The KIER has made history in Korea by successfully producing hydrogen of exceptional purity from ammonia, completely eliminating carbon dioxide emissions in the process.
NATIONAL RESEARCH COUNCIL OF SCIENCE & TECHNOLOGY
BASIC PRINCIPLES OF AMMONIA-BASED CARBON-FREE HYDROGEN PRODUCTION TECHNOLOGY (ABOVE)
COMPARISON OF EXISTING TECHNOLOGY AND KIER TECHNOLOGY (BELOW)
CREDIT: KOREA INSTITUTE OF ENERGY RESEARCH (KIER)
Dr. Jung Unho's research team at the Hydrogen Research Department of the Korea Institute of Energy Research (KIER) has developed Korea's first clean hydrogen production technology. This technology is based on ammonia decomposition and does not use fossil fuels. The team's breakthrough could pave the way for a more sustainable and eco-friendly energy source. This allows for the production of high-purity hydrogen that meets international standards for hydrogen-powered vehicles, without the carbon dioxide emissions produced by using fossil fuels.
Ammonia, a compound of hydrogen and nitrogen, has a hydrogen storage density 1.7 times higher than that of liquefied hydrogen, and it is gaining attention as the most cost-effective method for transporting hydrogen. In particular, as it has been used in various fields such as fertilizer for over 100 years, it is equipped with infrastructure, handling, and safety standards. It is considered the most practical solution to address hydrogen storage and transportation challenges.
Ammonia consists only of hydrogen and nitrogen, so no carbon is emitted when the hydrogen is separated. The decomposition process requires a supply of heat energy of over 600℃, and currently, fossil fuels are used, resulting in the emission of carbon dioxide. Therefore, to produce clean hydrogen, a carbon-free energy source must be used, even in the process of decomposing ammonia.
By utilizing the small quantities of hydrogen and ammonia left over from the decomposition reaction, the researchers were able to produce hydrogen without the use of fossil fuels.
To generate pure hydrogen from ammonia, the decomposition of ammonia is carried out at a temperature above 600℃ using a ruthenium (Ru) catalyst, followed by the purification of hydrogen through pressure swing adsorption (PSA*) technology. While carrying out this method, a residual gas mixture of nitrogen and hydrogen is formed and repurposed as a heating element for the ammonia decomposition reactor. Despite this, the residual gas alone does not offer sufficient heat of reaction, therefore extra heat must be added.
*Pressure Swing Adsorption (PSA): The most widely used process for hydrogen separation. This is an adsorption-based process used to separate a specific gas from a mixed gas, utilizing the adsorption equilibrium that gas molecules have on a specific adsorbent and separate gases by adjusting process pressure.
In the case of existing technology, insufficient heat of reaction are supplemented with fossil fuels such as natural gas (LNG) or liquefied petroleum gas (LPG), so carbon dioxide is emitted during combustion. However, using the system developed this time, by supplying ammonia instead of fossil fuels, heat of reaction can be supplied and carbon dioxide emissions can be blocked at the source.
Using the developed system, high-purity hydrogen of more than 99.97%, which can be supplied to fuel cells for hydrogen electric vehicles, is produced at 5Nm3 (approximately 0.45kg) per hour. In addition, the hydrogen produced has an impurity concentration of less than 300ppm for nitrogen and less than 0.1ppm for ammonia. It met ISO 14687*, the international standard for hydrogen-fueled electric vehicles.
*ISO 14687: international standard specifying minimum quality characteristics for hydrogen fuel distributed for use in vehicles and stationary applications
The research team has reached a significant milestone by demonstrating a 1kW fuel cell system for buildings that generates electricity without emitting carbon dioxide, using hydrogen extracted from ammonia. This demonstration, conducted in collaboration with Doosan Fuel Cell Power BU (Business Unit), is of great importance as it overcomes the issue of carbon dioxide emissions, which has been considered a disadvantage of natural gas (LNG) based fuel cell systems. It shows the potential to generate power using clean hydrogen fuel cells.
Ammonia-based hydrogen production system with 1 kW class PEMFC
1st Carbon-free Ammonia Decomposition Reactor
According to lead researcher Dr. Jung Unho, the newly developed technology holds great significance as it allows for carbon-free hydrogen production using ammonia, filling a previous gap in this area. There is an expectation that it will find practicality in diverse areas that use clean hydrogen. In his remarks, he went on to say, “The combining of ammonia and fuel cells presents a viable option for powering eco-ships. And as we scale up, we can also make a significant impact in the clean hydrogen power sector.“
Meanwhile, this research was conducted with the support of Korea Southern Power Co., Ltd. (KOSPO).
Evolution-capable AI promotes green hydrogen production using more abundant chemical elements
Searching for electrode materials free of platinum-group elements
IMAGE:
THIS RESEARCH TEAM DEVELOPED AN AI TECHNIQUE CAPABLE OF ACCURATELY PREDICTING THE COMPOSITIONS OF MATERIALS WITH DESIRABLE CHARACTERISTICS BY SWITCHING PREDICTION MODELS DEPENDING ON THE SIZES OF THE DATASETS AVAILABLE FOR ANALYSIS.
view moreCREDIT: KEN SAKAUSHI NATIONAL INSTITUTE FOR MATERIALS SCIENCE
1. A NIMS research team has developed an AI technique capable of expediting the identification of materials with desirable characteristics. Using this technique, the team was able to discover high-performance water electrolyzer electrode materials free of platinum-group elements—substances previously thought to be indispensable in water electrolysis. These materials may be used to reduce the cost of large-scale production of green hydrogen—a next-generation energy source.
2. Large-scale production of green hydrogen using water electrolyzers is a viable means of achieving carbon neutrality. Currently available water electrolyzers rely on expensive, scarce platinum-group elements as their main electrocatalyst components to accelerate the slow oxygen evolution reaction (OER)—an electrolytic water reaction that can produce hydrogen. To address this issue, research is underway to develop platinum-group-free, cheaper OER electrocatalysts composed of relatively abundant chemical elements compatible with large-scale green hydrogen production. However, identifying the optimum chemical compositions of such electrocatalysts from an infinitely large number of possible combinations had been found to be enormously costly, time-consuming and labor-intensive.
3. This NIMS research team recently developed an AI technique capable of accurately predicting the compositions of materials with desirable characteristics by switching prediction models depending on the sizes of the datasets available for analysis. Using this AI, the team was able to identify new, effective OER electrocatalytic materials from about 3,000 candidate materials in just a single month. For reference, manual, comprehensive evaluation of these 3,000 materials was estimated to take almost six years. These newly discovered electrocatalytic materials can be synthesized using only relatively cheap and abundant metallic elements: manganese (Mn), iron (Fe), nickel (Ni), zinc (Zn) and silver (Ag). Experiments found that under certain conditions, these electrocatalytic materials exhibit superior electrochemical properties to ruthenium (Ru) oxides—the existing electrocatalytic materials with the highest OER activity known. In Earth’s crust, Ag is the least abundant element among those constituting the newly discovered electrocatalytic materials. However, its crustal abundance is nearly 100 times that of Ru, indicating that these new electrocatalytic materials can be synthesized in sufficiently large amounts to enable hydrogen mass-production using water electrolyzers.
4. These results demonstrated that this AI technique could be used to expand the limits of human intelligence and dramatically accelerate the search for higher-performance materials. Using the technique, the team plans to expedite its efforts to develop new materials—mainly water electrolyzer electrode materials—in order to improve the efficiency of various electrochemical devices contributing to carbon neutrality.
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5. This project was carried out by a NIMS research team led by Ken Sakaushi (Principal Researcher) and Ryo Tamura (Team Leader). This work was conducted in conjunction with another project entitled, “High throughput search for seawater electrolysis catalysts by combining automated experiments with data science” (grant number: JPMJMI21EA) under the JST-Mirai Program mission area, “low carbon society.”
6. This research was published in ACS Central Science, an open access journal of the American Chemical Society, as an “ASAP (as soon as publishable) article” at 8:00 am on November 30, 2023, EST (https://doi.org/10.1021/acscentsci.3c01009).
JOURNAL
ACS Central Science
METHOD OF RESEARCH
Experimental study
SUBJECT OF RESEARCH
Not applicable
ARTICLE TITLE
Human-Machine Collaboration for Accelerated Discovery of Promising Oxygen Evolution Electrocatalysts with On-Demand Elements
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