Daejeon
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Production of chemicals without petroleum
Systems metabolic engineering of microorganisms allows efficient production of natural and non-natural chemicals from renewable non-food biomass
In our everyday life, we use gasoline, diesel, plastics, rubbers, and numerous chemicals that are derived from fossil oil through petrochemical refinery processes. However, this is not sustainable due to the limited nature of fossil resources. Furthermore, our world is facing problems associated with climate change and other environmental problems due to the increasing use of fossil resources. One solution to address above problems is the use of renewable non-food biomass for the production of chemicals, fuels and materials through biorefineries. Microorganisms are used as biocatalysts for converting biomass to the products of interest. However, when microorganisms are isolated from nature, their efficiencies of producing our desired chemicals and materials are rather low. Metabolic engineering is thus performed to improve cellular characteristics to desired levels. Over the last decade, much advances have been made in systems biology that allows system-wide characterization of cellular networks, both qualitatively and quantitatively, followed by whole-cell level engineering based on these findings. Furthermore, rapid advances in synthetic biology allow design and synthesis of fine controlled metabolic and gene regulatory circuits. The strategies and methods of systems biology and synthetic biology are rapidly integrated with metabolic engineering, thus resulting in "systems metabolic engineering".
In the paper published online in Nature Chemical Biology on May 17, Professor Sang Yup Lee and his colleagues at the Department of Chemical and Biomolecular Engineering, Korea Advanced Institute of Science and Technology (KAIST), Daejeon, Korea present new general strategies of systems metabolic engineering for developing microorganisms for the production of natural and non-natural chemicals from renewable biomass. They first classified the chemicals to be produced into four categories based on whether they have thus far been identified to exist in nature (natural vs. nonnatural) and whether they can be produced by inherent pathways of microorganisms (inherent, noninherent, or created): natural-inherent, natural-noninherent, non-natural-noninherent, and non-natural-created ones. General strategies for systems metabolic engineering of microorganisms for the production of these chemicals using various tools and methods based on omics, genome-scale metabolic modeling and simulation, evolutionary engineering, synthetic biology are suggested with relevant examples. For the production of non-natural chemicals, strategies for the construction of synthetic metabolic pathways are also suggested. Having collected diverse tools and methods for systems metabolic engineering, authors also suggest how to use them and their possible limitations.
Professor Sang Yup Lee said "It is expected that increasing number of chemicals and materials will be produced through biorefineries. We are now equipped with new strategies for developing microbial strains that can produce our desired products at very high efficiencies, thus allowing cost competitiveness to those produced by petrochemical refineries."
Editor of Nature Chemical Biology, Dr. Catherine Goodman, said "It is exciting to see how quickly science is progressing in this field – ideas that used to be science fiction are taking shape in research labs and biorefineries. The article by Professor Lee and his colleagues not only highlights the most advanced techniques and strategies available, but offers critical advice to progress the field as a whole."
The works of Professor Lee have been supported by the Advanced Biomass Center and Intelligent Synthetic Biology Center of Global Frontier Program from the Korean Ministry of Education, Science and Technology through National Research Foundation.
Contact: Dr. Sang Yup Lee, Distinguished Professor and Dean, KAIST, Daejeon, Korea (leesy@kaist.ac.kr, +82-42-350-3930)
2012.05.23 View 15487 -
Korea's First MOU between a University Education Volunteer Work Group and Local Government
- 200 Adolescents from Yuseong-gu to Receive Education Community Services
Midam Scholarship committee which is composed of KAIST"s students and graduates, will draw up a contract that states that it will work together with the Yuseong-gu municipality for the development of the district education services on the 14th at the Yuseong-gu office.
Both sides will together ▲mentor the local students, ▲cooperate to run and develop creative programs, ▲exchange work for the development of the KAIST Midam Scholarship Committee, ▲conduct various other projects.
From now, the Midam Scholarship Committee will teach about 200 students in Yuseong-gu. The drawing of this contract has much meaning in that it is the first of its kind.
The Midam Scholarship Committee was founded on 2009 by students in KAIST to teach math, english, and science to students from families with low income levels.
This committee has made educational pacts with middle and high schools located in Daejeong such as Chungnam High School and Beobdong High School, and has not only taught these students but also has given scholarships to the selected students.
On one hand, the Midam Scholarship Committee has also supported 10 students in KAIST who were in need with 300000won each on the 6th. This fund was raised through the donations of alumni and mentoring projects.
The Midam Scholarship Committee has been recognized for its positive impacts on the society and has received an award from the Yuseong-gu municipality office.
2012.05.10 View 9786
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KAIST Midam Institute Gives Donations Raised by Students
Midam Association which is consisted of students from KAIST (representatives Neung-in Jang and Minkyu Jin) has donated 300thousand won per person to ten KAIST students who are in need totaling a 3million won of donation. This donation was created through the mentoring activities of the members and donations from alumni and alumni corporations.
Midam Association which was created on July of 2009 teaches math, science, and English to children from lesser off families. It started as a club created by undergraduate students and has now turned into an NGO where other local volunteers could participate.
Currently as of March, there are ten schools including Bubdong Middle School, Jeon-min Middle School, Chungnam High School, and Jeonmin High School that have a pact with the Midam Association. The association has been conducting education assistance as well as giving donations to students in need.
Last January, UNIST has benchmarked KAIST"s Midam Association and has started free education volunteer programs in association with Ulsan city.
On the other hand, Midam Association of KAIST has been awarded a Certificate of Recognition by the Municipality of Yuseong-gu, Daejeon in recognition of their deed.
2012.05.10 View 9162
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Kaist expresses appreciation to a Swedish nurse served in the Korean War and donated a scholarship.
Public release date: 19-Dec-2011
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Contact: Lan Yoon
hlyoon@kaist.ac.kr
82-423-502-295
The Korea Advanced Institute of Science and Technology (KAIST)
Kaist expresses appreciation to a Swedish nurse served in the Korean War and donated a scholarship
The largest private donation ever given to KTH Royal Institute of Technology in Stockholm, Sweden, will include a scholarship for KAIST students to study there
The largest private donation ever given to KTH Royal Institute of Technology in Stockholm, Sweden, will include a scholarship for KAIST students to study there.
"I"ve never forgotten the tragedy of the Korean War that I witnessed as a nurse, even today, more than 60 years later. I"m glad to contribute to a wider cooperation in science and technology between Sweden and Korea," said the donor.
Daejeon, Republic of Korea, December 19, 2011— On Monday, December 19th, 2011 at 4:00 pm (Central European Time), at KTH Royal Institute of Technology (KTH) in Stockholm, KAIST (Korea Advanced Institute of Science and Technology) presented a plaque of appreciation to a Swedish couple, Rune and Kerstin Jonasson, whose generous donation will establish a scholarship fund for KAIST students.
In late June of 2011, the Jonassons donated 70 million Krona ($10 million USD) to KTH, the largest lump sum donation ever given to the university by an individual, and the couple requested that a portion of the money be used to promote academic interaction and collaboration with Korean universities. KTH had various student exchange programs with KAIST, and with the financial support from the Jonassons, the two universities have decided to invite KAIST students to study at KTH.
Enjoying a long tradition of excellence in higher education in Asia and Northern Europe, KAIST and KTH have continued to lead the development of science and technology through top-notch educational programs, dynamic research experiences, technological innovation, and highly skilled and motivated manpower. The two global research universities expect that the scholarship program will add another dimension to already expanding exchanges.
Kerstin Jonasson, 88 years old, came to Korea in 1951 when she was 28, and served a six-month tour of duty as a nurse in the Korean War. Recalling her past, Mrs. Jonasson said, "The calamity of the war remains deeply engraved in my mind." Ever since returning from the battlefield, she has been seeking ways to help Korea, and has thus been regularly involved in volunteer activities to strengthen bilateral relations between Korea and Sweden.
Chang-Dong Yoo, Associate Vice President of Special Projects & Institutional Relations at KAIST, thanked the couple while presenting them with the award on behalf of KAIST family including President Nam-Pyo Suh.
"We feel greatly indebted to the Jonassons, most particularly to Kerstin Jonasson, who came to Korea during the toughest time in our modern history and rendered generous humanitarian assistance to Koreans. Not only that, Mrs. Jonasson has continued to play an important role, up to today, as a "Goodwill Ambassador for Korea" in bringing the two countries closer than ever. This scholarship will provide our students with excellent opportunities to study in Sweden, the home of many great scientists, as well as to experience the robust and vibrant Nordic culture."
In response, Kerstin Jonasson said:
"I"m grateful to the Korean people who, over the past 60 years, have consistently expressed their appreciation for my work during the Korean War, and I"m really proud of the fact that they"ve made Korea a great country, reemerging from the destitution of the war as an important power of democracy and economy in the world. My husband and I hope that our donation will further enhance the strong ties forged between Sweden and Korea, and that KTH and KAIST will become the centerpiece of a mutually beneficial relationship between the two countries through the advancement of science and technology."
The details of the scholarship have yet to be finalized, but the fund is expected to be approximately 10 to 15 million Krona ($1.4~$2.1 million USD) to be spread out over five years. KAIST aims to begin sending students to KTH in the fall of 2012, and will select 10~12 graduate students for the exchange program. Since 1990, 38 KAIST students have studied at KTH, and 50 KTH students have studied at KAIST.
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2011.12.23 View 10045 -
"2011 Korean Language and Culture Festival" held in commemoration of KAIST 40th Anniversary
“2011 Korean Language and Culture Festival” was hosted by KAIST from the 5th of October to the 8th of October for 4 days at various locations within campus and BaekJae Cultural Complex in Daejeon City. The festival was aimed at increasing foreigners’ understanding about Korean culture and language and at the same time, introduced about KAIST, the home of the best minds in Korea’s science and technology.
The festival was part of the KAIST 40th anniversary celebratory events, which included 1) Korean Speaking Competition, 2) Korean Traditional Music Performance by Daejeon City Orchestra, 3) Foreigners Talent Show, 4) Tour of BaekJae Cultural Complex, and others such as lecture given by Chairman Lee Cham of Korea Tourism Organization.
In the Korean Speaking Competition, 10 foreigners who passed the preliminaries competed by giving speeches with the theme on “Korea that I’ve experienced.” The speakers were given 5 minutes for speech, and their presentations were graded based on uniqueness, fluency, appropriateness, and fluidity in spoken Korean. 200,000 Korean Won was given to a winner as prize.
In addition, the chance for foreigners to visit the BaekJae Cultural Complex allowed them to experience firsthand “traditional Korean culture,” through which they had a good opportunity to develop a better understanding on Korea as a whole.
Director of KAIST Language Center Michael Park commented, “The festival was a meaningful and important occasion for foreigners to appreciate Korean culture and language, and it would be a great step towards foreigners’ gaining a solid understanding of Korean culture and language to the extent that they become to know better about DaeJeon, the city they live in.”
2011.10.10 View 9633
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Bicycle Sharing System "Ta-Shu" Arrives at KAIST.
KAIST has begun providing a bike rental service, called “Ta-Shu,” to its students. This bicycle sharing system, implemented in tandem with the local city government, has been in service since the 7th of September and will allow KAIST students to rent bicycles for travel within campus and even to other parts of the city, Daejeon.
The ‘University Pubic-Bicycle Rental System’ is a program in which numbers of bicycles are made available for shared use by students. Initiated by the Ministry of Public Administration and Security, the university expects that more students will use bicycles as part of their daily mobility means through this system.
2011.09.22 View 9150 -
Cancer detection from an implantable, flexible LED
Professor Keon Jae Lee
A KAIST research team has developed a new type of biocompatible and bendable GaN LED biosensor.
Daejeon, the Republic of Korea, August 8, 2011—Can a flexible LED conformably placed on the human heart, situated on the corrugated surface of the human brain, or rolled upon the blood vessels, diagnose or even treat various diseases? These things might be a reality in the near future.
The team of Professor Keon Jae Lee (Department of Materials Science and Engineering, KAIST) has developed a new concept: a biocompatible, flexible Gallium Nitride (GaN) LED that can detect prostate cancer.
GaN LED, a highly efficient light emitting device, has been commercialized in LED TVs and in the lighting industry. Until now, it has been difficult to use this semiconductor material to fabricate flexible electronic systems due to its brittleness. The research team, however, has succeeded in developing a highly efficient, flexible GaN LED and in detecting cancer using a flexible LED biosensor.
Prof. Lee was involved in the first co-invention of "High Performance Flexible Single Crystal GaN" during his PhD course at the University of Illinois at Urbana-Champaign (UIUC). This flexible GaN LED biosensor utilized a similar protocol to transfer thin GaN LED films onto flexible substrates, followed by a biocompatible packaging process; the system’s overall potential for use in implantable biomedical applications was demonstrated.
Professor John Roger (Department of Materials Science and Engineering, UIUC) said,
“Bio-integrated LEDs represent an exciting, new technology with strong potential to address important challenges in human health. This present work represents a very nice contribution to this emerging field.”
This paper was published in the online issue of Nano Energy Elsevier Journal (Editor, Prof. Zhong Lin Wang) dated September 16, 2011.
Flexible GaN LED produces blue light.
2011.09.20 View 13375 -
Review of organophosphonate nerve agent remediation and sensing chemistry
Professor David Churchill, Dept. of Chemistry, KAIST
Scientists in Daejeon, South Korea and Lexington, Kentucky (USA) have recently published a review on the subject of nerve agent remediation and probing chemistry (Chemical Reviews, DOI:10.1021/cr100193y). This article endeavored to pursue organophosphonate nerve agent chemistry deeply and comprehensively and to reflect that decontamination / sensing and nerve agents / pesticides are quite inextricable: when one tries to degrade nerve agents one also needs to detect what components are still present “downstream,” etc. Nerve agents and many pesticides also share a common generalized organophosphate / -phosphonate structure.
Also, the use of simulant molecules (mimics) and a consideration of the closely related organophosphonate pesticides were also treated comprehensively in the Review. The authors reached back into the literature when developing some sections to make important connections to the contemporary topics of interest. The review also includes industrial insights.
Kibong Kim, Olga G. Tsay and David G. Churchill of the Department of Chemistry at KAIST and David A. Atwood of the Department of Chemistry of the University of Kentucky endeavored to "make a variety of connections in research strategies and (sub-) fields to present what is still possible, fruitful, practical, and necessary and to facilitate a current comprehensive molecular level understanding of organophosphonate degradation and sensing," Churchill says.
The authors feel that for the time being, researchers in varying research areas “can use this manuscript effectively when considering future research directions.”
2011.09.19 View 9927 -
Late Dr. Ryu Geun Chul's Achievements and Generous Contributions
First Doctor in the field of Korean Traditional Medicine
The late Dr. Ryu was born in 1926 and is the father figure of Korea’s Traditional Medicine and is its First Doctor (1976 Kyung Hee University), and was the vice-professor of Kyung Hee University of Medicine, Vice-Director of Kyung Hee Institute of Korean Traditional Medicine, and was the first chairman of the Association of Korea Oriental Medicine. He developed the painless acupuncture administering device for the first time in Korea in 1962, and succeeded in anesthetizing a patient for cesarean procedure using acupuncture in 1972.
He even was the first to receive a medical engineering doctorate degree from the Moscow National Engineering School in April of 1996 and developed a stroke rehabilitation machine.
Korea’s Most Generous Donor
Dr. Ryu surprised the world by donating 57.8billion Won worth of real estate to KAIST in August of 2008. Dr. Ryu revealed that his reason for donating such a huge sum to KAIST was due to its focused students giving him the belief that the future of Korea is at KAIST and that the development of science and technology is necessary for Korea to develop into a world class nation and KAIST is the institute most suitable to lead Korea in the field.
Dr. Ryu lived on KAIST campus after donating his entire fortune and even established ‘KAIST scholars and spacemen health research center’ and ‘Dr. Ryu Health Clinic’ as he also wanted to donate his knowledge.
Even when he was a professor at Moscow National Engineering University in the late 1990s he carried out free medical work throughout Korea and in recognition of his devoted work, he was named honorary citizen from Chun Ahn city, San Chung city, and DaeJeon city. In 2007 he donated 450million Won to Cheon Dong Elementary School in Chun Ahn city to build a gymnasium and an indoor golf practice range.
Role as Science and Technology Public Relations Officer
Dr. Ryu volunteered to numerous lectures and interviews after donation to advertise science and technology. His belief that the development of science and technology is necessary for Korea’s development was the driving force behind his efforts at increasing interest and support for the field of science and technology.
In addition, through interviews with MBC, KBS, SBS, KTV, Joong Ang Newspapers, Dong Ah Newspaper and other media mediums, Dr. Ryu improved the public perception on donations whilst increasing the pride of scientists and researchers by highlighting their importance and the importance of science and technology.
In recognition of Dr. Ryu’s efforts, he received the 43rd Science Day Science and Technology Creation Award, 2010 MBC Social Service Special Award, and 2010 ‘Proud Chung Cheong Citizen’ Award.
2011.03.22 View 20768
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Rise of the mimic-bots that act like we do: Human-machine teamwork.
An online magazine, Technology Marketing Corporation, based in the UK published an article, dated January 8, 2011, on a robot research project led by Professor Jong-Hwan Kim from the Electrical Engineering Department. The article follows below:
Technology Marketing Corporation
[January 08, 2011]
Rise of the mimic-bots that act like we do Human-machine teamwork
(New Scientist Via Acquire Media NewsEdge) Rise of the mimic-bots that act like we doA robot inspired by human mirror neurons can interpret human gestures to learn how it should actNow follow meA robot inspired by human mirror neurons can interpret human gestures to learn how it should actA HUMAN and a robot face each other across the room. The human picks up a ball, tosses it towards the robot, and then pushes a toy car in the same direction.
Confused by two objects coming towards it at the same time, the robot flashes a question mark on a screen. Without speaking, the human makes a throwing gesture. The robot turns its attention to the ball and decides to throw it back.
In this case the robot"s actions were represented by software commands, but it will be only a small step to adapt the system to enable a real robot to infer a human"s wishes from their gestures.
Developed by Ji-Hyeong Han and Jong-Hwan Kim at the Korea Advanced Institute of Science and Technology (KAIST) in Daejeon, the system is designed to respond to the actions of the person confronting it in the same way that our own brains do. The human brain contains specialised cells, called mirror neurons, that appear to fire in the same way when we watch an action being performed by others as they do when we perform the action ourselves. It is thought that this helps us to recognise or predict their intentions.
To perform the same feat, the robot observes what the person is doing, breaks the action down into a simple verbal description, and stores it in its memory. It compares the action it observes with a database of its own actions, and generates a simulation based on the closest match.
The robot also builds up a set of intentions or goals associated with an action. For example, a throwing gesture indicates that the human wants the robot to throw something back. The robot then connects the action "throw" with the object "ball" and adds this to its store of knowledge.
When the memory bank contains two possible intentions that fit the available information, the robot considers them both and determines which results in the most positive feedback from the human?- a smile or a nod, for example. If the robot is confused by conflicting information, it can request another gesture from the human. It also remembers details of each interaction, allowing it to respond more quickly when it finds itself in a situation it has encountered before.
The system should allow robots to interact more effectively with humans, using the same visual cues we use. "Of course, robots can recognise human intentions by understanding speech, but humans would have to make constant, explicit commands to the robot," says Han. "That would be pretty uncomfortable."Socially intelligent robots that can communicate with us through gesture and expression will need to develop a mental model of the person they are dealing with in order to understand their needs, says Chris Melhuish, director of the Bristol Robotics Laboratory in the UK. Using mirror neurons and humans" unique mimicking ability as an inspiration for building such robots could be quite interesting, he says.
Han now plans to test the system on a robot equipped with visual and other sensors to detect people"s gestures. He presented his work at the Robio conference in Tianjin, China, in December. nAs the population of many countries ages, elderly people may share more of their workload with robotic helpers or colleagues. In an effort to make such interactions as easy as possible, Chris Melhuish and colleagues at the Bristol Robotics Laboratory in the UK are leading a Europe-wide collaboration called Cooperative Human Robotic Interaction Systems that is equipping robots with software that recognises an object they are picking up before they hand it to a person. They also have eye-tracking technology that they use to monitor what humans are paying attention to. The goal is to develop robots that can learn to safely perform shared tasks with people, such as stirring a cake mixture as a human adds milk.
(c) 2011 Reed Business Information - UK. All Rights Reserved.
2011.01.10 View 12238
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Native-like Spider Silk Produced in Metabolically Engineered Bacterium
Microscopic picture of 285 kilodalton recombinant spider silk fiber
Researchers have long envied spiders’ ability to manufacture silk that is light-weighted while as strong and tough as steel or Kevlar. Indeed, finer than human hair, five times stronger by weight than steel, and three times tougher than the top quality man-made fiber Kevlar, spider dragline silk is an ideal material for numerous applications. Suggested industrial applications have ranged from parachute cords and protective clothing to composite materials in aircrafts. Also, many biomedical applications are envisioned due to its biocompatibility and biodegradability.
Unfortunately, natural dragline silk cannot be conveniently obtained by farming spiders because they are highly territorial and aggressive. To develop a more sustainable process, can scientists mass-produce artificial silk while maintaining the amazing properties of native silk? That is something Sang Yup Lee at the Korea Advanced Institute of Science and Technology (KAIST) in Daejeon, the Republic of Korea, and his collaborators, Professor Young Hwan Park at Seoul National University and Professor David Kaplan at Tufts University, wanted to figure out. Their method is very similar to what spiders essentially do: first, expression of recombinant silk proteins; second, making the soluble silk proteins into water-insoluble fibers through spinning.
For the successful expression of high molecular weight spider silk protein, Professor Lee and his colleagues pieced together the silk gene from chemically synthesized oligonucleotides, and then inserted it into the expression host (in this case, an industrially safe bacterium Escherichia coli which is normally found in our gut). Initially, the bacterium refused to the challenging task of producing high molecular weight spider silk protein due to the unique characteristics of the protein, such as extremely large size, repetitive nature of the protein structure, and biased abundance of a particular amino acid glycine. “To make E. coli synthesize this ultra high molecular weight (as big as 285 kilodalton) spider silk protein having highly repetitive amino acid sequence, we helped E. coli overcome the difficulties by systems metabolic engineering,” says Sang Yup Lee, Distinguished Professor of KAIST, who led this project. His team boosted the pool of glycyl-tRNA, the major building block of spider silk protein synthesis. “We could obtain appreciable expression of the 285 kilodalton spider silk protein, which is the largest recombinant silk protein ever produced in E. coli. That was really incredible.” says Dr. Xia.
But this was only step one. The KAIST team performed high-cell-density cultures for mass production of the recombinant spider silk protein. Then, the team developed a simple, easy to scale-up purification process for the recombinant spider silk protein. The purified spider silk protein could be spun into beautiful silk fiber. To study the mechanical properties of the artificial spider silk, the researchers determined tenacity, elongation, and Young’s modulus, the three critical mechanical parameters that represent a fiber’s strength, extensibility, and stiffness. Importantly, the artificial fiber displayed the tenacity, elongation, and Young’s modulus of 508 MPa, 15%, and 21 GPa, respectively, which are comparable to those of the native spider silk.
“We have offered an overall platform for mass production of native-like spider dragline silk. This platform would enable us to have broader industrial and biomedical applications for spider silk. Moreover, many other silk-like biomaterials such as elastin, collagen, byssus, resilin, and other repetitive proteins have similar features to spider silk protein. Thus, our platform should also be useful for their efficient bio-based production and applications,” concludes Professor Lee.
This work is published on July 26 in the Proceedings of the National Academy of Sciences (PNAS) online.
2010.07.28 View 20801 -
The 2010 International Forum on Electric Vehicle will be held at the Korea Advanced Institute of Science and Technology (KAIST) in Daejeon, South Korea.
Universities, industries, and governments from the world gathered to make an important endeavor for the commercialization of electric vehicles that has emerged as a strong option to replace conventional cars with an internal combustion engine.
With the potential benefit of electric cars, in view of environmental protection and less dependence of oil import, they still have limitations for the daily use in customers’ perspective. Electric cars are still very expensive to own with relatively short distance of driving with one charging and with the expensive and bulky nature of the batteries, in addition to the safety concerns with the Lithium batteries.
The Korea Advanced Institute of Science and Technology (KAIST) will hold an international forum, at which it hopes to address a wide range of issues related to the development and commercialization of electric vehicles. The 2010 International Forum on Electric Vehicle will be held for three days at KAIST’s campus in Daejeon, South Korea, from June 17th to 19th, 2010.
Internationally renowned speakers from Korea and overseas will present their views and conduct a discussion forum on the technology, market, and policy on electric vehicles. The event is open to the public.
Major discussions, however, will take place on the second day, Friday, June 18, 2010, which will proceed with two sessions. In the first session, conference participants will discuss the topic of “policies and markets for electric vehicles,” and at the second session, they will take up the issue of “electric vehicle technologies.”
Dr. Andrew Brown, president of SAE International and the executive director and chief technologist of Delphi, is scheduled to give a key note speech. The SAE International is a global association of more than 128,000 engineers and related technical experts in the aerospace, automotive, and commercial vehicle industries.
Topics to be covered by Dr. Brown during his key note speech are, among other things, elements of market forces for hybrid electric vehicles, electric vehicles, or battery-powered vehicles; clean technologies necessary for sustainable development; pending issues facing the automotive industry to create a substantial share by electric cars and government aids to increase consumers’ buying power for expensive electric cars; technology innovation required for the improvement of batteries and power electronics; development of smart grids; and other key issues that would mature an ever-growing market for electric vehicles.
President Nam Pyo Suh of KAIST will also deliver a key note remark on the overall accomplishments of online electric vehicle (OLEV) developed by KAIST. While stressing the OLEV’s technological breakthrough to succeed in the wireless in-motion power transfer through electromagnetic induction, President Suh will review the necessity of developing electric cars as a corresponding measure against climate changes and address the issues of battery weight and lifespan, charging time, and the limited amount of reserved Lithium.
Dr. Steven Shladover from the California Partners for Advanced Transit and Highways (California PATH), established in 1986 in collaboration with the University of California in Berkeley and the California Transit, will attend the conference. California PATH is a multi-disciplinary program with universities statewide and cooperative projects with private industry, state and local agencies, and non-profit institutions to find solutions to the problems of California’s surface transportation systems through cutting edge research.
California PATH once implemented a bold, innovative research project in the early 1990s in order to overcome the most difficult technical hurdle to reduce the heavy dependence of batteries for electric cars by adopting a non-contact transfer of electric power during vehicles’ movement. Despite the research declared as “unsuccessful” by California PATH, the implications of their innovative approach to solve an important issue inspired many researches subsequently followed—one of them is KAIST’s OLEV project.
In addition, the Infineon Technologies AG, a leading semiconductor and system manufacturer based in Germany, which offers solutions for automotive, industrial and multimarket sectors for applications in communication and memory products, will come to the forum and present a paper on its expertise to develop the necessary components for electric vehicles.
On the last day of the forum, all participants will have a chance to ride the Online Electric Vehicle (OLEV) at KAIST’s campus.
For details of the event, please visit the website of “www.olev.co.kr/en/ifev or refer to the invitation attached herewith.
About KAIST’s Online Electric Vehicle:
The Online Electric Vehicle (OLEV) developed by KAIST is a dynamic plug-in electric car that receives electricity while running or stopping and thus acquired a complete mobility unlike other type of electric cars, whether hybrid or not. The OLEV reduces the size of a battery to one-fifth of the current battery installed in an electric car. Pure electric cars depend on a large bulky battery that has been a major obstacle to make the cars commercially accessible to the mass market. The OLEV gets charged wirelessly, a distinct difference to other dynamic plug-in electric cars including a tram or trolley, which directly picks up electricity from the road.
To explain it further, the OLEV is electrified through power lines buried underground; when flowing low frequency of currents, an electric magnetic field is created around the underground power lines, and the pick-up gadget installed underbody of an electric vehicle converts the field into electricity; and the vehicle then uses electricity either for operation or stores it at a battery to be used for running the road that is not equipped with the power lines. The electric power generated from the underground travels to the surface of the road above 20cm-25cm.
KAIST has succeeded to develop a commercial model of OLEV with a safe Electromagnetic Field (EMF), well below the international safeguard of 65mG. The actual model has been up and running at an amusement park in Seoul for the transportation of passengers. The non-contact charging method applied to the OLEV will accelerate the commercialization of electric cars by making a battery affordable and safer for a consumer.
2010.06.25 View 15533