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鶹Ӱ has successfully concluded its international exchange programs for foreign students_the 2025 Ajou International Summer School (AISS, Ajou International Summer School) and the (ABC, Ajou Bespoke College).The ABC Program ran for two weeks, from July 2 to July 15, beginning with an orientation held at Yulgok Hall. A total of 19 students from partner universities abroad including the University of Wisconsin, University of Southern California, University of South Florida, University of Nevada, Las Vegas, and the University of California, San Diego participated alongside 10 students from 鶹Ӱ. The program was designed to foster growth through capstone design projects, corporate field trips, and cultural exchange between international students and their Ajou counterparts. Participants visited companies such as Naver, Samsung Electronics, Gyeonggi Provincial Council, Dentium, Celltrion, and Daewoong Pharmaceutical, and explored Korean culture and history through experiences like visits to the National Museum of Korea, K-POP dance classes, and the Hwaseong Haenggung Palace.The program also included special lectures such as:Data Analysis on Korea's Economic and Cultural Development by Prof. Yoon Cheon-Seok (Global Business)Korea's Industrial History and Growth through Early Entrepreneurship by Prof. Kim Chan-Woo (University-Industry Cooperation)Modern History Rooted in Ancient Korea by Prof. Han Sang-Woo (History)Promoting Historical Content through National Museum Exhibits by Prof. Park Jae-Yeon (Cultural Contents)The AISS program was conducted over a three-week period starting on June 30, concluding with a graduation ceremony on July 18. During the program, students took courses such as:Data Analytics and Business Decision Making by Prof. Lee Sang-Kyu (Endicott College)Macroeconomic Development by Prof. Kim Tae-Bong (Economics)Understanding Korean Culture by Scott Scattergood (Dasan College)Sustainability by Prof. Lee Jae-Young (Environmental Safety Engineering)Korean Language by Professors Jeong Mi-Hye and Jeong Mi-Ji (Dasan College)In addition to classes, students enjoyed various cultural experiences including K-POP dance, traditional Korean cuisine, and visits to Bukchon Hanok Village. They also toured local landmarks such as the Samsung Innovation Museum, Hwaseong Haenggung Palace, and Suwon Media Center, gaining insights into both Korea’s past and present.At the AISS farewell, Prof. Lee Sang-Kyu told the graduates, “If you experienced something here that can only be found in Korea, make sure to record it. It will surely be something worth remembering.” He emphasized the lasting value of the students’ experiences in Korea.Exchange students enjoyed a K-pop danceHwaseong Haenggung Palace Tour
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- 작성자국제교류팶
- 작성일2025-07-30
- 66
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Professor Inhwan Lee’s research team at our university has successfully developed a new synthetic method that allows for flexible design of the structure of semiconducting polymer materials. This advancement enables faster production of polymers used in electronic devices and is expected to contribute significantly to the development of next-generation organic semiconductors.Professor Lee revealed that through a “Multicomponent Polymerization (MCP)” technique, which reacts three different monomers simultaneously, they have developed a technology that precisely controls the sequence inside semiconducting polymers and efficiently implements various structures.This research was published in the July issue of Angewandte Chemie International Edition under the title “Versatile Halide-Pair-Driven Multicomponent Polymerization for Library Synthesis of Sequence-Controlled Semiconducting Dendronized Polymers.” The paper received excellent reviews and was selected as a “Very Important Paper (VIP).”The study involved doctoral student Hae-nam Choi (right in the photo) from the Department of Energy Systems at 鶹Ӱ as the first author. Co-authors included Soo-min Go (Master’s graduate, 鶹Ӱ), Se-min Son (Integrated Master’s and PhD program, 鶹Ӱ), Ji-su Woo (Master’s student, UNIST Department of Energy Chemical Engineering), Hyun-woo Park (PhD student, ETH Zurich Department of Materials), and Dong-jun Lee (Graduate of integrated Master’s and PhD program, 鶹Ӱ).Professors Tae-rim Choi (ETH Zurich, Materials), Won-jin Kwak (UNIST, Energy Chemical Engineering), and Hwan-myung Kim (鶹Ӱ, Energy Systems) participated as co-authors, and Professor Inhwan Lee (鶹Ӱ, Department of Chemistry) served as the corresponding author.Poly(triarylamine) (PTAA) polymers are used in various organic electronic devices such as organic light-emitting devices, perovskite solar cells, electrochromic devices, flexible electronics, and battery electrodes. PTAA is especially notable as a hole transport material in perovskite solar cells. However, traditional synthesis of poly(triarylamine) polymers involved complicated multi-step synthesis and purification of reaction intermediates, which posed challenges for commercialization and cost efficiency. The core of this research lies in presenting a new polymerization strategy that precisely controls the polymer sequence by designing the reaction order of three readily available monomers mixed together in a single step.The research team successfully synthesized a library of semiconducting poly(triarylamine) polymers where arylamine and two types of aryl dihalide monomers are connected in a predetermined sequence. They also expanded this strategy to synthesize complex dendronized polymers, greatly broadening the structural diversity of polymers. As a result, poly(triarylamine) polymers and their derivatives used in electronic devices can now be rapidly produced in library form, which is expected to greatly accelerate the development of next-generation organic semiconductors.Professor Inhwan Lee said, “Through this research, we have enabled the cheap and diverse synthesis of expensive polymers in a single reaction step. We also expect this to contribute to improving the performance of organic electronic devices.”This research was supported by the National Research Foundation of Korea’s Mid-career Researcher Support Program, the G-LAMP program, the Carbon to X technology development project for producing useful substances, and the Leading Research Center (MRC) program.Image showing the synthesis process of sequence-controlled semiconducting polymers via sequential C–N coupling reactions
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- 작성자국제교류팶
- 작성일2025-07-21
- 442
- 동영상동영상
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(Photo) Schematic diagram of the energy generation system and mechanism:(a) Autonomous electrical energy harvesting system driven by water circulation due to temperature difference between day and night(b) Water harvesting mechanism using UiO-66-NH₂(c) Electrical energy generation mechanism using Ni3(HITP)2(d) Autonomous water harvesting and sustainable electrical energy generation system under ambient environmental conditions A Korean research team has developed a technology that collects moisture from the air using temperature differences between day and night, and converts it into electrical energy.The joint research team, led by Professor Taekwang Yoon from the Department of Applied Chemistry and Biological Engineering at 鶹Ӱ and Principal Researcher Giro Yoon from the Korea Institute of Industrial Technology (KITECH), has introduced an innovative energy harvesting system. This system is capable of generating electricity independently without any external water supply, even in extreme environments such as remote areas or deserts where water is scarce.The results of this research were published in the internationally renowned journal Composites Part B: Engineering (top 1% in JCR), under the title:"Sustainable electrical energy harvesting via atmospheric water collection using dual-MOF systems."The first authors of the study are Ji-Hyun Lee (integrated master’s and Ph.D. program, Hanyang University), Dong-Yeon Kim (Ph.D. candidate, KAIST), and Yong-Gyun Lee (master’s student, 鶹Ӱ).Professor Taekwang Yoon and Principal Researcher Giro Yoon served as co-corresponding authors.Traditional water-based energy harvesting technologies rely on the potential difference between wet and dry surfaces to generate electricity, but they have the limitation of requiring a constant external water supply. To overcome this, the research team was inspired by plant transpiration and capillary action, and combined two types of metal-organic frameworks (MOFs)—UiO-66-NH₂ and Ni₃(HITP)₂.As a result, they successfully developed a fully autonomous system that collects moisture from the air and generates electricity on its own.UiO-66-NH₂ absorbs moisture from the cool night air and releases the absorbed moisture during the warmer daytime. The released moisture condenses on the surface of fibers coated with Ni₃(HITP)₂. This condensation causes asymmetric wetting on the fiber surface, generating a potential difference, which allows electricity to flow. Through this process, the research team successfully achieved a maximum power density of 2.6 μW/cm³ and an energy density of 1.1 mJ/cm³.Notably, UiO-66-NH₂ exhibited excellent moisture adsorption and desorption performance, not only under normal conditions but also in low-humidity environments, showing its potential for use in various settings. The team conducted experiments simulating real climate conditions—including desert, coastal, and inland environments—and confirmed that the system could stably generate moisture and electricity autonomously across all tested scenarios.Professor Taekwang Yoon stated:“This research demonstrates the feasibility of a self-sustaining energy harvesting system that can operate without any external power or water supply.We hope it serves as a viable solution in disaster zones or areas with limited access to electricity.”Principal Researcher Giro Yoon added:“This system provides a technological foundation for easy electricity generation, even in extreme climates or regions lacking infrastructure.We expect this to make a meaningful contribution to sustainable energy technologies for a carbon-neutral society.”This research was supported by the National Research Foundation of Korea under the Global Research Infrastructure Cooperation Hub Program.[Energy Harvesting] refers to the technology of collecting energy from natural sources—such as sunlight, vibrations, heat, wind, waves, or even waste energy from daily life—and converting it into usable electrical energy.From the back row, starting from the left : Professor Taekwang Yoon (鶹Ӱ), Researcher Dongyeon Kim (KAIST), Principal Researcher Giro Yoon (KITECH), Researcher Yonggyun Lee (鶹Ӱ), and Researcher Jihyun Lee (Hanyang University)
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- 작성일2025-07-21
- 477
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AISS orientation was held on July 1 at Yeonam Hall, Students overview of the program and interact exchange sessions ABC orientation was held on July 2 at Yulgok Hall. Various program-related information and guidance were provided 鶹Ӱ has started its international exchange programs for foreign students: the 2025 Ajou International Summer School (AISS) and the Ajou Bespoke College (ABC) program. The AISS started off on July 1 in Yeonam Hall with an orientation and began its three-week academic session. A total of 64 students from 10 universities across eight countries—including Germany, Lithuania, the Netherlands, France, Spain, Austria, Uzbekistan, and Indonesia—are participating. Among them, 29 students are from 鶹Ӱ at Tashkent(AUT). During the program, participants will choose two out of five courses—Data Analysis & Business Decision-Making, Macroeconomic Development, Understanding Korean Culture, Sustainability, and Korean Language—to earn six credits. Beyond academics, students will experience K‑POP dance classes, traditional food experiences, visits to Bukchon Hanok Village, visits to Samsung Innovation Museum, Suwon Hwaseong Haenggung, Suwon Media Center, and more.The ABC program began its orientation on July 2 at Yulgok Hall and runs for 14 days until July 15. This year’s includes 19 students from top U.S. universities—University of Wisconsin, USC, University of South Florida, UNLV, UC San Diego—as well as 10 鶹Ӱ students. Centered on a capstone project led by Professor So Jae‑hyun (Construction & Transportation Engineering), the curriculum also features lectures on data analysis of Korea’s economic and cultural development (Prof. Yoon Cheon‑seok), the history and current state of Korean industry and entrepreneurial spirit (Prof. Kim Chan‑woo), the transformation from ancient to modern Korean history (Prof. Han Sang‑woo), and promoting historical content focusing on National Museum artifacts (Prof. Park Jae‑yeon) . Field trips include visits to Samsung Innovation Museum, Celltrion, DaeWoong, Dentium, Naver, the National Museum, Gyeonggi Provincial Assembly, a Han River cruise, and Suwon Hwaseong, giving participants diverse insights into Korean culture and history.
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617
- 작성자OIA
- 작성일2025-07-04
- 1339
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- Area-Selective Atomic Layer Deposition (AS-ALD) Gains Attention as a Key Breakthrough Technology- Enables Patterning Without Exclusive 'EUV Equipment', Allowing for Customized Fabrication* Caption for the image above: An illustration showing the selective formation of red-colored aluminum oxide (Al₂O₃) only at the grain boundaries — the leakage current pathways — of zirconium dioxide (ZrO₂) through the new area-selective atomic layer deposition (AS-ALD) process developed by the 鶹Ӱ joint research team. This technology is expected to maximize storage capacity while minimizing data loss in DRAM devices. Professor Ilkwon Oh’s research team at 鶹Ӱ has developed a technology that enhances the precision of semiconductor processes through area-selective atomic layer deposition (AS-ALD). This advancement is expected to play a crucial role in the manufacturing of next-generation miniaturized and high-density semiconductor devices. Professor Ilkwon Oh (Department of Intelligent Semiconductor Engineering and Department of Electrical and Computer Engineering) and a joint research team from the Samsung Advanced Institute of Technology (SAIT) announced their successful development of an AS-ALD technology that can significantly improve the precision of thin film deposition in semiconductor fabrication. Their research was published in the April issue of Advanced Science under the title “Area-Selective Atomic Layer Deposition on Homogeneous Substrate for Next-Generation Electronic Devices.” Minjeong Lee, Byungjun Won, and Youngjin Lim (Master’s students from the Department of Intelligent Semiconductor Engineering at 鶹Ӱ) participated as co-first authors, and Professor Ilkwon Oh served as the corresponding author. Dr. Seonghyun Kim and Dr. Jungkyu Song from SAIT also contributed as co-authors. Area-Selective Atomic Layer Deposition (AS-ALD) is a process that enables deposition to occur only on specific areas of a semiconductor substrate. This technology allows precise application of desired materials to selected locations on the semiconductor surface. Traditional Atomic Layer Deposition (ALD), widely used in semiconductor processes, forms uniform thin films across the entire substrate. It has been a key technique in the manufacturing of memory devices such as DRAM and NAND flash, as well as non-memory (system) semiconductors. However, as semiconductor devices continue to shrink and become more densely integrated, there is an increasing demand for selective thin-film deposition to reduce process steps, lower manufacturing costs, minimize error rates, and improve precision and efficiency. Consequently, AS-ALD has emerged as a core next-generation semiconductor processing technology, attracting attention as a breakthrough solution capable of overcoming the technical limits currently facing the semiconductor industry. By employing AS-ALD, many conventional process steps can be eliminated, dramatically lowering manufacturing costs and the potential for errors. Additionally, AS-ALD enables semiconductor patterning without the need for expensive extreme ultraviolet (EUV) lithography equipment, which has been monopolized by certain companies, further intensifying industrial and academic interest. Furthermore, AS-ALD opens possibilities for customized fabrication of new types of three-dimensional micro-semiconductor devices that are difficult to achieve using traditional techniques and equipment. Despite these advantages, the implementation of AS-ALD in actual semiconductor mass production has faced significant challenges. Depending on the chemical materials and substrates used, maintaining precise selective deposition has been difficult, and electrical performance degradation has often been observed when applied to real devices. To overcome these limitations, the 鶹Ӱ research team targeted the widely used ZAZ (ZrO₂/Al₂O₃/ZrO₂) capacitor layer structure in DRAM processes. Specifically, they selectively deposited aluminum oxide (Al₂O₃) only at the grain boundaries—the paths where leakage currents typically occur—thereby minimizing unnecessary Al₂O₃ deposition and effectively improving device performance and reliability. * Transmission electron microscope (TEM) images and chemical composition analysis confirmed the selective formation of Al₂O₃ at grain boundaries. Graphs b and c illustrate the concentration of Al depending on the distance from the grain boundaries, verifying the selective deposition of Al₂O₃ at the desired locations. Using zirconium dioxide (ZrO₂) substrates, the research team experimentally analyzed and demonstrated the mechanisms for selective deposition, proving that selective control was feasible. They also confirmed that AS-ALD not only enhances semiconductor device performance but also significantly reduces unwanted leakage currents. This breakthrough suggests a method to maximize storage efficiency in DRAM devices and minimize data loss during device miniaturization, marking an important technical milestone for memory device advancement. Professor Ilkwon Oh stated, "While area-selective atomic layer deposition is essential for overcoming technological barriers in the semiconductor industry, there have been many challenges in applying it to real processes. Our research experimentally demonstrates that selective deposition and control are achievable, representing a significant advance in semiconductor processing technology." He added, "We will continue further research to enhance device performance and improve process efficiency for industrial applications." The 鶹Ӱ research team plans to pursue follow-up studies to develop more precise control techniques for atomic layer deposition processes and to explore their industrial applicability.
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- 작성자OIA
- 작성일2025-05-02
- 3599
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* In the photo above – from left: Professor Taekwang Yoon (鶹Ӱ), Seonghun Lee (Ph.D. integrated program student, 鶹Ӱ), Ji-Young Park (Master’s student, 鶹Ӱ), and Hyungseob Yoon (Ph.D. integrated program student, Chung-Ang University). Professor Taekwang Yoon’s research team at 鶹Ӱ has developed a natural rubber-based electrolyte additive that dramatically improves the performance and lifespan of supercapacitors. By utilizing eco-friendly and cost-effective materials, this innovation is expected to become a significant milestone in securing the sustainability of supercapacitors, one of the leading high-performance energy storage technologies. Professor Taekwang Yoon (Department of Applied Chemistry and Graduate School of Molecular Science and Technology) and his team announced that they successfully enhanced the performance and durability of supercapacitors by developing a novel electrolyte additive based on biopolymers. Their research findings were published online in the April issue of Energy Storage Materials under the title, “Long-lasting supercapacitor with stable electrode-electrolyte interface enabled by a biopolymer conjugate electrolyte additive.” Professor Yoon served as the corresponding author, with Seonghun Lee (Ph.D. integrated program student at 鶹Ӱ), Ji-Young Park (Master’s student at 鶹Ӱ), and Hyungseob Yoon (Ph.D. integrated program student at Chung-Ang University) contributing as co-first authors. Supercapacitors are next-generation energy storage devices that offer significant advantages over conventional batteries. They do not use lithium (Li), making them environmentally friendly, and are capable of storing large amounts of electrical energy. With their ability for rapid charge and discharge cycles and their virtually unlimited lifespan, supercapacitors are increasingly seen as a viable alternative to traditional batteries. They are already being utilized as supplementary power sources in fields such as electric vehicles and renewable energy systems, and are expected to find even broader applications in the future. Unlike batteries, which rely on chemical reactions and ion diffusion to store energy, supercapacitors store energy through surface-controlled reactions at the electrode-electrolyte interface. Thus, the stability of this interface plays a critical role in determining the electrochemical performance of supercapacitors. Because of this, ensuring the stability of the electrode-electrolyte interface has been a key research focus for improving supercapacitor performance. Various approaches have been explored, such as ▲polymer coatings ▲the use of self-healing inks based on 3D printing ▲surface modification using atomic layer deposition (ALD) techniques. However, these methods have faced limitations regarding process complexity, environmental concerns, high costs, and scalability challenges for mass production. In particular, maintaining stable interface characteristics over long periods while preserving high power output remains a major challenge. Over time, the electrode-electrolyte interface tends to become unstable, leading to the accumulation of by-products and the deterioration of electrochemical performance. In response, the 鶹Ӱ research team set a goal to develop a high-performance system that meets the demands of long-term stability, reliable operation, and environmental sustainability. a. Schematic of the supercapacitor developed by Professor Taekwang Yoon’s team at 鶹Ӱ. b. Schematic illustration of the electrode structure. c. Schematic depiction of the electrolyte additive fabrication process. The additive, made from gum kondagogu (a by-product of natural rubber production) and sodium alginate(extracted from seaweed), is eco-friendly, cost-effective, and highly efficient. To solve the instability problem of the electrode-electrolyte interface in conventional supercapacitor systems, the 鶹Ӱ research team developed a conjugated KS (gum kondagogu/sodium alginate) additive using eco-friendly natural rubber-derived gum kondagogu and sodium alginate extracted from seaweed. This additive boasts excellent solubility in aqueous electrolytes, improving ion conductivity and mobility, resulting in significantly enhanced performance compared to traditional electrolytes. Notably, adding even a small amount of the KS additive to sulfuric acid (H₂SO₄)-based electrolytes substantially improved interface characteristics. After 30,000 charge-discharge cycles, the capacitance retention rate increased from 58% to 93%. This remarkable result was achieved because the protective layer formed on the electrode surface suppressed by-product generation and facilitated smooth ion and electron transport. Compared to conventional chemically synthesized electrolytes, the KS additive-based electrolyte offers simpler processing and lower costs, making it highly promising for industrial applications. Additionally, the KS additive, being a natural polysaccharide-based biopolymer, is abundant, recyclable, and inexpensive, providing excellent scalability for mass production and large-scale processing. The research team expects that this study will establish a core technology for next-generation eco-friendly energy storage devices. In particular, electrodes made from the same biopolymers as the additive exhibit excellent flexibility and are easily manufacturable on a large scale, making them applicable not only to wearable electronics but also to large-scale energy storage systems. Professor Taekwang Yoon stated, "Through this research, we have significantly improved the electrode-electrolyte interface stability of supercapacitors, developing an eco-friendly and industrially applicable energy storage technology," and added, "We plan to continue with follow-up research aimed at applications in various fields." This research was supported by the Ministry of Science and ICT, the National Research Foundation of Korea, the University of Glasgow Startup Fund, and the AMRITA Seed Grant. *An image showing the flexibility of the large-area KS/CNT electrode developed by the 鶹Ӱ research team. The electrode maintains its structural integrity without damage under various mechanical deformations, suggesting its potential application in energy storage systems for wearable electronic devices.
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613
- 작성자OIA
- 작성일2025-05-02
- 3505
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A roundtable meeting was held to discuss ways to enhance universities’ global competitiveness. Minister of Education Lee Ju-ho, 鶹Ӱ President Choi Ki-joo, and international students from 鶹Ӱ gathered to exchange ideas on the educational environment and conditions.Held on the afternoon of the 9th at 鶹Ӱ’s Yulgok Hall, thew meeting was attended by Minister Lee and officials from the Ministry of Education, President Choi and other 鶹Ӱ representatives, as well as nine international students currently enrolled at Ajou. National Assembly member Kim Jun-hyuck and Han Sang-shin, President of the National Institute for International Education, were also present.Lee Seok-Won, Vice President for International Affairs, delivered a presentation on the theme of “Strategies to Strengthen Universities’ Global Competitiveness,” followed by a session to hear the reflections and suggestions of the international students. A free discussion among the attendees followed.The event was organized to hear firsthand opinions from international students studying in Korea. The goal is to contribute to the regional development through the recruitment, nurturing, and settlement support of outstanding international students, while enhancing the global competitiveness of Korean universities.Representing 鶹Ӱ’s international students, two graduate students and seven undergraduate students participated in the event, sharing their experiences about campus life, academic studies, and difficulties faced. Participants included GKS scholarship recipient Vats Animesh (Graduate School of International Studies, India) and Bayeh Rediet Sahlu (Master’s Program in Medicine, Ethiopia), along with: ▲ Khit Min (Department of Software)▲ Erdenesaikhan Amuujin (Department of Software) ▲ Hasegawa Reo (Department of Software) ▲ Pyae Phyo Thu (Department of Culture and Contents) ▲ Uzun Kubra (Department of Culture and Contents) ▲ Nguyen Thi Lan (Department of Business) ▲ Choo Shue Wen (Department of Korean Language and Literature).This semester, a total of 2,981 international students are enrolled at 鶹Ӱ. Of these, 1,505 are in degree programs, of which the majority are in the undergraduate program or the Master’s Degree program at the Graduate School of International Studies, while 1,476 are pursuing non-degree programs such as Korean language studies.鶹Ӱ has established various support programs to assist the growing number of international students in adapting to campus life and succeeding academically. These include: ▲ A dedicated orientation program for new international students ▲ The International Student Council ▲ Specialized counseling support programs ▲ Career development and internship support programs.Additionally, to strengthen Korean language education for international students, the Global Liberal Arts Division offers various courses and extracurricular activities, such as: ▲ Korean Language Buddy Program ▲ Korean Writing Contest ▲ Korean Language Social Gatherings ▲ Writing Clinics.The Ministry of Education is hosting the “Together Tea Talks,” where the Minister personally visits educational institutions to have conversations with students and staff. This event was held as part of the 74th session of the "Together Tea Talks.“Our international graduate student Vats Animesh speaks during the roundtableStudent Uzun Kubra (Department of Culture and Contents, Türkiye) shares her thoughts
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- 작성자OIA
- 작성일2025-04-28
- 3623
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A meeting was held between President Ki-Joo Choi and Myanmar students currently enrolled at 鶹Ӱ, aiming to support their stability and explore ways the university can assist, in light of the recent earthquake that caused significant damage in Myanmar.On the morning of April 9, six Myanmar students met with President Choi at the President’s Office in Yulgok Hall. Lee Seok-Won, Vice President of International Affairs, and Choi Jeong-Young(Catherine), Director of the Undergraduate International Admissions Team, also attended the meeting.The attendees included five undergraduate students, such as Aye Nyein Thet Naing (Business Administration major), and one student currently enrolled in the Korean Language Program. Representing the Ajou community, President Choi listened to the students as they shared the situations of their families and friends affected by the disaster, offering words of comfort. He also discussed possible support measures the university could provide.On March 28, a powerful 7.7-magnitude earthquake struck near Mandalay, Myanmar’s second-largest city, causing significant loss of life and property damage.Currently, a total of 351 Myanmar students are studying at 鶹Ӱ, including 155 in degree programs (undergraduate and graduate) and 196 in non-degree Korean language programs. The university has been monitoring the situation closely and has identified more than 20 students who reported being directly affected by the earthquake.Meanwhile, 鶹Ӱ has launched a fundraising campaign to support earthquake relief efforts in Myanmar. The campaign, which began on April 7, ran until April 14, and contributions were made through the 鶹Ӱ portal website.
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- 작성자OIA
- 작성일2025-04-28
- 3277
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鶹Ӱ held an orientation session for the Korean Language Buddy Program, designed to help international students adjust to campus life and succeed academically. The orientation took place on March 7 in the Yulgok Hall auditorium, with around 110 new international students and 40 Korean student buddies in attendance.The event included ▲welcome remarks by Professor Sun-Young Hwang (Head of Korean Language Education), ▲an introduction to the Korean Language Buddy Program by Professor Ju-mi Lee, ▲awards for outstanding participants, ▲presentations by top performers, and ▲team meetings. Awards were presented to three top-performing buddies from the second semester of the 2024 academic year: Ye-rin Kim (Economics), Yu-hwa Lim (French), and HUYNH MY NHAT (Graduate School of Korean Language and Literature). The Korean Language Buddy Program is a non-curricular initiative led by the School of Global Studies, matching 鶹Ӱ students with newly admitted undergraduate international students to support their transition into university life. To support Korean language learning, the School of Global Studies offers both academic and extracurricular programs. These include ▲the Korean Language Buddy Program, ▲Korean Writing Contest, ▲Smart Korean Gathering, and ▲Writing Clinic. Each semester, Korean buddies are selected from among applicants and paired with international students for one semester of shared Korean study and cultural experiences. Participants receive financial support for cultural activities, and Korean buddies may receive scholarships based on their volunteer hours. In the first semester of 2025, approximately 180 international students entered Ajou’s undergraduate programs, representing countries such as Vietnam, Myanmar, and Mongolia.
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- 작성자OIA
- 작성일2025-03-28
- 3889
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The leadership of 鶹Ӱ recently visited the K-NIBRT (Korean National Institute for Bioprocessing Research and Training) Initiative at Yonsei University's International Campus in Songdo, Incheon, to discuss concrete measures for collaboration in nurturing highly skilled professionals in the bioprocessing sector. This visit follows a memorandum of understanding (MOU) signed between the two institutions in February. On March 25, 鶹Ӱ President Ki-Joo Choi, accompanied by faculty members from the College of Advanced Biomedical Science and Engineering, including Dean Yong-sung Kim, met with Vice President Jong-Soo Lee of Yonsei University’s International Campus. The delegation also toured the K-NIBRT and Quantum Computing Research Centers. During the visit, the two institutions explored practical avenues for collaboration, including the joint development and operation of educational programs. The discussions involved K-NIBRT Director Gyoon-hee Han (Department of Biotechnology) and Deputy Director Do-sik Min (College of Pharmacy). K-NIBRT, operated by Yonsei University with support from the Ministry of Health and Welfare and the Ministry of Trade, Industry and Energy, was established as part of the Korean government’s “Bio-Health Innovation Strategy.” The initiative is dedicated to training work-ready professionals in bioprocessing, offering both theoretical and hands-on training in areas such as ▲mRNA, ▲vaccines, ▲antibody-based drugs, and ▲gene and cell therapies. Its curriculum spans the full spectrum of biopharmaceutical manufacturing processes, including purification, formulation, final product production, and quality control in regulatory science. In February, 鶹Ӱ and Yonsei University’s International Campus signed an MOU to cooperate on bioprocessing workforce development in connection with K-NIBRT. The agreement outlines plans for collaboration in ▲joint development and operation of academic programs, ▲career support and information exchange on emerging technologies for students, and ▲training and educational opportunities for both faculty and students. Vice President Lee of Yonsei University stated, “K-NIBRT adopts the NIBRT model from Ireland and meets global standards in training professionals in bioprocessing. We are pleased to collaborate with 鶹Ӱ, a leader in advanced biomedical education, and look forward to our joint efforts contributing meaningfully to the development of Korea’s bio industry workforce.” President Choi of 鶹Ӱ remarked, “This agreement will provide students from both the College of Advanced Biomedical Science and Engineering and other bio-related majors at Ajou with greater access to practical training opportunities. The university remains committed to supporting our students in becoming globally competitive professionals in the bio sector.” In response to the growing demand for skilled talent in the rapidly expanding bio industry, 鶹Ӱ launched the College of Advanced Biomedical Science and Engineering in 2024 and admitted its first cohort of 79 students this year. The college offers two specialized majors—Innovative Drug Engineering and Advanced Biomaterials Engineering—leading to a Bachelor of Engineering degree. In addition to scholarship opportunities, students benefit from hands-on internships and global exchange programs. The recent K-NIBRT partnership aligns with the college’s mission to produce industry-ready graduates. The college is also actively building partnerships with leading institutions such as the Osong Medical Innovation Foundation, Gyeonggi Institute of Science & Technology Promotion, and Korea Atomic Energy Research Institute, aiming to enhance Korea’s competitiveness in high-value bio sectors. Photo caption: From left to right – Professor Hyun-ji Park and Professor Hyun-jin Yoon (Program Director) of 鶹Ӱ, Dean Yong-sung Kim, Vice President Jong-Soo Lee of Yonsei University, President Ki-Joo Choi of 鶹Ӱ, Director Gyoon-hee Han and Deputy Director Do-sik Min of K-NIBRT.
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- 작성자OIA
- 작성일2025-03-28
- 3783
- 동영상동영상
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Ajou International Day, our university’s representative global event, was held in Gaon Lawn on the 7th.More than 800 foreign students from all over the world participated, making it a meaningful time for cultural exchange and communication. The "Ajou International Day," which marks its 27th anniversary this year, is an event where foreign students from our school present and share their own food and culture.Students from 16 countries participated in the event to decorate their own booth in each country and showcase their own food and culture. Students from China, Vietnam, Turkiye, Myanmar, India, the Netherlands, Germany, Uzbekistan, Bangladesh, Japan, Mexico, Spain, Mongolia, Bolivia and Albania prepared booths. The International Student Association also prepared individual booths.This year's 'Ajou International Day' consists of introduction of culture and food by country, parade of traditional costumes, experience of Korean folk games including tug-of-war.More than 2,000 international students from more than 70 countries around the world are studying at 鶹Ӱ. It is in the form of language training, exchange students, and degree programs (undergraduate, master's, and doctorate), and about 600 students are also enrolled in undergraduate programs.▲ parade of traditional costumes▲ introduction of culture and food by country
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603
- 작성자OIA
- 작성일2024-11-13
- 6862
- 동영상동영상
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Our university ranked 9th among Korean universities in the "2025 THE WORLD UNIVERSITY RANKINGS", maintaining the 501-600th rank following last year.The World University Rankings, published annually by Times Higher Education, a British university evaluation agency, is known to focus on research and educational conditions rather than school reputation, and evaluates university performance in five areas and 18 detailed indicators using papers, citations, and surveys by professors. The 2025 rankings was attended by 2,092 universities from 115 countries.In our university, the score increased in three out of five evaluation items. The score increased from 37.7 to 38.7 in the research environment, from 52.8 to 53.9 in research quality, and from 92.3 to 94.2 in industry-academia cooperation. Education maintained a score of 35.6, and internationalization fell 0.2 points, but the impact on the ranking was minimal.Since the 2018 ranking, it has maintained an upward trend in the ranking, receiving higher scores than the previous year. In particular, in last year's evaluation, it entered the top 500 for the first time, with an increase of 18 points in industry-academic cooperation and more than 11 points in the research environment, and this year, it has risen slightly and maintained a stable top 500. This year, it recorded the highest score among the top 500 domestic universities, and it is expected to enter the top 500 in the future.The world's No. 1 ranking is Oxford University, which has maintained its No. 1 ranking for nine years since 2017. MIT, Harvard, and Princeton University ranked second, third and fourth, while Cambridge University maintained its ranking at fifth. In Korean universities, Seoul National University, KAIST, and Yonsei University ranked first, second and third, while Sungkyunkwan University made strides, climbing more than 40 notches. Konkuk University, Kyungpook National University, and Ulsan National University are among the top 500 universities, while Sogang University, University of Seoul, and Inha University remained at 801-1000.
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601
- 작성자OIA
- 작성일2024-11-12
- 11273
- 동영상동영상
