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A “Hole” Lot of Sponge! New Technique to Create Organic-Inorganic Hybrid Super-sponges is a Game Changer

  • 조회. 1786
  • 등록일. 2020.05.27
  • 작성자. Public Relations Team

Scientists have devised new methods for the post-synthetic modification of Metal-Organic Frameworks to produce properties in the material ideal for gas manipulation.

 

Metal-organic frameworks (MOFs) are sponge-like organic-inorganic hybrid materials and have a variety of uses due to their ultra-high “porosity,” or the ratio of pores or air pockets to the solid material. Through a technique called “post-synthetic modification,” Professor Jinhee Park and her research team were able to enhance and modify the function of these materials for specific purposes. 

 

Professor Jinhee Park (right) and her student Byeongchan Lee (left) of DGIST

Professor Jinhee Park (right) and her student Byeongchan Lee (left) of DGIST. ⓒDGIST 


Metal-organic frameworks (MOFs) are unique micromaterial compounds consisting of a sponge-like network of metal ions or clusters linked together by organic linkers, and are able to store specific gas molecules in their pores. MOFs have such a high surface area due to their porosity that a single gram of the material has enough surface area to cover the size of a football field!

These super-sponges are used in research and industry to separate and store gases within tailor-made pockets, enabling their use as gas storage, separations, and sensing. Unlike traditional porous materials, MOFs can be modified as per need; in theory, their structure can be controlled through careful selection of the components of the synthesis process. But in practice, this process is challenged by the restricted synthetic conditions and high thermal and chemical sensitivity of MOFs. An attractive alternative is the post-synthetic modification (PSM) of MOFs.

Leading a team of scientists from Daegu Gyeongbuk Institute of Science and Technology (DGIST), Korea, Professor Jinhee Park approached this issue with the dual goals of giving desired functional groups to MOFs and introducing “mesoscopic” (bigger than microscopic) holes, which improve adsorption kinetics. Professor Park shares her convictions, stating, “We believe that this kind of study can facilitate the use of MOFs as a key material in environmental and energy related areas.” 

PSM via carbon-carbon bond formation has historically been difficult due to the lack of suitable reaction conditions that maintain the MOF structures. The scientists introduced stable carbon-carbon bonds by converting existing carbon-hydrogen bonds using elevated temperatures and adding “electrophilic organic halides or carbonyl compounds”, allowing simultaneous introduction of the required functional groups as well as the mesoscopic holes.

Professor Park reports, “These results confirm the ability of the dual-PSM protocol to introduce desired alterations in MOFs while generating highly porous mesostructures.” This technique could potentially improve the safety of workers in enclosed, gas-filled environments such as in the nuclear industry, and provide a more economically viable method of gas storage and purification.


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For more information, contact:
Jinhee Park, Assistant Professor
Department of Emerging Materials Science,
Daegu Gyeongbuk Institute of Science and Technology (DGIST)
E-mail: jinhee@dgist.ac.kr

Associated Links
Research Paper in the journal of Angewandte International Edition
DOI: 10.1002/anie.20200027

Journal Reference
Byeongchan Lee, Dohyun Moon,* and Jinhee Park*, "Microscopic and Mesoscopic Dual-Post-Synthetic Modifications of Metal-Organic Frameworksr", Angewandte International Edition A Journal of the Gesellschaft Deutscher Chemiker Chemie, on-line published on 27th April 2020.

 

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