SNU Researchers Develop Technology for Simultaneous Production of Purified Water and Hydrogen — Proposing a Sustainable Water Treatment Platform with Integrated Energy Recovery

SNU Researchers Develop Technology for Simultaneous Production of Purified Water and Hydrogen — Proposing a Sustainable Water Treatment Platform with Integrated Energy Recovery- Water purification and hydrogen generation achieved simultaneously via nanoelectrokinetic ion concentration polarization- Promising for use in infrastructure-limited environments such as disaster sites, spacecraft, and military operations- Published in Communications Materials, an international journal in materials science▲ (From left) Dr. Jihee Park (SNU Energy Initiative), Dr. Sehyuk Yoon (SNU Soft Foundry Institute), Dr. Sungjae Ha (ProvaLabs, Inc.), and Professor Sung Jae Kim (Department of Electrical and Computer Engineering, Seoul National University)Seoul National University College of Engineering announced that a research team led by Professor Sung Jae Kim from the Department of Electrical and Computer Engineering has developed a new energy-harvesting water purification system capable of producing both purified water and hydrogen simultaneously.This innovative technology removes impurities from saline water while reducing hydrogen ions at the electrode to generate hydrogen gas. The system integrates desalination and water electrolysis into a single process, thereby minimizing energy loss compared to conventional water-purification systems.Designed as a compact and modular unit, the system allows for flexible scalability through the assembly of multiple modules. This makes the technology highly promising for resource-limited environments, such as spacecraft, disaster areas, and remote military sites where clean water and energy supplies are strictly limited.Supported by the Korea Ministry of Science and ICT (MSIT) and the SNU Energy Initiative (SNUEI), the study has been published online in Communications Materials (Nature Portfolio, 2025), a leading journal in the field of materials science.Securing both clean water and clean energy is one of the most urgent global challenges. However, this problem is paradoxical: water purification requires electricity, while electricity production often requires water. As a result, there is a critical need for technologies that can address both challenges at once.To address this issue, Professor Kim’s research team developed a combined freshwater–hydrogen production platform based on ion concentration polarization (ICP)*, a nanoelectrokinetic phenomenon that enables salt removal and hydrogen generation within a single module using a cation exchange membrane.* Ion concentration polarization: When an electric field is applied across an ion-selective membrane, ions separate into enriched and depleted zones on opposite sides of the membrane.By integrating desalination and water electrolysis processes, the new system provides purified water while simultaneously producing hydrogen energy. The core mechanism operates as follows:When electrical current is applied across a cation exchange membrane (CEM), salt and other contaminants are removed on one side of the membrane, producing purified water. While on the other side, hydrogen ions (H⁺) receive electrons at the electrode and are reduced to hydrogen gas (H₂). In other words, a single electrochemical process produces purified water and hydrogen at the same time (see Figure 1).▲ Figure 1. (Left) Conceptual diagram of simultaneous freshwater–hydrogen production using ion concentration polarization(Right) Enlarged view of the region near the membrane, where salt-ion transport and hydrogen-ion transport occur simultaneously.To experimentally validate this principle, the team first fabricated a microfluidic device, enabling simultaneous visualization of hydrogen bubble generation and purified-water regions (ion-depleted zones) via fluorescence imaging. They then built a finger-sized meso-scale device using 3D printing, successfully achieving stable purified-water production and hydrogen generation at several milliliters per hour (see Figure 2).* Meso-scale: Size range between microscopic structures and macroscopic components, typically hundreds of micrometers to several centimeters.▲ Figure 2. (Left) Microfluidic experiment demonstrating simultaneous freshwater–hydrogen production(Center) Exploded view of the meso-scale freshwater–hydrogen production platform(Right) Experimental demonstration of simultaneous freshwater–hydrogen generation in the 3D-printed meso-scale deviceThe system recovered approximately 10% of the electrical energy used for purification in the form of hydrogen energy. Hydrogen production increased linearly with increasing current, confirming the feasibility of scaling. Moreover, the device consistently produced purified water even from high-salinity brines, demonstrating its potential for seawater and highly saline water applications.Unlike existing technologies such as electrodialysis (which requires complex alternating ion-exchange membrane stacks) and reverse osmosis* (which requires high-pressure pumping), the proposed system operates using a single membrane structure and functions without high pressure pumps. This simplicity and lightweight form factor make the device ideal for portable or distributed water purification systems.* Reverse osmosis: A water purification technology that uses a semipermeable membrane and high pressure to allow water molecules to pass through while blocking salts and contaminants. It is commonly used for seawater desalination and the production of high-purity water.Professor Kim’s team has demonstrated a technology to recover a portion of the electrical energy used in water purification in the form of hydrogen gas—recovering approximately 8–10% of energy that would otherwise be lost in conventional ICP desalination. If the produced hydrogen is supplied to a fuel cell, the system could evolve into a self-powered, energy-autonomous water purification platform, capable of generating a part of its own operating electricity.Because the device is designed as a modular, scalable platform, capacity can be increased by connecting multiple units in parallel—similar to assembling LEGO blocks. This adaptability enables applications ranging from small personal purifiers to mobile purification units for disaster response, as well as operations in military or space environments.Notably, this ICP-based system is capable of removing not only salt but also heavy metals, fine particulates, and bio contaminants, suggesting wide applicability in practical fields such as environmental remediation, water treatment, biomedical devices like artificial kidneys.▲ Figure 3. Conceptual rendering of a field-deployable water treatment platform capable of self-sustaining power generation when integrated with hydrogen fuel cells and renewable energy systemsProfessor Sung Jae Kim, corresponding author of the study, stated, “The key significance of this research is that it demonstrates a system capable of addressing water and energy challenges simultaneously, rather than handling them separately. We plan to further expand the modular design for large-scale implementation so that anyone—whether in disaster zones or spacecraft—can easily secure both water and energy even in extreme environments.”Co-corresponding author Dr. Sungjae Ha (ProvaLabs, Inc.) added, “This is one of the first demonstrations of nanoelectrokinetic technology for concurrent hydrogen production and desalination, establishing a foundation for water–energy self-sufficiency.”First author Dr. Jihee Park (SNU Energy Initiative) noted, “A major discovery of this research is that ion transport occurring during purification can be harnessed to recover energy at the same time. This work presents the possibility of small-scale purifiers that partially power themselves—marking a starting point for next-generation sustainable technologies addressing both environmental issues and energy shortages.”Co–first author Dr. Sehyuk Yoon (SNU Soft Foundry Institute) added, “This study demonstrates that ICP-based microfluidic technologies can be expanded to meso-scale devices with verified operational performance. The integration of desalination and hydrogen production within a single module shows strong potential for future field-deployable water and energy systems.”Dr. Jihee Park and Dr. Sehyuk Yoon continue to work in the SNU Energy, Environment and Sustainability Laboratory, developing methods to further enhance system efficiency. They also plan to pursue research on battery metal dendrite suppression and energy resource recovery in future energy applications.* Dendrite: Tree-like needle-shaped crystals that can form in battery electrodes.[Reference Materials]- Supplementary video: attached via email- Paper Title / Journal: Energy-Efficient Modular Water Purification System via Concurrent Freshwater and Hydrogen Generation Using Ion Concentration Polarization, Communications Materials (Nature Portfolio)- DOI: https://doi.org/10.1038/s43246-025-01001-z- Authors: Jihee Park, Sehyuk Yoon, Myeonghyeon Cho, Dongguen Eom, Beomjoon Kim, Hyomin Lee, Wonseok Kim, Sangwook Park, Sungjae Ha, and Sung Jae Kim- Corresponding Authors: Professor Sung Jae Kim (SNU Department of Electrical and Computer Engineering) / Dr. Sungjae Ha (ProvaLabs, Inc.)- Funding: Ministry of Science and ICT (MSIT) and SNU Energy Initiative (SNUEI)[Contact Information] Professor Sung Jae Kim, Department of Electrical and Computer Engineering, Seoul National University / +82-2-880-1665 / gates@snu.ac.kr  

SNU Researchers Solve 40-Year Physics Mystery, Revealing High-Temperature Superconductivity Mechanism through “Thermal Decoupling”

SNU Researchers Solve 40-Year Physics Mystery, Revealing High-Temperature Superconductivity Mechanism through “Thermal Decoupling”- Published in Materials Today Physics, an international journal in materials physics- Lays the groundwork for advances in quantum devices, power transmission, quantum computing, magnetic levitation, and energy storage technologies▲ Research team members (from left): Prof. Gun-Do Lee, Research Professor at the Research Institute of Advanced Materials, Seoul National University (corresponding author); Dr. Sungwoo Lee, Researcher at the Research Institute of Advanced Materials, Seoul National University (first author); Prof. Young-Kyun Kwon, Department of Physics, Kyung Hee University; and Prof. Miyoung Kim, Department of Materials Science and Engineering, Seoul National University.A research team from the High-Temperature Superconductivity Research Group at Seoul National University, led by Prof. Gun-Do Lee, Research Professor at the Research Institute of Advanced Materials, has successfully explained the fundamental origin of high-temperature superconductivity—an unresolved question in physics for nearly 40 years—through a novel concept called “thermal decoupling.”The study provides a quantitative explanation for a wide range of experimental results that could not be understood under traditional electron-centered theories, and has been recognized as presenting a new paradigm in superconductivity research.These findings were published online on October 27 in Materials Today Physics (Impact Factor 9.7), an international academic journal in the field of materials physics, under the title “Thermal Decoupling in High-Tc Cuprate Superconductors.”Superconductivity—the state in which electric current flows without resistance—was first discovered in 1911 by Dutch physicist Heike Kamerlingh Onnes. In 1957, American physicists John Bardeen, Leon Cooper, and Robert Schrieffer developed the BCS (Bardeen–Cooper–Schrieffer) theory, explaining the mechanism behind superconductivity, for which they later received the Nobel Prize in Physics. However, this theory only applied to materials at temperatures below roughly –250°C (around 25 K).In 1986, Bednorz and Müller at IBM Zurich Research Laboratory discovered that cuprate oxides exhibited superconductivity even at –240°C, and subsequent research found superconductivity at –140°C under atmospheric pressure. Since then, physicists around the world have been grappling with the fundamental question: “Why does superconductivity occur at such high temperatures?”Professor Lee’s team at SNU determined that previous approaches over the past four decades had failed because they focused solely on the electronic properties of materials. Instead, the team turned its attention to the thermal properties of layered high-temperature superconductors. They found that most high-temperature superconducting materials have a layered (two-dimensional) crystal structure, with each layer composed of different elements, resulting in weak interlayer coupling. Remarkably, they discovered that below about –70°C (≈200 K), the flow of heat between layers is severed, leading to a phenomenon they termed “thermal decoupling.”In particular, the team found that the CuO₂ layers—composed of copper and oxygen, where superconductivity actually occurs—maintain a low effective temperature inside YBCO (yttrium barium copper oxide) and thus satisfy the BCS theory conditions. However, experimental measurements typically reflect the higher surface temperature of the barium–oxygen layers, explaining why past experimental data appeared inconsistent with theoretical predictions. The key factor responsible for this temperature difference was identified as alkaline earth metals such as barium (Ba), which modulate ionic bonding between layers and block heat transfer.* Alkaline earth metals: Elements belonging to Group 2 of the periodic table.Moreover, theoretical calculations showed that once this temperature separation effect is accounted for, long-standing puzzles—including the linear temperature dependence of resistivity, the Uemura relation, the superconducting dome, and the reduced isotope effect—can all be quantitatively explained within a single unified framework.* Linear-T resistivity: In conventional metals, electrical resistance before the superconducting transition follows a quadratic temperature dependence as predicted by Fermi liquid theory. In contrast, almost all high-temperature superconductors show resistance that varies linearly with temperature.* Uemura relation: The critical temperature of high-Tc superconductors is proportional to their Fermi temperature.* Superconducting dome: The critical temperature of high-Tc materials increases with carrier doping and then decreases again, forming a dome-like dependence.* Reduced isotope effect: According to BCS theory, the superconducting critical temperature in low-Tc materials is inversely proportional to the square root of the isotope mass. In high-Tc superconductors, this effect is dramatically reduced.By uncovering the mechanism behind high-temperature superconductivity—a long-standing challenge in condensed matter physics—this study is expected to accelerate innovation beyond semiconductor-based electronics, paving the way for quantum devices, power transmission, quantum computing, magnetic levitation, and energy storage technologies. The team has already filed a patent based on the core ideas for developing superconductors near room-temperature, and plans to begin machine learning–based exploration of new high-Tc superconducting materials in the near future.Prof. Gun-Do Lee commented, “This study introduces a new physical paradigm that goes beyond the conventional concept of thermal equilibrium. Like Einstein’s theory of relativity or Planck’s quantum theory in their early days, it may provoke intense debate—but that is precisely what drives physics forward. We also expect experimental verification of thermal decoupling to emerge soon.”Dr. Sungwoo Lee, the first author who performed the key theoretical calculations at SNU’s Research Institute of Advanced Materials, will extend this research to explore whether the thermal decoupling mechanism also applies to other high-Tc materials such as magic-angle twisted bilayer graphene and Kagome superconductors.This work was supported by the “Future Promising Convergence Technology Pioneer” National Science Challenge Project of the Ministry of Science and ICT (MSIT) and the National Research Foundation of Korea (NRF), as well as by the KISTI Supercomputing Center’s Grand Challenge Research Project.▲ Figure 1. Schematic illustration showing how thermal decoupling within cuprate superconductors gives rise to high-temperature superconductivity.▲ Figure 2. According to the thermal decoupling model, the effective temperature of barium (Ba) in YBCO is relatively high, meaning that the distance between Ba and the underlying superconducting CuO₂ plane (arrows in the right-hand figure) is expected to influence the critical temperature (Tc, left-hand figure).Remarkably, as shown in the left graph, experimental data from three independent research groups demonstrate that the variation in Ba–CuO₂ distance (red, yellow, and blue points) with doping concentration matches precisely with the variation in critical temperature (black points).[Reference Materials]- Title/Journal : “Thermal decoupling in high-Tc cuprate superconductors”, Materials Today Physics- DOI : https://doi.org/10.1016/j.mtphys.2025.101916[Contact Information]Prof. Gun-Do Lee, Research Professor, Research Institute of Advanced Materials, Seoul National University / +82-10-3207-1058 / gdlee@snu.ac.kr

SNU Researchers Develop Holographic AR Display with Enhanced Realism via Occlusion Effect

SNU Researchers Develop Holographic AR Display with Enhanced Realism via Occlusion Effect- Selected as a cover paper in Laser & Photonics Reviews, a world-renowned optics journal- Enables next-generation immersive display applications by creating a natural AR environment  ▲ (From left) Professor Jae-Hyeung Park (corresponding author), Ph.D. candidate Woongseob Han (first author), and integrated master’s–Ph.D. student Chanseul Lee, Department of Electrical and Computer Engineering, Seoul National University (SNU).Seoul National University College of Engineering announced that a research team led by Professor Jae-Hyeung Park from the Department of Electrical and Computer Engineering has developed a holographic augmented reality (AR) display that significantly enhances realism through the incorporation of optical occlusion effects.By combining a holographic display with an occlusion optics system, the researchers succeeded in improving the visual realism of AR environments. Furthermore, they demonstrated opaque 3D virtual images and optically generated virtual shadows, reproducing the visual effect of virtual objects interacting naturally with real-world environments.Recognizing that visual information in AR environments tends to concentrate around virtual objects rather than being distributed across the entire space, the team also introduced an AI-based hologram generation algorithm optimized for sparse holographic imagery*.* Sparse holographic image: A hologram in which visual information is concentrated only in certain regions of the spatial field rather than uniformly distributed.The study, titled “Enhancing Realism in Holographic Augmented Reality Displays Through Occlusion Handling,” was published on October 7 as an inside cover article in Laser & Photonics Reviews (Impact Factor: 10.0), a leading international journal in optics published by Wiley-VCH (Germany).▲ Inside cover image of Laser & Photonics Reviews.AR glasses, often regarded as the next-generation smart device following smartphones, have advanced rapidly due to major global investments. However, most commercial or prototype AR glasses still lack the occlusion effect, in which virtual imagery can block or obscure real-world objects. Without this effect—a key visual cue for human depth perception—virtual images appear semi-transparent and overlaid on real objects, significantly reducing the realism and immersion of AR experiences.Additionally, current AR glasses typically reconstruct 3D imagery using only binocular disparity (the difference between the two eyes’ views) while keeping monocular depth cues fixed, leading to the vergence–accommodation conflict (VAC)—a mismatch between the eyes’ focus and convergence cues. This mismatch often causes eye strain and visual discomfort, hindering the widespread adoption of near-eye displays such as AR headsets.To address these issues, prior research has attempted to incorporate occlusion optics that selectively block real-world light in front of the display to create opaque virtual images, or to reproduce monocular depth using holography, light-field, or varifocal technologies. However, no previous study had successfully combined both occlusion and true 3D holographic rendering, leaving room for more advanced solutions to achieve realistic AR visuals.Professor Jae-Hyeung Park's research team has developed a holographic AR display that achieves the most realistic AR environment by combining a holographic AR display capable of reproducing ideal three-dimensional images with an optical occlusion system that optically masks the actual background. The researchers first observed that the Fourier filter structure in a 4f optical system—commonly used to remove noise in holographic displays—shares the same architecture as an occlusion optics system. Leveraging this insight, they implemented a single Digital Micromirror Device (DMD) within a single 4f optical system to function both as a Fourier filter and an occlusion mask, using time multiplexing to perform occlusion control and noise filtering simultaneously.* Fourier filter structure: An optical setup that analyzes image frequency components to selectively remove or correct noise.* DMD (Digital Micromirror Device): A reflective optical element composed of thousands of tiny mirrors that rapidly adjust brightness and pattern of holographic images.Furthermore, unlike conventional static Fourier filters, the team incorporated the dynamic modulation capability of the DMD into their AI-based hologram generation algorithm. This drastically reduced the optimizer’s search space, improving the Peak Signal-to-Noise Ratio (PSNR) of sparse holographic images by an average of 11 decibels (dB) compared to existing methods. In addition, by employing time multiplexing, they successfully suppressed speckle noise*—a granular interference pattern that degrades holographic image quality—and doubled the field of view (FOV) of the holographic display.* Speckle noise: A granular pattern of noise caused by optical interference in coherent light systems.* PSNR: A standard metric for measuring image quality; higher PSNR indicates better reconstruction fidelity.Based on the proposed system, the team fabricated a benchtop prototype to experimentally reproduce opaque 3D AR images in which virtual objects visibly block real backgrounds. They further demonstrated AR scenes where virtual objects cast shadows onto real environments through optical occlusion, achieving unprecedented realism. Experimental results showed significant improvements in contrast and clarity compared to conventional AR setups without occlusion, successfully realizing the world’s first high-contrast, interference-free 3D AR scenes.* Benchtop prototype: A small-scale experimental device built to verify the performance and working principles of a system prior to commercialization.▲ Figure 1. Experimental results showing holographic 3D images that obscure the real background and cast virtual shadows through the proposed occlusion-based system.This research marks an important milestone by realizing a truly interactive AR system in which virtual imagery optically interacts with real-world light. The proposed technology enables natural AR environments where virtual objects can selectively block or cast shadows on real scenes, representing a key advancement toward next-generation immersive display technologies.Moreover, the study offers a new research direction by integrating dynamic Fourier filtering directly into the hologram generation algorithm, shifting away from purely software-based optimization. This hardware–algorithm co-design approach demonstrates how physical devices can enhance computational performance, paving the way for advanced co-optimized architectures in future immersive display systems.Professor Jae-Hyeung Park, who led the research, stated, “Our study demonstrates a new paradigm for augmented reality—one where virtual imagery can physically interact with light from the real world. We will continue to pursue research that merges optics and artificial intelligence to create next-generation display technologies that deliver more natural and immersive visual experiences.”The first author, Woongseob Han, is currently pursuing his Ph.D. in the Department of Electrical and Computer Engineering at Seoul National University, focusing on AR/VR near-eye displays and next-generation 3D display technologies. After graduation, he plans to work as an optical design engineer specializing in immersive display systems at research institutes or global technology companies.[Reference Materials]- Title/Journal : “Enhancing Realism in Holographic Augmented Reality Displays Through Occlusion Handling”, Laser & Photonics Reviews- DOI : https://doi.org/10.1002/lpor.202501052[Contact Information]Professor Jae-Hyeung Park, Three-Dimensional Optical Engineering Laboratory, Department of Electrical and Computer Engineering, Seoul National University / +82-2-880-1825 / jaehyeung@snu.ac.kr