LLO
-
The 2016 Research Highlights
KAIST has selected the ten most outstanding projects of 2016 conducted by its faculty and researchers. This selection embodies the KAIST research portfolios that translate their discoveries into meaningful and measurable impact toward a better world. All of them demonstrate exceptional creativity, which open new research paths for each field in its novelty, innovation, and impact.
The following list has been reviewed by a committee of faculty peers headed by Associate Vice President for Research. Following are the 2016 KAIST research highlights:
□ Commercialization of 3D Holographic Microscopy
By YongKeun Park of the Department of Physics
Professor YongKeun Park and his colleagues develop a powerful technique to measure 3D images of live cells without labeling agents. This technique, called 3D holographic microscopy or holotomography, will open a new avenue for the study of cell biology and its applications in medical diagnosis. This research also led to the founding of a start-up company Tomocube Inc. and the successful commercialization of the technique.
Professor Park and his research team developed a solution based on digital holography technology used to visualize 3D refractive index tomograms of live cells without staining. This allowed the real-time observation of biological cells in 2D, 3D, and 4D without the use of labeling agents. Conventional techniques for 3D cell imaging requires the use of labeling agents such as fluorescence dyes and proteins, which prevent from investigating the physiology of intact untreated cells. In particular, label-free imaging capability becomes more important in several emerging fields such as stem cell research and immunotherapy.
The team employs the concept of 3D digital holography to achieve the optical measurements of 3D refractive index tomograms of live cells and tissues. Also, a digital micromirror device (DMD), which has been used for DLPTM projectors, was utilized to steer a laser beam for 3D measurements.
Tomocube, founded from seed money funded by the EndRun Project of the Institute for Startup KAIST, succeeded in the commercialization of the 3D holographic microscopy and established an international distribution network in more than ten countries. It now has started exporting the product to several countries. The microscopes are being used in several leading research institutes including MIT, German Cancer Center, Pittsburg Medical Center, and Seoul National University Hospital Selected as one of the top ten mechanical technologies of 2016 by the Korean Society of Mechanical Engineers, the team raised four billion KRW investment from industry leaders including Soft Bank Venture Korea, Hanmi Pharmaceutical, and InterVest investment.
(Figure: Images of cells measured by 3D microscopy)
□ Designer Proteins with Chemical Modifications
By Hee-Sung Park and Hee Yoon Lee of the Department of Chemistry
Professor Hee-Sung Park developed a new strategy for installing authentic post-translational modifications (PTM) into recombinant proteins. Most essential biological processes are controlled by PTM, which plays a critical role in metabolic changes. However, abnormal protein modification aroused by environmental or genetic factors induce diverse diseases such as neurodegenerative diseases, cancer, and many other chronic diseases.
Professor Park has conceived a novel chemical biology route to achieve authentic and selective chemical modifications in proteins.He first used the established O-phosphoserine (Sep) orthogonal translational system to create a Sep-containing protein. The Sep residue is then dephosphorylated to dehydroalanine (Dha). Finally, Zn-Cu is conjugated to Dha of alkyl iodides, which enables it to form chemo-selective carbon-carbon bonds.
This approach offers a powerful tool to engineer designer proteins with diverse chemical modifications, providing a novel platform for investigating numerous diseases and drug development including for cancer and Alzheimer's. Furthermore, this research will allow mass production of abnormally modified proteins that could induce diseases, opening up new prospects in disease treatment research. It will help to enable investigation and discovery of new drug inhibitors that directly target abnormally modified proteins.
(Figure: Application of Customized Protein Modification Technology)
□ Lanthanum-Catalyzed Synthesis of Microporous 3D Graphene-Like Carbons in a Zeolite Template
By Ryong Ryoo, of the Department of Chemistry
Professor Ryong Ryoo’s team presented a scaled-up carbon synthesis viable for practical applications such as Li-ion batteries and catalyst supports.
Zeolite-templated carbon has an extremely large surface area and a regular microporous structure. As a result, it was expected to show excellent performance in various applications, such as for electrode materials or catalyst supports. However, until recently difficulties in synthesis have hindered research on application and properties of zeolited-templated carbon compared to other porous carbon materials.
Professor Ryoo’s team demonstrated that lanthanum ions embedded in zeolite pores lowered the temperature for carbonization of ethylene or acetylene. In this contribution, a graphene-like carbon structure was selectively formed inside zeolite template without the non-selective carbon deposition. Single crystal X-ray diffraction data revealed that carbon formed along the micropore surface. After removal of zeolite template, the carbon framework showed high electrical conductivity.
His synthesis method not only allowed selectivity in ethylene carbonization inside zeolite pore but permitted the diffusion of carbon material even when a large amount of zeolites was synthesized at once, allowing mass production of carbon. Thus, this method is expected to accelerate research on the application and properties of zeolite-templated carbon.
(Figure: Electron density distribution of zeolite that underwent selective pore carbonization. The structure of carbon determined by electron density distributions of carbon atoms, shown in yellow and red, within the framework of zeolite, shown in blue, can be observed.)
□ Complete Prevention of Blood Loss by Self-Sealing Hemostatic Needles
By Haeshin Lee of the Department of Chemistry
Professor Haeshin Lee’s team invented a hemostatic hypodermic needle, which prevented bleeding of punctured tissue during and after injections.
Bleeding unavoidably accompanies injections when a conventional needle penetrates tissue. Though the scale of bleeding from controlled injections does not cause harm to healthy individuals, uncontrolled bleeding may bring serious complications for those who suffer from hemophilia, coagulopathy, or who have been exposed to infectious diseases.
Professor Lee’s hemostatic hypodermic needle is coated with partially cross-linked catechol-functionalized chitosan that undergoes a solid-to-gel phase transition in situ to seal-seal punctured tissues. The team reported a complete prevention of blood loss following intravenous and intramuscular injections in animal models. They observed a 100% survival rate in hemophiliac mice following a syringe injection into a jugular vein.
The self-sealing hemostatic needles may help to prevent complications associated with bleeding in clinical settings such as for diabetic patients who experience delayed hemostasis and in the procedure of biopsy thereby preventing profuse bleeding.
□ An Immunological Mechanism for the Contribution of Commensal Microbiota Against Herpes Simplex Virus Infection in Genital Mucosa
By Heung Kyu Lee of the Graduate School of Medical Science and Engineering
Professor Heung Kyu Lee identified an immunological mechanism of commensal microbiota against herpes virus infections. The protective mechanisms of commensal bacteria against viral infections was limited to how immune inductive signals are provided by commensal bacteria for enhancing innate and adaptive immunity. Until Professor Lee’s research discovery, whether, or how, commensal bacteria might influence the effector arm of immune responses such as effector T cells to eliminate infected virus remained unknown.
Professor Lee’s team demonstrated that dysbiosis within the vaginal microbiota resulted in severe impairment of antiviral protection against HSV-2 infection. IL-33 released into the vaginal tract after antibiotic treatment blocked the ability of effector T cells to migrate into vaginal tissues and secrete the antiviral cytokine, IFN-γ. Thus, the findings suggested a previously unstudied role of commensal bacteria in the effector phase of the antiviral immune response against genital herpes. These findings provided insight into the mechanisms by which the secretion of proteases from opportunistic pathogens in susceptibility to various sexually transmitted pathogens might induce type 2 immunity within the female genital tract.
Promoting awareness of overuse of antibiotics, the research is expected to contribute to the development of viral vaccines with enhanced defense capacity by regulating commensal bacteria to promote health.
□ Development of a Pulse-Echo Laser Ultrasonic Propagation Imaging System
By Jung-Ryul Lee of the Department of Aerospace Engineering
Professor Jung-Ryul Lee’s team for the first time developed a mobile laser ultrasonic propagation imaging system that is capable of 2500-point inspection per second and visualization of pulse-echo ultrasonic wave through the thickness of a solid medium. This novel ultrasonic propagation visualization system has been successfully prototyped for the application of in-situ and in-process nondestructive evaluation of aerospace structures.
The real world proof-of-concept was achieved by testing the new system in the inspection of a space launcher fuselage (KSLV-II), control surfaces of military transport (CN-235), and the brake disk of F-16, guided weapon fuselage. In addition, the system has passed F-16 standard specimen test done by Korea Air Force and got a US patent. The prototype which was developed over a period of two years has been successfully delivered to Korea Air Force last December.
Furthermore, Boeing has expressed interest in prototype development project and KAIST OESL has been selected as the Boeing-KAIST technical contact lab and received a two-year grant from Boeing. The second prototype is under construction for Boeing and the third prototype will be delivered to an optional research institute and used as a standard inspection instrument.
□ Birefractive Stereo Imaging for Single-Shot Depth Acquisition
By Min H. Kim of the School of Computing
Professor Min H. Kim’s team proposed a novel 3D imaging method that allows the capture of not only color pictures but also corresponding depth images while traditional cameras capture just color pictures.
Depending on the polarization state of light, the incident light on a birefringent material such as calcite can be refracted into two different angles. This physical phenomenon is called double refraction. Whereas traditional stereo imaging requires at least two stereo cameras, 3D imaging method can capture depth from a single picture of double refraction. This proposed 3D imaging technique can be applied to many graphics and computer vision applications such as AR/VR applications that require color and depth information simultaneously.
This technology, which could measure depth images, is currently needed for various industrial applications. The suggested method in this research to measure depth information from one photo using double refraction media accurately can be used in areas where system size and cost are important, such as mobile cameras, VR/ARs, driverless cars, and 3D microscopes.
(Figure: Measuring high-resolution depth of single image via bi-refringent medium)
□Development of Environment Friendly Geotechnical Construction Material Using Biopolymer
By Gye-Chun Cho of the Department of Civil and Environmental Engineering
Professor Gye-Chun Cho has succeeded in making a 100% bio-based KABS (KAIST Bio-Soil) binder using biopolymer, an eco-friendly geotechnical construction material. A biopolymer is an organic polymer produced in the course of microbial activities and thus is an eco-friendly material manufactured without generating carbon dioxide. Biopolymers have been used in food, agriculture, cosmetics, and medicine as hardener and gelling agents, but have never been applied in construction. His team verified the microscopic interaction, feasibility, and strengthening mechanism of microbial biopolymers for soils for the first time in the world, suggesting that biopolymers be an eco-friendly soil binder.
In addition to soil binders, biopolymers can also be applied to various fields of ground construction (e.g., ground improvement, grouting, erosion control, vegetation, anti-desertification, etc.). The team expects more biopolymer applications in construction since increasing demands for replacing cement-based or chemical ground materials have surged.
With KABS binder, the team has performed several field tests along with industrial technology transfer underway. In collaboration with the Korea Expressway Corporation and LH Corporation, Professor Cho’s team is working on additional commercial applications.
(Figure: Strength enhancement effect of soil grain processed by biopolymer )
□ Protein Delivery Via Engineered Exosomes
By Chulhee Choi of the Department of Bio and Brain Engineering
Professor Chulhee Choi’s team unveiled a new tool for intracellular delivery of target proteins, named “exosomes for protein loading via optically reversible protein-protein interactions” or “EXPLORs”.
Nanoparticle-mediated delivery of functional macromolecules is a promising method for treating a variety of human diseases. Among nanoparticles, cell-derived exosomes have recently gained attention as a new therapeutic strategy for the in vivo delivery of nucleotides and chemical drugs.
By integrating a reversible protein-protein interaction module controlled by blue light with the endogenous process of exosome biogenesis, the team successfully loaded cargo proteins into newly generated exosomes. Treatment with protein-loaded EXPLORs is shown to significantly increase intracellular levels of cargo proteins and their function in recipient cells in vitro and in vivo.
These results clearly indicate the potential of EXPLORs as a mechanism for the efficient intracellular transfer of protein-based therapeutics into recipient cells and tissues. This technology has been transferred to KAIST bio-venture Cellex Life Science, Incorporated for commercialization.
□ Hot Electron Detection under Catalytic Reactions
By Jeong Young Park of the Graduate School of EEWS
Professor Jeong Young Park’s team developed a novel catalytic nanodiode consisting of a thin metal catalyst deposited onto a semiconductor support. The team succeeded in observing in real-time hot electrons created in the course of catalytic reaction occurring at atmospheric pressure or at liquid-solid interfaces.
Use of a noble catalytic nanodiode is a new measurement system that detects hot electrons produced on catalyst surface through atmospheric pressure and liquid chemical reaction in real time that allows direct identification of the catalytic activity of catalytic reactions. In particular, the system allows macro-observation of hot-electron movements that change with the type of nano-catalyst without high-priced equipment in atmospheric pressure and liquidation, and thus is not limited to experimental conditions such as in ultrahigh vacuums.
Therefore, it could be applied in the future to analyze complex chemical reaction mechanisms of catalysts used in high temperature and various pressure conditions, and to develop high efficiency next-generation catalyst materials. This finding may lead not only to the fundamental understanding in the mechanism of the catalytic reactions but also to the development of next-generation catalysts with enhanced catalytic performance.
(Figure: Schematic diagrams of nano-catalyst hot electron element and graphene hot electron detector)
2017.02.20 View 13992 -
Professor Shin Honored Posthumously for Iridescent Microparticles
(The Late Professor Joong-Hoon Shin (left) and Professor Shin-Hyun Kim)
A research team co-led by Professor Shin-Hyun Kim from the Department of Chemical and Biomolecular Engineering and Professor Jong-Ryul Jeong from the Department of Materials Science and Engineering at Chungnam National University developed iridescent microparticles with a structural color gradient. The research team posthumously dedicated their research to a renowned professor in the field of nanophotonics, the late Professor Joong-Hoon Shin of the Graduate School of Nanoscience and Technology at KAIST. He passed away suddenly in a car accident last September.
The iridescent microparticles, which allow on-demand control over structural color, will be key components for next-generation reflection-mode displays with clear color realization even in direct sunlight.
Materials such as opals, Morpho butterfly wings, and peacock feathers all display beautiful colors without pigment, using regularly-spaced nanostructures. Regularly-spaced nanostructures render color, by selectively reflecting the light of a particular wave through light interference. As such, materials that possess periodic modulation of refractive index at subwavelength scale are referred to as photonic crystals.
In general, photonic crystals are only able to display a single color, so limitations exist when attempting to apply them to reflection-mode displays which call for multiple structural colors. The research team addressed the issue using inspiration from snowflakes stacking in the winter. When snow falls on the surface of a round-shaped structure, the thickness of the snow stacking differs depending on the orientation. Based on this observation, the research team created photonic microparticles with a structural color gradient by depositing two different materials on spherical microparticles.
When some material is deposited on the surface of a sphere, the material on the top is thickest and becomes thinner on the sides. The team alternately deposited titania and silica on the spherical microparticles to form periodic modulation of the refractive index. The thickness of the alternating photonic layers is reduced along the angle from the top, which yields a structural color gradient.
Consequently, the microparticles reflect long-wavelength red light from the top of the sphere and short-wavelength blue light from the side of the sphere. Any color of the visible spectrum can be selected in between the top and side depending on the orientation of the microparticles.
The research team used an external magnetic field as a way to control the orientation of the photonic microparticles and the structural colors. As magnetic iron layer was deposited underneath the alternating photonic layer, it was possible to freely control the orientation of the microparticles using a magnet, thereby allowing control of the color seen by the users.
KAIST doctoral candidate Seung Yeol Lee of the Department of Chemical and Biomolecular Engineering is the first author of this research, with support from the Midcareer Researcher Program of the National Research Foundation and funded by the Ministry of Science, ICT, and Future Planning (MSIP). This research was published in the online edition of Advanced Materials on February 6, 2017.
Figure1: Sets of an OM image of photonic Janus microspheres and an SEM image showing a cross-section of the photonic layers.
Figure 2: A series of schematics and OM images showing the color change depending on the orientation angle of the photonic Janus microsphere.
2017.02.17 View 9228 -
A New Approach to 3D Holographic Displays Greatly Improves the Image Quality
With the addition of holographic diffusers or frosted glasses to wavefront modulators, KAIST researchers offer a simple and practical solution to significantly enhance the performance of 3D dynamic holographic displays by 2,600 times.
The potential applications of three-dimensional (3D) digital holograms are enormous. In addition to arts and entertainment, various fields including biomedical imaging, scientific visualization, engineering design, and displays could benefit from this technology. For example, creating full-sized organs for 3D analysis by doctors could be helpful, but it remained a challenge owing to the limitation of hologram-generation techniques.
A research team led by Professor YongKeun Park of the Physics Department at KAIST has come up with a solution and developed a 3D holographic display that performs more than 2,600 times better than existing 3D holographic displays. This study is expected to improve the limited size and viewing angle of 3D images, which were a major problem of the current holographic displays. The study was published online in Nature Photonics on January 23, 2017.
3D holograms, which often appear in science fiction films, are a familiar technology to the public, but holograms in movies are created with computer graphic effects. Methods for creating true 3D holograms are still being studied in the laboratory. For example, due to the difficulty of generating real 3D images, recent virtual reality (VR) and augmented reality (AR) devices project two different two-dimensional (2D) images onto a viewer to induce optical illusions.
To create a 3D hologram that can be viewed without special equipment such as 3D glasses, the wavefront of light must be controlled using wavefront modulators such as spatial light modulators (SLMs) and deformable mirrors (DMs). A wavefront modulator is an optical manipulation device that can control the direction of light propagation.
However, the biggest limitation to using these modulators as 3D displays is the number of pixels. The large number of pixels that are packed into high-resolution displays developed in recent years are suitable for a 2D image, and the amount of information contained in those pixels cannot produce a 3D image. For this reason, a 3D image that can be made with existing wavefront modulator technology is 1 cm in size with a narrow viewing angle of 3 degrees, which is far from practicable.
As an alternative, KAIST researchers used a DM and added two successive holographic diffusers to scatter light. By scattering light in many directions, this allows for a wider viewing angle and larger image, but results in volume speckle fields, which are caused by the interference of multiple scattered light. Random volume speckle fields cannot be used to display 3D images.
To fix the problem, the researchers employed a wavefront-shaping technique to control the fields. As a result, they succeeded in producing an enhanced 3D holographic image with a viewing angle of 35 degrees in a volume of 2 cm in length, width, and height. This yielded a performance that was about 2,600 times stronger than the original image definition generated when they used a DM without a diffuser.
Professor Park said, “Scattering light has previously been believed to interfere with the recognition of objects, but we have demonstrated that current 3D displays can be improved significantly with an increased viewing angle and image size by properly controlling the scattered light.”
Hyeonseung Yu, who is the lead author of this research article and a doctoral candidate in the Department of Physics, KAIST, noted that this technology signals a good start to develop a practical model for dynamic 3D hologram displays that can be enjoyed without the need for special eyeglasses. “This approach can also be applied to AR and VR technology to enhance the image resolution and viewing angles,” added Yu.
The research paper is entitled “Ultrahigh-definition Dynamic 3D Holographic Display by Active Control of Volume Speckle Fields.”
Figure 1. Concept of Scattering Display
The size and viewing angle of 3D images can be simultaneously increased when a scattering medium (diffuser) is introduced. By controlling the wavefront impinging on the scattering medium, the desired 3D hologram is generated.
Figure 2. Experimental Setup
The optical set-up consists of a deformable mirror and the scattering medium with two successive holographic diffusers. A high-numerical-aperture imaging unit mounted on a three-axis motorized translational system is utilized for wavefront optimization and imaging.
Figure 3. 3D Images Projected
This picture shows 3D images in a volume of 2 cm × 2 cm × 2 cm with a viewing angle of 35 degrees using one of the wavefront modulators, a digital micromirror device (DMD).
Figure 4. Artist’s Rendition of the Proposed Concept
A dynamic 3D hologram of a face is displayed.
2017.02.01 View 14238 -
Humanoid Robot Research Center Opened
(Photo from left: Kyong-Hoon Kim from Korea Evaluation Institute of Industrial Technology, Vice President of Research at KAIST Hee-Yoon Lee, Director Oh, Jong-Hwan Kim at the Ministry of Trade, Industry and Energy, President Ki-Han Park at the Korea Institute for Robot Industry Advancement, and Dean of KAIST Institute Yun Chol Chung.)
KAIST opened its Humanoid Robot Research Center on January 19 at the KAIST Institute. Endorsed by the Ministry of Trade, Industry and Energy with 15 billion KRW funding over five years, the center will conduct research for advancing humanoid robot technology and fostering research fellows in the field.
Professor Jun Ho Oh at the Department of Mechanical Engineering will serve as the director of the center. Team KAIST under Professor Oh won the 2015 DARPA Robotics Challenge (DRC) with its humanoid robot DRC-HUBO, beating 23 teams from six countries.
Professor Oh said, “I believe we have already achieved technological prowess through developing the HUBO robot over the past decade. The center will continue to strive for further development of original technology crucial for humanoid robots’ key components. We want to pave the way for having enough of our own technology and needing to bring in technology from abroad. Professor Oh said he will focus on fields such as high-efficiency, high-powered electric drives and hydraulic system humanoid robot capable of executing solid manipulability with high confidence and object recognition intelligence technology. In addition, he said the center will develop module type and extended open software in an effort to disseminate robot technology.
2017.01.23 View 7827 -
Adsorbent That Can Selectively Remove Water Contaminants
Professor Cafer T. Yavuz and his team at the Graduate School of Energy, Environment, Water, and Sustainability (EEWS) have developed an adsorbent that can selectively capture soluble organic contaminants in water.
This water treatment adsorbent is a fluorine-based nanoporous polymer that can selectively remove water-soluble micromolecules. It has the added advantage of being cheap and easily synthesized, while also being renewable.
The results of this research have been published online in Nature Communication on November 10, 2016. The research paper is titled “Charge-specific Size-dependent Separation of Water-soluble Organic Molecules by Fluorinated Nanoporous Networks.” (DOI: 10.1038/ncomms13377)
Water pollution is accelerating as a result of global industrial development and warming. As new materials are produced and applied in the agricultural and industrial sectors, the types of contaminants expelled as sewage and waste water are also becoming diverse.
Chemicals such as dyes and pesticides can be especially harmful because they are made up of small and highly soluble organic particles that cannot be completely removed during the water treatment process, ultimately ending up in our drinking water.
The current conventional water treatment systems utilize processes such as activated carbon, ozonolysis, and reverse osmosis membrane. These processes, however, are designed to remove larger organic molecules with lower solubility, thus removal of very small molecules with high solubility is difficult. In addition, these micromolecules tend to be charged, therefore are less easily separated in aqueous form.
The research team aimed to remove these small molecules using a new adsorbent technology.
In order to remove aqueous organic molecular contaminants, the team needed an adsorbent that can adsorb micro-sized molecules. It also needed to introduce a chemical function that would allow it to selectively adsorb molecules, and lastly, the adsorbent needed to be structurally stable as it would be used underwater.
The team subsequently developed an adsorbent of fluorine-based porous organic polymer that met all the conditions listed above. By controlling the size of the pores, this adsorbent is able to selectively adsorb aqueous micromolecules of less than 1-2 nm in size.
In addition, in order to separate specific contaminants, there should be a chemical functionality, such as the ability to strongly interact with the target material. Fluorine, the most electronegative atom, interacts strongly with charged soluble organic molecules.
The research team incorporated fluorine into an adsorbent, enabling it to separate charged organic molecules up to 8 times faster than neutral molecules.
The adsorbent developed by Professor Yavuz’s team has wide industrial applications. It can be used in batch-adsorption tests, as well as in column separation for size- and charge-specific adsorption.
Professor Yavuz stated that “the charge-selective properties displayed by fluorine has the potential to be applied in desalination or water treatment processes using membranes."
This paper was first-authored by Dr. Jeehye Byun, and the research was funded by KAIST’s High Risk High Return Program and the Ministry of Science, ICT and Future Planning of Korea’s Mid-Career Researcher Program, as well as its Technology Development Program to Solve Climate Change.
Figure 1. Diagram conceptualizing the process of charge- and size-specific separation by the fluorine-based porous polymer adsorbent
Figure 2. Difference in absorbance before and after using a porous fluorine polymer column to separate organic molecules
Figure 3. Adsorption properties of a fluorine polymer according to the charge and size of organic molecules
2017.01.17 View 10918 -
Nobel Laureate Dr. John Michael Kosterlitz Speaks at KAIST
KAIST’s Department of Physics will invite one of three co-recipients of the Nobel Prize in Physics 2016, Professor John Michael Kosterlitz of Brown University, on January 9, 2017, to speak about the exotic states of matter, which is entitled “Topological Defects and Phase Transitions.”
Professor Kosterlitz shares the Nobel award with two other researchers, David Thouless and Duncan Haldane. He is considered one of the pioneers in the field of topological phases. In the early 1970s, along with Thouless, he demonstrated that superconductivity could occur at low temperatures and explained the mechanism behind, phase transition, that makes superconductivity disappear at higher temperatures.
Over the last decade, topological materials and their applications have been widely studied with the hope of using them in new generations of electronics and superconductors, or in future quantum computers. Details of the lecture follow below:
Distinguished Lecture Series by KAIST’s Physics Department
· Speaker: Professor John Michael Kosterlitz of the Physics Department,
Brown University
· Topic: “Topological Defects and Phase Transitions”
· Date: January 9, 2017, 4:00 PM
· Place: Lecture Hall (#1501), College of Natural Sciences (E6-2)
2017.01.06 View 8315 -
President Kang Welcomes the New Year with an Upbeat Message
KAIST held a kick-off ceremony on January 2 at the Auditorium on campus to officially welcome the beginning of 2017.
In his New Year’s speech, President Sung-Mo Kang, who is slated to complete his term in February, recalled some of the major achievements accomplished under his leadership in the past four years.
Upon his inauguration in 2013, President Kang set a goal for KAIST to become a global top 10 university and established Quantum Jump Strategies for qualitative growth through innovative education and research programs. Such initiatives have laid the foundation for KAIST to emerge as one of the world’s best “student-centered, faculty-driven, and innovative research universities.” In 2016, Thomson Reuters named KAIST the world’s sixth most innovative university.
President Kang promoted a campus culture that cherishes creativity and a challenging spirit and encouraged university members to increase their interest in entrepreneurship and social responsibility. He reorganized academic structures to offer interdisciplinary education and revamped administrative organizations to streamline university management. On a softer note, he created various channels of communication within the university community to make the campus “happier and united,” which included the establishment of the Customer Satisfaction Center, the Center for Ethics and Human Rights, and coffee meetups.
He promised that KAIST would remain committed to leading the frontier of higher education and research, nationally and globally. The university will establish the Graduate School for Interdisciplinary Medical Science, continue to provide university members with opportunities to learn entrepreneurship, extend its efforts to upgrade campus infrastructures, and strive to globalize and diversify the campus.
Finally, President Kang praised the tremendous support KAIST has received from across Korea and the globe, including the members of KAIST and its alumni, noting that there were more than 26,000 donations made to the university during his presidency.
The full text of President Kang’s New Year message follows below:
President Kang's New Year Message
Dear Members of KAIST,
It is 2017, and the year of the rooster has dawned on us. May you and your family enjoy good health and happiness in the new year, and I hope that you will all fulfill your dreams. In return for the love and trust of the nation’s citizens, KAIST will continue to do its best.
Following my inauguration in 2013, I established Quantum Jump Strategies in the first half of my term (2013 to 2014), and I also created a united KAIST during this period. In the second half (2015 to 2016), I promoted innovation through qualitative growth. KAIST has seen astonishing growth in the past four years, and this has laid the foundation to emerge as one of the world’s best Student-Centered, Faculty-Driven, and Innovative Research Universities.
Creativity and challenge are the key words serving as the driving force behind national progress. KAIST’s qualitative growth has been achieved through continuous innovation of education and research, promotion of an entrepreneurial spirit, and exercising of social responsibility.
KAIST’s education is constantly improving. It has developed a future-oriented educational platform, commensurate with its reputation as a world-class university, after several rounds of reorganization. The interdisciplinary education system at KAIST, based on a harmony of academic excellence and creativity, facilitates efficient operation of its broad undergraduate education and interdisciplinary graduate curriculum. Through a π-shaped education system, the students solidify their foundation at the undergraduate level, and go on to graduate school to gain more wisdom and knowledge through interdisciplinary education and research. Upon graduation, they are recognized as irreplaceable, talented members of society.
The newly introduced capstone design curriculum has shifted the paradigm of Korea’s engineering education, placing greater emphasis on real-world applications. With the opportunity to plan realistic projects and identify problems, the students will acquire creativity, practical skills, teamwork, and leadership.
Under Education 3.0, KAIST has implemented a student-centered education system. Students participate in self-directed learning using online contents provided before lectures, and gain knowledge and problem-solving skills through collaborative learning with team members during classes. In addition, KAIST is fulfilling its social responsibility by making its lectures available to the public through KAIST’s Massive Open Online Course (MOOC).
KAIST is among the world’s top universities in terms of research capacity. The university has been highly ranked by QS and THE for its innovative education and research, and it was recently named by Thomson Reuters as the world’s sixth most innovative university. To ensure continuous developments, KAIST must perform sustainable research for the long run. Ideas aimed at improving humanity must be continuously produced, and the university must acquire the necessary resources to support such research. KAIST should promote a research culture that assesses researchers based on their diligence and conscientiousness rather than how successful they are. The KAIST Grand Challenge 30 Project was launched for KAIST to resolve major issues faced by humanity and to spread its culture of innovation to all.
To acquire global competitiveness in the field of biological sciences, KAIST is planning to establish the Graduate School of Interdisciplinary Medical Science in Sejong. From 2018, the government will allocate a budget for the graduate school, which fared well in the preliminary feasibility study. Beginning with the Graduate School of Interdisciplinary Medical Science, KAIST will establish a system for innovative education and research in Sejong, and further strengthen its capacities.
KAIST has worked hard to instill an entrepreneurial spirit in its students. It has provided students with many opportunities to learn entrepreneurship, so as to enhance the economic and social value of its activities in education and research. Through the Institute for Startup KAIST (ISK), the university supports students in all stages of entrepreneurship, from ideation to commercialization. The Master of Entrepreneurship & Innovation at the K-School is jointly operated by several departments. Thanks to its active efforts in promoting entrepreneurship such as the opening of ISK Pangyo and the offering of the Social Entrepreneurship MBA (SEMBA), KAIST has produced the highest number of student entrepreneurs in Korea.
KAIST’s innovative pursuits in its administration have been highly regarded by organizations around the world. The tenure system, introduced for the first time in Korea, has now stabilized. Its English-only lecture policy and tuition subsidy by GPA have been improved based on feedback from students and experts.
KAIST went through a major administrative reorganization in 2013. The reorganization, introduced to integrate similar functions and simplify the decision-making process, enabled KAIST’s administration to adapt flexibly to changes, become function-oriented, assume roles more rationally, and to be more responsive to the needs of customers. With the opening of the Administration Development Education Center, KAIST has improved the quality of administrative services by providing staff in administrative positions with more opportunities for self-development and to attend lectures that improve the efficiency of administrative operations.
The university is actively reflecting the opinions of its members through various channels of communication. The school marked a first in Korea when it implemented an ombudsman to mediate between parties in case of conflict. The Customer Satisfaction Center was opened to improve the quality of services on campus, and the Center for Ethics and Human Rights to prevent the infringement of human rights. I have tried to make myself more available to all members of KAIST, so as to freely interact with them without having to arrange separate meetings. The opening of the office of the president, coffee meetups, forums with undergraduate and graduate students, and e-mail exchanges have been tremendously helpful in gaining valuable feedback and improving university operations.
KAIST is strongly supported by the citizens of Daejeon. The university has strengthened its ties with Daejeon Metropolitan City, Yuseong District Office, and Chungnam National University. Its efforts have paid off with the opening of a new path connecting Chungnam National University and KAIST, and the KAIST Bridge in front of the main gate. KAIST has encouraged students to reach out to society by serving as tutors for the socially neglected and helping out in making kimchi.
By improving its infrastructure in the past four years, KAIST has now established high-quality infrastructure to support its education and research. The Chung Moon Soul Building 2 is now complete, the Academic Cultural Creative Building is underway, and the Main Library is being upgraded. New constructions or remodeling on campus include the opening of Startup KAIST Studio 2, opening of the Biomedical Research Center (Pharmacy), remodeling of International Village C, remodeling of the Semiconductor Building, remodeling of the Auditorium, remodeling of the Mechanical Engineering Building, remodeling of the Startup Village, remodeling of Haejeong Hall and Buildings No. 8 and 9, remodeling of the Outdoor Theater, remodeling of Hwaam Dormitory (tentative), establishment of an eco campus (planting of pine trees), establishment of a safe campus (improvements to roads and pedestrian roads). Besides expanding its infrastructure, KAIST has exerted efforts to make efficient use of existing space by relocating IBS and the Graduate School for Green Growth to Munji Campus.
KAIST strives to create a more accommodating atmosphere for international members and to embrace diversity. It has reached its goal of having international faculty, international students, and female faculty account for 10% each of the total school population. Now, it is time to improve this 10:10:10 initiative to a 20:20:20 initiative. In addition, it must continue to improve the common kitchen at Nanum Hall, communicate with international members through regular podcasts, open a Halal Food Cafeteria, establish a bilingual campus, offer joint degrees with outstanding universities, expand overseas internship opportunities, enhance gender equality, and improve the women’s lounge and childcare facilities.
In the near future, I believe that KAIST will be a center of attention both at home and abroad. It has attracted an increasing number of undergraduate applicants in the past four years, and admits highly qualified freshmen each year. Students of all levels, including freshmen, have shown great pride in studying at KAIST. Recently, the university has received a high number of donations from students, alumni, and parents. There were more than 26,000 donations in the past four years, amounting to a total of 70.8 billion won. KAIST is also serving as a benchmark institute for similar organizations in and outside of Korea. Some authorities have even requested KAIST to open branch campuses in their countries. These results would not have been possible without your efforts to create a happy campus.
Dear Members of KAIST,
This New Year’s greetings will be my last as the president of KAIST. The Board of Trustees is selecting a new president, whose inauguration shall fall on February 23, 2017. I will look back fondly on my past four years at KAIST.
During the remainder of my term as the president, I will concentrate my efforts to create a happy campus for each and every member. It was a great pleasure and honor to serve as President for the past four years. I am sincerely grateful to all members for playing their part in nurturing KAIST into the world’s best university and in creating a happy campus.
You are the future of KAIST, and the driving force behind Korea. I believe you have what it takes to lead developments in the country, and I encourage you to dream bigger.
May 2017 be a year in which all members of KAIST fulfill their dreams. Let us work towards our goal of becoming the hub of the fourth industrial revolution and one of the world’s best Student-Centered, Faculty-Driven Research Universities.
2017.01.03 View 8542 -
Center for Overseas Development Hosts Dominican Republic Officials
The Center for Overseas Development at KAIST invited a group of government and higher education officials from the Dominican Republic and offered them an opportunity to learn about KAIST and other public institutions in Korea.
The Dominican delegation, consisting of 20 high-ranking officials from the Ministry of Higher Education, Science and Technology (MESCYT), the Autonomous University of Santo Domingo (UASD), the Pontifical Catholic University (PUCMM), and Santiago University of Technology (UTESA), stayed in Korea for about two weeks, December 4-17, 2016 and visited KAIST, the Korea International Cooperation Agency (KOICA), universities, research centers, and companies. They also participated in meetings, workshops, and lectures to deepen their understanding of Korea.
The purpose of the Dominican delegation’s visit was to learn about Korea’s knowledge and experiences acquired over the years from establishing and operating what many view now as some of the leading universities, research organizations, and industries in the world.
lácido F. Gomez Ramirez, Deputy Minister of MESCYT, said that their visit would be a good reference when formulating action plans for the growth of science and technology in the Dominican Republic.
He added, “We were able to see how Korea has transformed itself into a high-tech nation. We will share Korea’s success stories with our people in the Dominican Republic, for example, referring to them when creating a system to facilitate cooperation among the government, higher education, and industry. I hope our second visit, slated for some time next year, will allow us to discuss cooperation between the two countries in more concrete terms including opening branch offices of Korean companies in our country.”
Sung-Hyon Myaeng, Director of KAIST’s Center for Overseas Development, said, “We will continue our support to coordinate more visits by the Dominican Republic and expand cooperation, particularly, in higher education.”
The visit was arranged with support from KOICA to offer Dominican senior professionals from higher education and government offices a chance to increase their competency, to promote research activities in science and technology, and to accelerate industry and university collaboration.
2016.12.22 View 6337 -
Professor Suck-Joo Na Receives the 2016 Humboldt Research Award
The Alexander von Humboldt Foundation, established by the German government in 1953, promotes academic cooperation and exchange among scientists and scholars from Germany and abroad. The foundation has bestowed this year's award to Professor Suck-Joo Na of KAIST's Mechanical Engineering Department in recognition of his lifetime achievements.
Professor Na's main interests are in the fields of arc and laser welding, computational fluid dynamics simulation, residual stress and distortion, and design of welded structures. He has received numerous honors and awards including the Research Fellowship Award from the Alexander von Humboldt Foundation (1989), the Excellent Research Paper Award from the Korean Welding and Joining Society (1993), the Charles H. Jennings Memorial Award from the American Welding Society (2003), and the Yoshiaki Arata Award from the International Institute of Welding (2014).
The Humboldt Research Award is granted annually to up to 100 academics whose fundamental discoveries, new theories, or insights have had a significant impact on their own discipline and who are expected to continue producing cutting-edge achievements in the future.
The award winners also receive a research grant of 60,000 Euros and are invited to work up to one year with colleagues at research institutions in Germany. Nominations for the award are made only by established academic institutions in Germany.
Professor Na will collaborate with a research team led by Professor Michael Rethmeier at the Berlin-based Federal Institute for Materials Research and Testing (BAM) to conduct research in laser welding and selective laser melting, as well as the mathematical analysis of these manufacturing processes from July 2017 to the end of February 2018.
2016.12.19 View 8233 -
A KAIST Team Wins the Chem-E-Car Competition 2016
A KAIST team consisted of four students from the Department of Chemical and Biomolecular Engineering won the Chem-E-Car Competition 2016, which took place on November 13 at the Union Square in San Francisco. The students who participated were Young-Hyun Cha, Jin-Sol Shin, Dae-Seok Oh, and Wan-Tae Kim. Their adviser was Professor Doh Chang Lee of the same department.
Established in 1999, the Chem-E-Car is an annual worldwide college competition for students majoring in chemical engineering. The American Institute of Chemical Engineers (AIChE), founded in 1908, is the world’s leading organization for chemical engineering professionals with more than 50,000 members from over 100 countries and hosts this competition every year.
A total of 41 university teams including Carnegie Mellon University and Purdue University participated in this year’s competition.
KAIST students competed in the event for the first time in 2014 and reached the rank of 28. In 2015, the students placed 16th, and finally, took the first place in last month’s competition, followed by the Georgia Institute of Technology.
In the competition, students must design small-scale (20x30x40 cm) automobiles that operate chemically, as well as describe their research and drive their car a fixed distance down a wedge-shaped course to demonstrate the car’s capabilities. In addition to driving a specified distance (15-30 meters), the car must hold a payload of 0-500 mL of water.
The organizers tell participants the exact distance and amount of payloads one hour before the competition begins. Winners are chosen based on their finishing time and how close their car reaches the finish line. Thus, students must show sophisticated coordination of chemical reactions to win.
The KAIST team designed their car to have a stable power output using a Vanadium redox flow battery developed by Professor Hee Tak Kim of Chemical and Biomolecular Engineering. They employed iodine clock reactions to induce quick and precise chemical reactions to control their car.
KAIST’s car finished with the best run coming within 11 cm of the target line; Georgia Tech’s car reached the finish line by 13 cm and New Jersey Institute of Technology’s car by 14 cm.
Young-Hyun Cha, one of the four students, said, “When we first designed our car, we had to deal with many issues such as stalls or connection errors. We kept working on fixing these problems through trial and error, which eventually led us to success.”
For a news article on KAIST’s win at 2016 Chemi-E-Car Competition by AIChE, see the link below:
http://www.aiche.org/chenected/2016/11/koreas-kaist-wins-1st-place-2016-chem-e-car-competition-photos
2016.12.08 View 11739 -
Professor Young Jae Jang Receives the Grant Award from Mathworks
Professor Young Jae Jang of KAIST’s Industrial and Systems Engineering Department won the Grant Award from Mathworks, Inc., an American developer of mathematical computing software. Headquartered in Massachusetts in the United States, Mathworks has been known for its MATLAB software that is used by many engineers and scientists around the world for algorithm development, data analysis, visualization, and numeric computation.
Winners of the Grant Award are selected from proposals submitted by educational institutions in 18 different countries based on their innovative lab curricula and future potential for innovation and creativity.
Award winners receive a cash grant of up to USD 40,000 as well as various other forms of support including software and technical guidance for creating a course.
Professor Jang has researched combining the concept of industrial engineering education with Lego principles since 2014. He developed Lego-based experimental equipment and utilized it to teach students about difficult ideas, for example, big data and manufacturing technologies needed for Industry 4.0, such as automation, cyber-physical systems, the Internet of Things, and cloud computing. He created an innovative teaching environment where students learn engineering concepts and then conduct experiments on their own to understand the new paradigm of industrial systems.
Lego-based education allows students to personalize their learning process, shifting lecture-centered approaches toward learner-oriented approaches. Students apply theories to operate tools and equipment made with Lego, identify problems, and find solutions. In such processes, they can understand the content of their study more easily and efficiently and become more motivated.
Professor Jang’s research has attracted a great deal of interest overseas, and he is frequently invited to international conferences as a keynote speaker.
Picture: Lego-based Learning Model of Experiment Equipment Developed by Professor Young Jae Jang
2016.12.08 View 6933 -
KAIST's Doctoral Student Receives a Hoffman Scholarship Award
Hyo-Sun Lee, a doctoral student at the Graduate School of EEWS (Environment, Energy, Water and Sustainability), KAIST, is a recipient of the 2016 Dorothy M. and Earl S. Hoffman Scholarships presented by the American Vacuum Society (AVS). The award ceremony took place during the Society’s 63rd International Symposium and Exhibition on November 6-11, 2016 in Nashville, Tennessee.
Lee is the first Korean and foreign student to receive this scholarship.
The Hoffman Scholarships were established in 2002 to recognize and encourage excellence in graduate studies in the sciences and technologies of interest to AVS. The scholarships are funded by a bequest from Dorothy M. Hoffman, who was a pioneering member of the Society of Women Engineers and served as the president of AVS in 1974.
Lee received the scholarship for her research that detects hot electrons from chemical reactions on catalytic surface using nanodevices. Nano Letters, an academic journal published by the American Chemical Society, described her work in its February 2016 issue as a technology that allows quantitative analysis of hot electrons by employing a new nanodevice and therefore helps researchers understand better the mechanism of chemical reactions on nanocatalytic surface. She also published her work to detect the flow of hot electrons that occur on metal nanocatalytic surface during hydrogen oxidation reactions in Angewandte Chemie.
Lee said, “I am pleased to receive this honor from such a world-renowned academic society. Certainly, this will be a great support for my future study and research.”
Founded in 1953, AVS is an interdisciplinary, professional society composed of approximately 4,500 members worldwide. It supports networking among academic, industrial, government, and consulting professionals involved in a range of established and emerging science and technology areas such as chemistry, physics, engineering, business, and technology development.
2016.11.17 View 10784