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KAIST Alumni of the Year
(From left Chul-Hwan Kim, president and CEO of Orange Power, Hooshik Kim, president & CEO of Vieworks, Chilhee Chung, presient of Samsung Advanced Institute of Technology, KAIST President Sung-Mo Kang, KAIST Alumni Association President Jung-Sik Ko, Won-Pil Baek, senior vice president for R&D program at Korea Atomic Energy Research Insitute, Hyonho Jung, CEO of Medytox, Jaehwa Kim on behalf of Han-Oh Park, president & CEO of Bioneer Corporation) The KAIST Alumni Association presented the Alumni of the Year award to six of its most accomplished alumni at the New Year dinner held at the Lotte Hotel in Seoul on January 14. KAIST alumni community, which numbers over 500,000, has made a significant impact around the globe in science and technology, industry, education, and the public sector. Each year, the KAIST Alumni Association honors individuals who have made a significant contribution with outstanding leadership through the Alumni of the Year awards. KAIST Alumni Association President Jung-Sik Ko awarded the recipients at the dinner. About 200 alumni, faculty, and students, including KAIST President Sung-Mo Kang, joined the celebration. The 2016 awardees are Dr. Chilhee Chung, president of Samsung Advanced Institute of Technology(SAIT); Dr.Won-Pil Baek, senior vice president for R&D program at Korea Atomic Energy Research Institute(KAERI); Dr.Han-Oh Park, president & CEO of Bioneer Corporation; Dr.Hyonho Jung, CEO of Medytox; Hooshik Kim, president & CEO of Vieworks; and Dr.Chul-Hwan Kim, president & CEO of Orange Power. Dr. Chung of SAIT (MS in physics ’79) played a leading role in developing top-notch system semiconductors and memory device technology while serving as president of the Samsung Electronic Semiconductor R&D Center. He has focused on the development of cutting-edge future technology, the Quantum Dot, by incorporating eco-friendly materials with the highest efficiency and color purity which is cadmium-free. Working at KAERI since 2001, Dr. Baek (Ph.D. in nuclear and quantum engineering ’87) has made contributions to help Korea emerge as a nuclear technology powerhouse. He played a critical role in developing and facilitating a global nuclear safety verification facility dubbed ‘ATLAS.’ Such nuclear technological prowess led the Korean government to advance into the foreign markets, such as exporting nuclear power plants to United Arab Emirates. The CEO of Bioneer, Dr. Park (Ph.D. in chemistry ’87) started a bio-venture in Korea. His company has developed hundreds of reagents, diagnostic kits, and advanced equipment for gene research over two decades. Bioneer has paved the way for establishing a world-class level of infrastructure in genomic technology. By developing the innovative technology "SAMiRNA ™ (Self-Assembled-Micelle-inhibitory-RNA)" that overcomes the problems in drug development, Bioneer presented a new solution for the treatment of incurable diseases. In collaboration with global pharmaceutical companies and research groups, Dr. Park has successfully led joint development in the licensing of new therapeutic medicine candidates for various incurable diseases. Dr. Jung (Ph.D. in biological sciences ’88) founded the bio-pharmaceutical company Medytox in 2000. Medytox is the first company in Korea that commercialized botulinum toxin formulation. Medytox developed the non-animal liquid botulinum toxin formulation for the first time in the world. It successfully localized botulinum preparation that can treat various neurological diseases. Medytox’s new toxin formulation resulted in improving public health care as well as relieving the heavy dependence on importing bio-pharmaceutical products. As the CEO of Vieworks, Kim (MS in physics ’95) succeeded in commercializing of digital X-ray. Especially, it is leading the design of optical and image systems that affect the quality of digital X-ray image. Kim’s company established related technology base, contributing to human health promotion and national industrial development. President Kim of Orange Power (Ph.D. in chemical and biomolecular engineering ’93) is also the founder of the KITE Entrepreneurship Foundation. He launched Biogenix Co., Ltd. and Image and Materials Co. in 2005. In order to nurture an entrepreneurship and start-ups eco-system, he invested 10 billion KRW from the proceeds of the sale of one of his start-ups. In addition, he started Orange Power Co., Ltd. in 2012 to solve the secondary battery heat problem and established a global partnership with Hydro Quebec in Canada, Nexion in UK, Volkswagen of Germany, and Tesla of the US.
2017.01.16
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KAISTian of the Year 2016: Professor Hee-Sung Park
Professor Hee-Sung Park of the Department of Chemistry has been named the KAISTian of 2016. President Sung-Mo Kang awarded him at the New Year ceremony on January 2, 2017. The KAISTian of the Year recognizes the most outstanding professor whose research and scholarship made significant achievements for the year. The Selection Committee announced that Professor Park was chosen as the 16th awardee in recognition of his developing new methods to incorporate unnatural amino acids into proteins. Earning his Ph.D. in chemical engineering at KAIST in 2000, Professor Park has been a professor at KAIST since 2009. His research focuses on the production of synthetic proteins and the generation of diverse protein functions as well as the designing and engineering of new translation machinery for genetic code expansion, and the application of synthetic biology techniques for basic cell biology and applied medical science. He developed a tool to engineer designer proteins via diverse chemical modifications, providing a novel platform for investigating numerous diseases such as cancer and dementia. Post-translational modifications (PTMs) are constantly taking place during or after protein biosynthesis. PTMs play a vital role in expanding protein functional diversity and, as a result, critically affect numerous biological processes. Abnormal PTMs have been known to trigger various diseases including cancer and dementia. Therefore, this technology, that enables proteins to reproduce with specific modifications at selected residues, will significantly help establish experimental strategies to investigate fundamental biological mechanisms including the development of targeted cancer therapies. Professor Park’s research results appeared in the September 28, 2016 edition of Science. For more on Professor Park's research, please visit: http://kaistcompass.kaist.ac.kr/?issues=fall-2016&magazine=a-chemical-biology-route-to-site-specific-authentic-protein-modifications http://science.sciencemag.org/content/early/2016/09/28/science.aah4428 http://www.kaist.ac.kr/html/en/news/podcast.html (Podcast: Season 6 Episode 7: When good proteins go bad )
2017.01.10
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Science, IT & Culture Volunteering Team at Cambodia
The Science, IT and Culture Volunteering Team, which is composed of 17 undergraduates, is visiting Cambodia January 1 to 16. Based at Hosanna High School in Phnom Penh, the KAIST volunteering team will participate in diverse science and IT classes as well as cultural events for Cambodian high school students. The KAIST volunteering service is designed to improve Cambodian students’ science education including the areas of physics, chemistry, biology, earth science, as well as an increased exposure to IT technologies. For this service, the volunteering team has prepared for three months, making syllabi for the science classes in addition to planning Arduino IT classes and cultural performances, including K-pop dances and Korean traditional games. The team will present various science experiments including smart electric fan and mini vehicles using Arduino. Before departing, the students made great efforts to ensure this service would be a success by taking a basic Khmer language class and studying safety education. Se-Woong Oh, the head of the team said, "All our members are very excited to have the chance to share our knowledge with Cambodian students and help them learn science and IT technology. We hope this service will serve as an opportunity to understand a different culture as well. We made every effort to prepare for an activity we believe in." (KAIST volunteer team with Hosanna High School students in Phnom Penh, Cambodia.)
2017.01.10
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Controlling DNA Orientation Using a Brush
Professor Dong Ki Yoon’s research team in the Graduate School of Nanoscience and Technology has developed a technique for producing periodic DNA zigzag structures using a common make-up brush. The results of the research, first-authored by Ph.D. student Yun Jeong Cha and published in Advanced Materials (online, November 15, 2016), has been highlighted in the hot topics of “Liquid Crystals.” There exist various methods for synthesizing DNA-based nanostructures, but they commonly involved complex design processes and required expensive DNA samples with regulated base sequences. Using DNA materials extracted from salmon, the research team was able to produce a nanostructure with a well-aligned zigzag pattern at one-thousandth of the usual cost. The team used a commercial make-up brush bought at a cosmetics store, and with it, applied the salmon DNA in one direction onto a plate, in the same way paint is brushed onto paper. Using a brush with a width of several centimeters, the team aligned DNA molecules of 2 nanometers in diameter along the direction of the brush strokes. As the thin and dense film of DNA came into contact with air, it lost moisture. An expansive force was created between the dried film and the plate. This force interacted with the elastic force of DNA and caused undulations in the uni-directionally aligned DNA molecules, which resulted in a regular zigzag pattern. The zigzag DNA’s base sequences could not be controlled because it was extracted from biological sources. However, it has the advantage of being cheap and readily available without compromising its structural integrity and provides a very regular and intricate structure. This kind of well-ordered DNA structure can be used as template because it can guide or control versatile guest functional materials that are applied to its surface. For example, it can align liquid crystals used in displays, as well as metallic particles and semi-conductors. It is expected that this capacity can be extended to optoelectric devices in the future. Professor Yoon remarked that “these findings have special implications, as they have demonstrated that various materials in nature aside from DNA, such as proteins, muscle cells, and components of bones can be applied to optoelectric devices.” This research has been carried out with the support of the Korea National Research Foundation’s Nanomaterials Fundamental Technology Development Program and the Pioneer Research Center under the High-tech Convergence Technology Development Program. Source: "Control of Periodic Zigzag Structures of DNA by a Simple Shearing Method" by Yun Jeong Cha and Dong Ki Yoon (Advanced Materials, November 15, 2016, DOI: 10.1002/adma.201604247) Figure 1. Diagram showing the well-ordered zigzag structure of DNA, and the internal molecular orientation Figure 2. (Left) Unaligned DNA (Right) Aligned DNA after being brushed and dried Figure 3. Control of the periodicity of the DNA zigzag patterns using micro-channel plates Figure 4. Diagram representing the control of orientation of liquid crystal materials applied on a zigzag DNA template, and a polarized optical microscope image
2017.01.10
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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
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KAIST Undergraduates Win the Innovative Design Contest 2016
A team of KAIST students, consisting of five undergraduates (Do-Hoon Kwon, Tae-Hyun Kim, Hak-Gi Do, Hyun-Joo Lee, and Jong-Ho Jeong) from the Department of Mechanical Engineering, won the grand prize at the Innovative Design Contest held at Osaka University in Japan on December 12-13, 2016. The event took place during the 16th Asia Design Engineering Workshop (A-DEWS). For this year’s contest, a total of ten student teams from such countries as Korea, Japan, Taiwan, and Malaysia participated, and Team KAIST earned the highest scores. The five KAIST students, all taking the course entitled “Production of Creative Systems,” developed a manual wheelchair accessory called “Safe Attachable Wheelchair Assistive Device in Capstone Design (SAWADiCap). SAWADiCap is a detachable auxiliary power device that increases the range and mobility of manual wheelchairs. The device can easily be installed and removed, compared to existing add-on attachments for wheelchairs. Users can also enjoy similar advantages offered by powered wheelchairs at a lower cost. In their presentation on the device, the KAIST students introduced their design to improve the power of manual wheelchairs employing the magnetic reinforcement effect and to include the safety features necessary for users to install or operate the device. Do-Hoon Kwon said, “Our team had a great experience participating in the contest—we met people with diverse backgrounds and expanded our understanding in the field.” Professor Seibum B. Choi of the Mechanical Engineering Department, who advises the KAIST team, added, “I hope our technology can help the spread of affordable wheelchairs and increase mobility for the disabled.” Established in 2000, A-DEWS is held annually by the Asian branch of the Design Engineering Workshop to provide an international forum for researchers and practitioners in the field of design engineering by facilitating the exchange of recent research results and sharing knowledge about design strategies and methods. This year’s theme for the workshop was “Innovation of Life.” A-DEWS hosts the Innovative Design Contest to encourage young engineers, researchers, and students who are creating innovative products, services, and product-services and to show appreciation for their efforts. Pictured below from left to right are Hyun-Joo Lee, Do-Hoon Kwon, Jong-Ho Jeong, and Hak-Gi Do.
2017.01.03
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KAIST Ph.D. Candidate Wins the Next Generation of Engineers Award
Joo-Sung Kim, a doctoral student at the EEWS (Environment, Energy, Water and Sustainability) Graduate School won the inaugural Next Generation of Engineers Award in Leadership on December 14, 2016. The National Academy of Engineering of Korea hosts this award to support creative and ambitious students who have the potential to become leaders in engineering and who will serve as role models for future Korean engineers. Based on the recommendations of university professors in engineering and members of the academy, seven students are selected for the award in the categories of leadership and entrepreneurship. With his research focus on the development of high-performance, next-generation secondary cells for wearable devices such as smart watches, health bands, and smart eyewear, Joo-Sung created a startup, Lithium-ion Battery Energy Science and Technology (LiBEST), Inc. He plans to base his company at the Office of University and Industry Cooperation, KAIST, where he can receive assistance for launching the mass-production system for his technology. His adviser, Professor Jang-Wook Choi of the EEWS Graduate School, noted, “Joo-Sung has been a great student who has a strong sense of curiosity and perseverance. The award is the by-product of his hard work.” “I have always enjoyed my work and study as a researcher, but eventually would like to expand my career into business based on the results of my research. It would be wonderful if I could become a businessman like Elon Musk, Masayoshi Son, or Ma Yun and create a role model for aspiring engineers in Korea by combining science and technology with business demand to create social values that benefit many people,” Joo-Young said.
2016.12.26
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EEWS Graduate School Team Receives the S-Oil Best Paper Award
Professor Hyungjun Kim and Dr. He-Young Shin from the EEWS (Energy, Environment, Water and Sustainability) Graduate School at KAIST received the Best Paper Award in Chemistry from S-Oil, a Korean petroleum and refinery company, on November 29, 2016. Established in 2011, the S-Oil Best Paper Awards are bestowed annually upon ten young scientists in the fields of five basic sciences: mathematics, physics, chemistry, biology, and earth science. The scientists are selected at the recommendation of the Korean Academy of Science and Technology and the Association of Korean Universities. The awards grant a total of USD 230,000 for research funding. Dr. Shin, the lead author of the awarded research paper, said, “My research interest has been catalyst studies based on theoretical chemistry. I am pleased to accept this award that will support my studies, and will continue to research catalyst design that can predict parameters and integrate them into catalytic systems.” Professor Hyungjun Kim (left) and Dr. He-Young Shin (right)
2016.12.23
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The Antibody That Normalizes Tumor Vessels
Researchers also discover that their antisepsis antibody reduces glioma, lung and breast cancer progression in mice. A research team at the Center for Vascular Research within the Institute for Basic Science (IBS) discovered that the antisepsis antibody ABTAA (Ang2-Binding and Tie2-Activating Antibody) reduces tumor volume and improves the delivery of anti-cancer drugs. Published in Cancer Cell, this study demonstrates that ABTAA restores the structural and functional integrity of tumor blood vessels in three different tumor models: breast, lungs, and brain. Blood vessels inside and around an established tumor can be described as a chaotic and dysfunctional labyrinth. While the inner walls of healthy blood vessels are surrounded and supported by endothelial cells and other cells called pericytes, in the established tumor, the endothelial junctions are broken apart and pericytes are also detached. Blood flow into and from the tumor is severely retarded and tumor vessels lacking an intact vessel wall become leaky. This microenvironment causes limited drug delivery to the tumor and leads to inadequate oxygen supply (hypoxia) and even metastasis. The research team led by Professor Gou-Young Koh at KAIST’s Graduate School of Medical Science and Engineering found that the antibody ABTAA normalizes the tumor vessels and hence, change the whole tumor microenvironment. “We call it normalization of tumor vessels, because it resembles closely the wall architecture of healthy, normal vessels,” explains PARK Jin-Sung, first author of the study. And continues: “Tumor can adapt to hypoxia and get more aggressive, so we tried to prevent this transition by normalizing tumor vessels. ABTAA changes the whole tumor environment, oxygenation status and level of lactate, so that the immune cells and drugs can reach the core regions of the tumor more easily. In this way, we create a favorable ground for tumor treatment.” In an attempt to generate antibodies targeting the protein Ang2, which is specifically expressed by endothelial cells in stressful conditions like in tumor, the team unexpectedly discovered that ABTAA has a peculiar way of working and a dual function. ABTAA indeed not only blocks Ang2, but also activates Tie2 at the same time. Tie2 is a receptor present on the cell membrane of endothelial cells. ABTAA causes Ang2 to cluster together and to strongly activate Tie2 receptors. “If we activate Tie2, we can efficiently normalize tumor vessels, enhance drug delivery and change the whole microenvironment,” explains KOH Gou Young, Director of the Center for Vascular Research. Several pharmaceutical companies are developing Ang2-blocking antibodies to cure cancer. However, even if these antibodies significantly inhibit tumor progression, they do not stop tumor hypoxia. Moreover, most of the anti-cancer drugs target the tumor at its early stage, when tumors are still hard to diagnose. ABTAA, instead, works with tumors that are already rooted: “When the tumor is established, hypoxia is the main driver of tumor progression. So, if we eliminate hypoxia, we make the tumor milder, by reducing its progression and metastasis,” comments Koh. Figure: Schematic drawing of a blood vessel around tumors before and after treatment with ABTAA. The picture above shows a typical tumor vasculature characterized by damaged walls, red blood cells leakage and detached pericytes. Activating Tie2 on endothelial cells with the antibody ABTAA restores the normal vessel architecture: endothelial and pericytes on the vessel walls are stabilized, the delivery of blood is improved, and the anticancer drugs are more likely to reach the tumor core. The researchers tested ABTAA in mice with three different types of tumors that show high levels of Ang2: glioma (a type of a brain tumor), lung carcinoma, and breast cancer. They also compared the effect of ABTAA with ABA, another antibody that blocks Ang2 but misses the Tie2 activating properties. In all three cases, ABTAA was superior to ABA in inducing tumor vessel normalization, which led to a better delivery of the anti-cancer drugs into the tumor core region. Glioma is one of the so-called intractable diseases, because of its poor prognosis and treatment. Professor Koh’s team found that the glioma volume was reduced 39% by ABTAA and 17% by ABA. ABTAA profoundly reduced vascular leakage and edema formation in glioma through promoting vascular tightening. Moreover, when ABTAA was administered together with the chemotherapeutic drug temozolomide (TMZ), the tumor volume reduces further (76% by ABTAA+TMZ, 51% by ABA+TMZ, and 36% by TMZ). In the Lewis Lung Carcinoma (LLC) tumor model, the team administered ABTAA together with a chemotherapeutic drug called cisplatin (Cpt) and observed a greater suppression of tumor growth (52%) compared with the controls and increased overall survival. Moreover, ABTAA+Cpt led to a marked increase in necrotic area within tumors. Finally, in a spontaneous breast cancer model, ABTAA delayed tumor growth and enhanced the anti-tumor effect of Cpt. Courtesy of the Institute for Basic Sciences (IBS) Figure: The antibody ABTAA alone and in combination with other anti-cancer drugs have a beneficial effect in reducing tumor volume. ABTAA was tested in mice with brain tumor (glioma), lung or breast cancer. The image shows the improvements: reduction in glioma tumor size, reduction in metastatic colonies in lung tumor and decrease in necrotic regions in breast tumor. In the future, the team would like to further understand the underlying relationship between faulty blood vessels and diseases. “We would like to apply this antibody to an organ that is rich in blood vessels, that is the eye, and see if this antibody can be useful to treat eye diseases such as age-related macular degeneration and diabetic retinopathy,” concludes Koh. Professor Gou-Young Koh (left) and Jin-Sung Park (right)
2016.12.16
View 7555
Professor Ih Reappointed as Vice President of the ICA
Professor Jeong-Guon Ih of the Mechanical Engineering Department at KAIST has been re-elected as the Vice President of the International Commission for Acoustics (ICA). His second term of office is from October 16, 2016 to September 30, 2019. Professor Ih, the first Korean who was selected to a senior position on the ICA management board, took over his current post in 2015 when the vice president at the time passed away in the middle of his term. During his stint, Professor Ih played a key role in planning the ICA’s triennial gathering, the International Congress on Acoustics, in Gyeongju, Korea, scheduled for October 24-28, 2022. He will also serve as the general chair for the conference. The International Congress on Acoustics is the largest professional meeting in the field of acoustics. It provides a venue to meet, discuss, and exchange ideas covering all aspects of acoustics including an extensive technical exhibition that highlights the latest advances in acoustical products such as materials, systems, and equipment. Acoustics has grown to become an important element in the Information Age in the areas of automation, machine learning, and virtual reality. Hosting the Congress will support Korea’s goal to lead acoustic research and development on the global stage. Professor Ih said, “Serving international academic organizations offers great opportunities to learn global trends and to collaborate with various research institutions, universities, and industries worldwide. I hope my service will inspire many young Korean researchers to pursue their careers in this field.” Professor Ih is also a member of eight eminent international academic societies such as the Audio Engineering Society, the International Congress on Ultrasonics, and the International Institute of Noise Control Engineering. The ICA was founded in 1951 as a subcommittee of the International Union of Pure and Applied Physics (IUPAP), and it consists of 46 member states and four observer nations. It promotes international development and collaboration in all fields of acoustics including research, development, education, and standardization.
2016.12.16
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Professor Hyun Chung Claims the Elmer L. Hann Award 2016
Professor Hyun Chung of KAIST’s Mechanical Engineering Department received the Elmer L. Hann Award 2016 at the SNAME Maritime Convention (SMC) that took place November 1-5 in Seattle, Washington, in the United States. Held annually, the SMC is the largest academic gathering for researchers and professionals in maritime and ocean engineering, and it is hosted by the Society of Naval Architects and Marine Engineers (SNAME). With more than 6,000 members around the world in 85 countries, SNAME is an internationally-recognized, non-profit, professional society of individual members serving the maritime and offshore industries and their suppliers. It strives to advance the art, science, and practice of naval architecture, marine engineering, ocean engineering, and other marine-related professions through the exchange of knowledge and ideas, as well as the promotion of R&D, and education. Every year, SNAME selects three research papers that are either published in its academic journal or presented at its sponsored conferences and awards them, respectively. One of the three awards is the Elmer L. Hann Award. This year, the Society announced Professor Chung’s paper as the Elmer L. Hann Award winner. His paper, entitled “Tolerance Analysis and Diagnosis Model of Compliant Block Assembly Considering Welding Deformation,” was presented at the World Maritime Technology Conference held November 3-7, 2015 in Providence, Rhode Island, USA. Analysis, management, and diagnostics of tolerance are important factors in the production of ocean structures. In the paper, Professor Chung’s team proposed a simplified tolerance analysis and diagnosis model including the effects of welding distortion for accuracy control in ship block assembly, thereby improving the production process. Professor Chung said, “This is indeed a wonderful award for our team. From early this year, with support from the U.S. Office of Naval Research, we have collaborated with the University of Michigan, the Massachusetts Institute of Technology, Ohio State University, and the Edison Welding Institute to study this topic more deeply. We will keep up the good work to make meaningful progress.”
2016.12.10
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Mechanical Engineering Building on Campus Refurbished
KAIST’s Mechanical Engineering Department has finished the project to remodel its buildings and hosted an opening ceremony on December 12, 2016, which was attended by the university’s senior management and guests including President Steve Kang and Choong-Hwan Ahn, Architecture Policy Officer at the Ministry of Land, Infrastructure and Transport of Korea (MLIT). With an investment of approximately USD 10 million, the old buildings (each consisting of seven floors and one basement) were transformed into smart, green buildings. Among the upgrades were the establishment of LED lighting systems, the replacement of the exterior walls with insulated materials, and the installation of double-glazed windows, all resulting in the improvement of the buildings’ energy efficiency. Previously, offices and lecture halls in the buildings had individual cooling and heating systems, which consumed a great deal of energy, but they were replaced with a centralized smart energy control system that monitors the operation status as well as energy consumption in real time. With these new improvements, the Department was able to slash its energy consumption by 32%, for which it received Green Building Conversion Certification from MLIT. The ministry issues the certification to buildings that reduce their energy consumption by over 20% as a result of infrastructure upgrades. Beginning with the Mechanical Engineering buildings, KAIST will work on obtaining this certification for all of its buildings that are either under renovation or construction. President Kang said, “We are pleased to offer our students a comfortable environment for study and research and will continue improving outdated facilities and infrastructure to make the campus safer and nicer.” Picture 1: Ribbon-cutting ceremony for the refurbished Mechanical Engineering buildings on campus Picture 2: Mechanical engineering buildings
2016.12.09
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