | WG1 - Advances in Porous Materials and Technologies | | - | WG3 - Energy |
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| Keywords |
| - | | Energy | | - | | Mesopores | | - | | Nanopores | | - | | Smart Functional Surfaces |
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Research field (Free keywords) |
Nanofluidics; Ion transport membrane; Single-pore device; Osmotic energy; Electrokinetic energy; Iontronics; MOF/COF/2D materials |
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| Materials/technologies |
| - | | Metal-Organic Frameworks (MOFs) | | - | | Covalent Organic Frameworks (COFs) | | - | | Inorganic Porous Materials (Porous Alumina, TiO2, ZnO) | | - | | Aerogels | | - | | Porous Hydrogels |
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Scientific expertise |
1. Microfluidics and nanofluidics
2. Metal-organic framework (MOF)/Covalent-organic framework (COF)/2D materials/Hydrogel
3. Single-pore device
4. Water-enabled energy generation (blue energy, electrokinetic energy, and energy generation from ambient)
5. Ion transport membrane
6. Ionic circuit
7. Colloid and interface sciences
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Relevant publications
(6 max.) |
| “Massively Enhanced Charge Selectivity, Ion Transport and Osmotic Energy Conversion by Anti-Swelling Nanoconfined Hydrogels”, Nano Letters, 24, 11756-11762 (2024) |
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| “Enhancing Ionic Selectivity and Osmotic Energy by Using an Ultrathin Zr-MOF-Based Heterogeneous Membrane with Trilayered Continuous Porous Structure”, Angewandte Chemie International Edition, 63, e202408375 (2024) |
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| “Engineered Heterogeneous Subnanochannel Membranes with a Tri-Continuous Pore Structure of Large Geometry Gradient for Massively Enhanced Osmotic Power Conversion from Organic Solutions”, Advanced Functional Materials, 34, 2306834 (2024) |
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| “Zwitterionic Gradient Double-Network Hydrogel Membranes with Superior Biofouling Resistance for Sustainable Osmotic Energy Harvesting”, Advanced Functional Materials, 33, 2211316 (2023) |
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| “Highly Selective and High-Performance Osmotic Power Generators in Subnanochannel Membranes Enabled by Metal-Organic Frameworks”, Science Advances, 7, eabe9924 (2021). |
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| “Rectification of Concentration Polarization in Mesopores Leads To High Conductance Ionic Diodes and High Performance Osmotic Power”, Journal of the American Chemical Society, 141, 3691-3698 (2019) |
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