Ryoo Ryong

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Ryoo Ryong
yuryonggyosunim Ryong Ryoo.jpg
Born1955 (age 6869)
Hwaseong, Gyeonggi, Republic of Korea
Nationality Korean
Alma mater Seoul National University
Korea Advanced Institute of Science and Technology
Stanford University
Known for Porous materials, zeolite, carbon, catalysis
Awards Clarivate Citation Laureate (2014)
Top Scientist and Technologist Award of Korea (2005)
National Scientist of the Republic of Korea (2007)
Ho-Am Prize in Science (2010)
Breck Award by International Zeolite Association (2010)
Scientific career
Fields Chemistry
Institutions Korea Advanced Institute of Science and Technology, Institute for Basic Science
Thesis Platinum Clusters in Y-Zeolite – Studies by Physical and Chemical Probes
Doctoral advisor Michel Boudart
Korean name
Hangul
유룡
Revised Romanization Yu Ryong
McCune–Reischauer Yu Ryong
Website http://rryoo.kaist.ac.kr/

Ryoo Ryong FRSC (born 1955 [1] ) is a distinguished professor of chemistry at KAIST in Daejeon, South Korea. [2] He was the head of the Center for Nanomaterials and Chemical Reactions, an Extramural Research Center of the Institute for Basic Science. Ryoo has won a variety of awards, including the Top Scientist and Technologist Award of Korea given by the South Korean government in 2005. He obtained the KOSEF Science and Technology Award in 2001 for his work on the synthesis and crystal structure of mesoporous silica. [3]

Contents

Ryoo obtained his bachelor's degree from Seoul National University in 1977, [2] [4] his master's from KAIST in 1979, [2] [4] and his doctorate from Stanford University in 1986. [4] After completing his master's degree, he worked for three years at the Korean Atomic Energy Research Institute. After returning to Korea in 1986, he took a position with KAIST.

In 2006, Ryoo and his research team announced the discovery of a form of zeolite that can catalyze petrochemical reactions much more effectively than previous zeolites. Because of the potential of this to streamline the gasoline refining process, it was greeted as a "magical substance" by the South Korean press. [5]

Education

Ryoo graduated Suwon High School, then graduated with a bachelor's degree in applied chemistry from the Seoul National University. He received his PhD in chemistry from Stanford University in 1985 under the supervision of Prof. Michel Boudart. [2] His PhD thesis is Platinum Clusters in Y-Zeolite – Studies by Physical and Chemical Probes. Prior to the PhD course, Ryoo worked at Korea Atomic Energy Research Institute as a researcher.

Work

After obtaining his Ph.D. from Stanford University in 1986, Ryoo worked at Lawrence Berkeley Laboratory (U. C. Berkeley) as a Postdoctoral Fellow. He studied solid-state NMR under the supervision of Prof. Alex Pines (Jan. 1986 - Nov. 1986). Then he moved to the Department of Chemistry at KAIST as a professor (Dec. 1986).

During his research at KAIST, Ryoo laid scientific cornerstones on nanoporous carbon and hierarchically nanoporous zeolite materials science. He developed a hard-templating synthesis strategy toward nanoporous carbon material and its application to the research field of fuel cells. [6] [7] This synthesis strategy is being evaluated as a creative and innovative approach for synthesis of not only nanoporous carbon, but also other nanoporous materials such as zeolites, polymers and metal oxides.

In addition, Ryoo has been focusing on the synthesis of hierarchically nanoporous zeolite materials and their catalytic applications. In this work, he proposed several innovative synthesis strategies in porous materials preparation. He reported the organosilane-directed synthesis route to the mesoporous zeolites. [8] Ryoo also released an article on the synthesis of single-unit-cell thick nanosheet zeolites. [9] In this approach, a surfactant chemically incorporating a zeolite structure-directing head group was used, which can generate zeolite micropores as well as mesoporous structures simultaneously in a single synthesis step.

Ryoo received the Breck Award from the International Zeolite Association in 2010. In 2011, he extended the surfactant-directing synthesis strategy to various nanoporous structures such as hexagonal honeycomb and disordered nanosponge, rather than lamellar-type nanosheet, and reported these results in Science (2011). In 2007, Ryoo was named National Scientist of the Republic of Korea and has received research funds as part of the award. In addition, he became a distinguished professor in the Department of Chemistry at KAIST in 2008. He is a fellow of the Royal Society of Chemistry, and member of the Editorial Board for both Chemical Communications and ChemCatChem.

Awards and honors

Highlight papers

Ryoo, R., et al. “Rare-earth–platinum alloy nanoparticles in mesoporous zeolite for catalysis”, Nature, 2020. [21]
Kim, K., et al. “Lanthanum-catalysed synthesis of microporous 3D graphene-like carbons in a zeolite template”, Nature, 2016. [22]
Na, K., et al. “Directing Zeolite Structures into Hierarchically Nanoporous Architectures”, Science, 2011. [23]
Choi, M., et al. “Stable single-unit-cell nanosheets of zeolite MFI as active and long-lived catalysts”, Nature, 2009. [9]
Choi, M., et al. “Amphiphilic organosilane-directed synthesis of crystalline zeolite with tunable mesoporosity”, Nature Materials, 2006. [24]
Choi, M., et al. “Ordered nanoporous polymer-carbon composites”, Nature Materials, 2003. [25]
Joo, S. H., et al. “Ordered nanoporous arrays of carbon supporting high dispersions of platinum nanoparticles”, Nature, 2001. [26]
Sakamoto, Y., et al. “Direct imaging of the pores and cages of three-dimensional mesoporous materials”, Nature, 2000. [27]

See also

Related Research Articles

<span class="mw-page-title-main">Mesoporous material</span>

A mesoporous material is a nanoporous material containing pores with diameters between 2 and 50 nm, according to IUPAC nomenclature. For comparison, IUPAC defines microporous material as a material having pores smaller than 2 nm in diameter and macroporous material as a material having pores larger than 50 nm in diameter.

<span class="mw-page-title-main">Nanoporous materials</span>

Nanoporous materials consist of a regular organic or inorganic bulk phase in which a porous structure is present. Nanoporous materials exhibit pore diameters that are most appropriately quantified using units of nanometers. The diameter of pores in nanoporous materials is thus typically 100 nanometers or smaller. Pores may be open or closed, and pore connectivity and void fraction vary considerably, as with other porous materials. Open pores are pores that connect to the surface of the material whereas closed pores are pockets of void space within a bulk material. Open pores are useful for molecular separation techniques, adsorption, and catalysis studies. Closed pores are mainly used in thermal insulators and for structural applications.

<span class="mw-page-title-main">Mesoporous silica</span> Nano-scale porous silica compound

Mesoporous silica is a form of silica that is characterised by its mesoporous structure, that is, having pores that range from 2 nm to 50 nm in diameter. According to IUPAC's terminology, mesoporosity sits between microporous (<2 nm) and macroporous (>50 nm). Mesoporous silica is a relatively recent development in nanotechnology. The most common types of mesoporous nanoparticles are MCM-41 and SBA-15. Research continues on the particles, which have applications in catalysis, drug delivery and imaging. Mesoporous ordered silica films have been also obtained with different pore topologies.

<span class="mw-page-title-main">Zeolitic imidazolate framework</span>

Zeolitic imidazolate frameworks (ZIFs) are a class of metal-organic frameworks (MOFs) that are topologically isomorphic with zeolites. ZIF glasses can be synthesized by the melt-quench method, and the first melt-quenched ZIF glass was firstly made and reported by Bennett et al. back in 2015. ZIFs are composed of tetrahedrally-coordinated transition metal ions connected by imidazolate linkers. Since the metal-imidazole-metal angle is similar to the 145° Si-O-Si angle in zeolites, ZIFs have zeolite-like topologies. As of 2010, 105 ZIF topologies have been reported in the literature. Due to their robust porosity, resistance to thermal changes, and chemical stability, ZIFs are being investigated for applications such as carbon dioxide capture.

Carbide-derived carbon (CDC), also known as tunable nanoporous carbon, is the common term for carbon materials derived from carbide precursors, such as binary (e.g. SiC, TiC), or ternary carbides, also known as MAX phases (e.g., Ti2AlC, Ti3SiC2). CDCs have also been derived from polymer-derived ceramics such as Si-O-C or Ti-C, and carbonitrides, such as Si-N-C. CDCs can occur in various structures, ranging from amorphous to crystalline carbon, from sp2- to sp3-bonded, and from highly porous to fully dense. Among others, the following carbon structures have been derived from carbide precursors: micro- and mesoporous carbon, amorphous carbon, carbon nanotubes, onion-like carbon, nanocrystalline diamond, graphene, and graphite. Among carbon materials, microporous CDCs exhibit some of the highest reported specific surface areas (up to more than 3000 m2/g). By varying the type of the precursor and the CDC synthesis conditions, microporous and mesoporous structures with controllable average pore size and pore size distributions can be produced. Depending on the precursor and the synthesis conditions, the average pore size control can be applied at sub-Angstrom accuracy. This ability to precisely tune the size and shapes of pores makes CDCs attractive for selective sorption and storage of liquids and gases (e.g., hydrogen, methane, CO2) and the high electric conductivity and electrochemical stability allows these structures to be effectively implemented in electrical energy storage and capacitive water desalinization.

Mesoporous organosilica are a type of silica containing organic groups that give rise to mesoporosity. They exhibit pore size ranging from 2 nm - 50 nm, depending on the organic substituents. In contrast, zeolites exhibit pore sizes less than a nanometer. PMOs have potential applications as catalysts, adsorbents, trapping agents, drug delivery agents, stationary phases in chromatography and chemical sensors.

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A nanosheet is a two-dimensional nanostructure with thickness in a scale ranging from 1 to 100 nm.

<span class="mw-page-title-main">MCM-41</span>

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References

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  5. "Korean Scientists Create Magical Substance". Archived from the original on August 18, 2006. Retrieved May 14, 2013.
  6. Ryoo, Ryong; Joo, Sang Hoon; Jun, Shinae (27 August 1999). "Synthesis of highly ordered carbon molecular sieves via template-mediated structural transformation". The Journal of Physical Chemistry B. 103 (37): 7743–7746. doi:10.1021/jp991673a . Retrieved 5 October 2018.
  7. Joo, Sang Hoon; Choi, Seong Jae; Oh, Ilwhan; Kwak, Juhyoun; Liu, Zheng; Terasaki, Osamu; Ryoo, Ryong (12 July 2001). "Ordered nanoporous arrays of carbon supporting high dispersions of platinum nanoparticles". Nature. 412 (6843): 169–172. Bibcode:2001Natur.412..169J. doi:10.1038/35084046. PMID   11449269. S2CID   4428691 . Retrieved 5 October 2018.
  8. Choi, Minkee; Cho, Hae Sung; Srivastava, Rajendra; Venkatesan, Chithravel; Choi, Dae-Heung; Ryoo, Ryong (6 August 2006). "Amphiphilic organosilane-directed synthesis of crystalline zeolite with tunable mesoporosity" (PDF). Nature Materials. 5 (9): 718–723. Bibcode:2006NatMa...5..718C. doi:10.1038/nmat1705. PMID   16892049. S2CID   16490891 . Retrieved 5 October 2018.
  9. 1 2 Choi, Minkee; Na, Kyungsu; Kim, Jeongnam; Sakamoto, Yasuhiro; Terasaki, Osamu; Ryoo, Ryong (10 September 2009). "Stable single-unit-cell nanosheets of zeolite MFI as active and long-lived catalysts". Nature. 461 (7261): 246–249. Bibcode:2009Natur.461..246C. doi:10.1038/nature08288. PMID   19741706. S2CID   4336470.
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  21. Ryoo, Ryong; Kim, Jaeheon; Jo, Changbum; Han, Seung Won; Kim, Jeong-Chul; Park, Hongjun; Han, Jongho; Shin, Hye Sun; Shin, Jae Won (September 2020). "Rare-earth–platinum alloy nanoparticles in mesoporous zeolite for catalysis". Nature. 585 (7824): 221–224. doi:10.1038/s41586-020-2671-4. ISSN   1476-4687. PMID   32908262. S2CID   221622573.
  22. Kim, Kyoungsoo; Lee, Taekyoung; Kwon, Yonghyun; Seo, Yongbeom; Song, Jongchan; Park, Jung Ki; Lee, Hyunsoo; Park, Jeong Young; Ihee, Hyotcherl; Cho, Sung June; Ryoo, Ryong (29 June 2016). "Lanthanum-catalysed synthesis of microporous 3D graphene-like carbons in a zeolite template". Nature. 535 (7610): 131–135. Bibcode:2016Natur.535..131K. doi:10.1038/nature18284. PMID   27362224. S2CID   4399216.
  23. Na, Kyungsu; Jo, Changbum; Kim, Jeongnam; Cho, Kanghee; Jung, Jinhwan; Seo, Yongbeom; Messinger, Robert J.; Chmelka, Bradley F.; Ryoo, Ryong (15 Jul 2011). "Directing zeolite structures into hierarchically nanoporous architectures". Science. 333 (6040): 328–332. Bibcode:2011Sci...333..328N. doi:10.1126/science.1204452. PMID   21764745. S2CID   14776142.
  24. Choi, Minkee; Cho, Hae Sung; Srivastava, Rajendra; Venkatesan, Chithravel; Choi, Dae-Heung; Ryoo, Ryong (6 August 2006). "Amphiphilic organosilane-directed synthesis of crystalline zeolite with tunable mesoporosity". Nature Materials. 5 (9): 718–723. Bibcode:2006NatMa...5..718C. doi:10.1038/nmat1705. PMID   16892049. S2CID   16490891.
  25. Choi, Minkee; Ryoo, Ryong (22 June 2003). "Ordered nanoporous polymer–carbon composites". Nature Materials. 2 (7): 473–476. Bibcode:2003NatMa...2..473C. doi:10.1038/nmat923. PMID   12819774. S2CID   13827560.
  26. Joo, Sang Hoon; Choi, Seong Jae; Oh, Ilwhan; Kwak, Juhyoun; Liu, Zheng; Terasaki, Osamu; Ryoo, Ryong (12 July 2001). "Ordered nanoporous arrays of carbon supporting high dispersions of platinum nanoparticles". Nature. 412 (6843): 169–172. Bibcode:2001Natur.412..169J. doi:10.1038/35084046. PMID   11449269. S2CID   4428691.
  27. Sakamoto, Yasuhiro; Kaneda, Mizue; Terasaki, Osamu; Zhao, Dong Yuan; Kim, Ji Man; Stucky, Galen; Shin, Hyun June; Ryoo, Ryong (23 November 2000). "Direct imaging of the pores and cages of three-dimensional mesoporous materials". Nature. 408 (6811): 449–453. Bibcode:2000Natur.408..449S. doi:10.1038/35044040. PMID   11100722. S2CID   4425165.
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