PNU researcher investigates left-tail momentum in the Korean stock market

The phenomenon is driven by investors overestimating the expected returns for stocks exhibiting large losses

Peer-Reviewed Publication

PUSAN NATIONAL UNIVERSITY

 

IMAGE: A NEW STUDY BY RESEARCHERS FROM KOREA IDENTIFIES TWO TYPES OF STOCKS WITH HIGH TAIL RISK—STOCKS WITH FREQUENT LARGE LOSSES (HIGH TAIL-FATNESS) AND THOSE WITH INFREQUENT BUT LARGE LOSSES (LOW TAIL-FATNESS). THE LTM PHENOMENON OCCURS DUE TO THE INVESTOR’S OVERCONFIDENCE IN THE LATTER STOCKS. view more 

CREDIT: PROFESSOR CHEOLJUN EOM FROM PUSAN NATIONAL UNIVERSITY

Left-tail risk (LT) stocks are those whose returns fall into the extreme end on the left side of the return distribution. In the hopes of mean-reverting to the normal price, investors usually hold on to these stocks. However, contrary to mean-reverting expectations, these stocks that have experienced extreme losses and high tail risks in the past tend to continue declining in the future, resulting in financial losses. This phenomenon, referred to as left-tail momentum (LTM), appears to challenge the traditional notion of a positive relationship between risk and return.

To investigate this market anomaly, a team of researchers, led by Prof. Eom from the School of Business at Pusan National University in South Korea, have recently re-verified the LTM phenomenon in the Korean stock markets through a cross-sectional comparison of all stocks by examining extreme risk situations. Their work was made available online on 10 February 2023 and published in Volume 87 of the International Review of Financial Analysis journal on 01 May 2023.

The researchers analyzed stock returns from July 2000 to June 2021 and standardized the distributions of these returns to cross-sectionally compare all stocks in the same criterion. By aligning the returns of all stocks within a predetermined threshold, they established a fair basis for comparing risks across different stocks. Their analysis revealed two types of LT stocks: those with fatter tails, reflecting higher tail risk and more frequent extreme losses, and those with thin tails, indicating relatively low tail risk and infrequent extreme losses.

The researchers then proceeded to investigate the LTM phenomenon within these groups by utilizing a measure called Value-at-Risk (VaR), which represents the boundary value associated with a specific probability in the distribution of stock returns. By utilizing VaR, they were able to assess the magnitude of potential financial losses, taking into consideration the tail-fatness property of the stock return distributions.

They found that the LTM phenomenon is not observed for all stocks that have experienced extreme losses in the past, but rather only for stocks with thin tails—stocks that have lower tail risk and have experienced extreme losses infrequently in the past. These results challenge previous assumptions, demonstrating that the LTM phenomenon does not contradict the conventional positive relationship between risk and return.

“If the fat tail property is viewed as a frequent occurrence of extreme losses, it can be interpreted as a high tail risk. Since LTM phenomenon was clearly observed only in stocks with a thin tail distribution, it is difficult to see it as evidence that violates the positive relationship between risk and return in traditional financial theory,” emphasize the researchers.

Overall, the research reveals that the LTM phenomenon is driven by investors overvaluing stocks with low left-tail risks compared to those with high left-tail risks. “This study looks forward to an interesting discourse in further studies investigating whether the LTM phenomenon that involves a low left-tail risk can be explained in terms of the risk–return trade-off relationship,” conclude the researchers.

 

***

 

Reference

 

DOI: https://doi.org/10.1016/j.irfa.2023.102570

 

About the institute
Pusan National University, located in Busan, South Korea, was founded in 1946, and is now the no. 1 national university of South Korea in research and educational competency. The multi-campus university also has other smaller campuses in Yangsan, Miryang, and Ami. The university prides itself on the principles of truth, freedom, and service, and has approximately 30,000 students, 1200 professors, and 750 faculty members. The university is composed of 14 colleges (schools) and one independent division, with 103 departments in all.

Website: https://www.pusan.ac.kr/eng/Main.do

 

About the authors
Cheoljun Eom is a professor at the School of Business at Pusan National University in South Korea. He was a postdoctoral researcher at Pohang University of Science and Technology (POSTECH) from 1999–2000, and worked in Hyundai Investment and Security Co. Ltd. as a manager from 2001–2002, where he developed the total asset allocation system. His research interests include asset pricing, portfolio optimization, financial econometrics, and econophysics. He has published more than 90 papers in the field of Finance and Interdisciplinary Science. After winning an award of 2009 Best Researcher in Pusan National University, he has received a few research excellence awards, and recently won the Korea Financial Investment Association Outstanding Paper Award at the 2023 joint conference with the Allied Korea Finance Associations.

Google Scholar website: https://scholar.google.com/citations?user=zEVhXPEAAAAJ&hl=en

ORCID id: 0000-0001-6362-9947

 

Yunsung Eom is a professor at the School of Business at Hansung University in Seoul, South Korea. He graduated from the Department of Fine Arts and the Department of Business Administration at Seoul National University and also obtained his master's and doctoral degrees in Finance there. He has conducted research as a visiting scholar at the University of Washington and the Economic Research Institute, Bank of Korea. His research interests include behavioral finance, market microstructure, investments, and algorithmic trading. His most cited research is “The disposition effect and investment performance in the futures market,” which is published in the Journal of Futures Markets in 2009.

Google Scholar website: https://scholar.google.com/citations?hl=en&user=M443k0EAAAAJ

 

Jong Won Park has been a professor of Finance at the College of Business at the University of Seoul since 2005. Before joining UOS, Professor Park was an assistant and associate professor at the College of Business at Cheju National University. He obtained his Ph.D. in Finance from Seoul National University in March 1995. His research interests focus on empirical asset pricing, market volatility, capital markets and anomalies, derivatives/risk management, retirement and public pension, corporate finance, market regulation, and macro-finance.

Google Scholar website: https://scholar.google.com/citations?hl=en&user=6qUbCb0AAAAJ&view_op=list_works&sortby=pubdate

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JOURNAL

International Review of Financial Analysis

DOI

10.1016/j.irfa.2023.102570 

METHOD OF RESEARCH

Data/statistical analysis

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Left-tail momentum and tail properties of return distributions: A case of Korea

 

A cool way to keep things cool: the electrocaloric effect

The electrocaloric effect (ECE) can be a key process to look into for giving current cooling systems a much-needed revamp, turning a necessary but harmful process into something more environmentally benign.

Peer-Reviewed Publication

TSINGHUA UNIVERSITY PRESS

 

IMAGE: HEAT IS PUMPED FROM A COLD LOAD, TC, TO A HEAT SINK, TH* TO COOL WITHOUT THE USE OF COMPRESSORS. view more 

CREDIT: Q.M. ZHANG, TSINGHUA UNIVERSITY

As necessary as cooling technologies are, we’re still operating on an outdated technology that can be considered a significant contributor to global warming and greenhouse gas emissions. Currently, vapor compression cycle-based cooling (VCC) is the standard for reliable cooling of air conditioning and refrigeration, but by switching to electrocaloric cooling (EC) researchers are hoping to create a more environmentally friendly, scalable and compressor-free method of cooling to benefit businesses, families and the environment.

 

The researchers published their work in iEnergy on June 29. The study highlights the electrocaloric effect (ECE) and how it can work to produce a cleaner, high-efficiency way of cooling without all of the harmful greenhouse gas emissions that a standard VCC process would add to the atmosphere.

 

The ECE can be explained as a reversible change of a dielectric material when it’s been exposed to a controlled change in the applied electric field. A dielectric material, like ceramic which is used in this study,  poorly conducts electricity but supports electrostatic fields, which is the catalyst for changing the polarization, or charge, of a field to induce the desired results of cooling. The reversible nature of this change allows for heat distribution and cooling to occur.

 

In order to have a large ECE the change in entropy needs to be sufficiently large, too. Entropy can be quantified as thermal energy that is ready to be made useful by converting it into mechanical work. This is where ferroelectric materials become advantageous to use. To have a high-efficiency product, the desired “operating window” where the largest change in the electrostatic field can be achieved, is just above the ferroelectric-paraelectric phase transition. Essentially, this transition phase consists of two oppositely “charged”  polarized fields, yielding the large change in entropy, or disorder, needed.

 

“These EC materials and device research reveals the promise of ferroelectric materials in generating giant ECE at low electric fields and EC cooling devices achieving high performance,” said Q.M. Zhang, first author and researcher of the study.

 

Simply put, the EC material used is heated past the temperature of the heat sink, and when the two materials make contact, a temperature equilibrium is reached; this is achieved by putting the energy into the field around the objects, not the objects themselves. By using ferroelectric materials a large ECE can be seen under relatively low electric fields which can achieve a  compressor-free system, lending to a cooling device that can be much more scalable to meet the needs of families and businesses alike.

 

“The electrocaloric cooling is attractive as an alternative to the VCC cooling. EC cooling is environmentally benign, compressor-free, highly scalable, and has the potential of achieving higher efficiency than VCC cooling” Zhang said.

 

While EC cooling is still being developed and researched as a practical way of cooling, a large portion of work that can be done on the EC coolers is developing lead-free materials, as currently the best-performing EC ceramics are lead-based. The lead-based ferroelectrics generate a higher amount of cooling in a shorter amount of time, but lead is a toxic substance, and generally, its use will not be well received by the public.

 

Another goal is to improve the thermal conductivity of the EC coolers. Since using lead isn’t the optimal choice, the performance of the ferroelectric component ideally would be improved to reduce heat loss and increase operating power. Achieving these goals and developing EC coolers that can be utilized in commercial and residential areas might aid in the global efforts to reduce greenhouse gas emissions and move forward with cleaner cooling technology.

 

Xin Chen of the Department of Materials Science and Engineering and the Materials Research Institute at Pennsylvania State University, Wenyi Zhu and Q.M. Zhang of the Materials Research Institute and Department of Electrical Engineering at Pennsylvania State University contribute to this research.

 

The U.S. Office of Naval Research supported this research.

 

##

 

About iEnergy 

 

iEnergy (Published by Tsinghua University Press), has multiple meanings, intelligent energy, innovation for energy, internet of energy, and electrical energy due to “i” is the symbol of current. iEnergy, publishing quarterly, is a cross disciplinary journal aimed at disseminating frontiers of technologies and solutions of power and energy. The journal publishes original research on exploring all aspects of power and energy, including any kind of technologies and applications from power generation, transmission, distribution, to conversion, utilization, and storage. iEnergy provides a platform for delivering cutting-edge advancements of sciences and technologies for the future-generation power and energy systems.

 

About Tsinghua University Press

 

Established in 1980, belonging to Tsinghua University, Tsinghua University Press (TUP) is a leading comprehensive higher education and professional publisher in China. Committed to building a top-level global cultural brand, after 42 years of development, TUP has established an outstanding managerial system and enterprise structure, and delivered multimedia and multi-dimensional publications covering books, audio, video, electronic products, journals and digital publications. In addition, TUP actively carries out its strategic transformation from educational publishing to content development and service for teaching & learning and was named First-class National Publisher for achieving remarkable results.

---

JOURNAL

iEnergy

DOI

10.23919/IEN.2023.0012 

ARTICLE TITLE

Electrocaloric cooling technologies for a sustainable world

 

Frozen Food Foundation presents Dr. Craig Hedberg with 2023 Freezing Research Award

Grant and Award Announcement

AMERICAN FROZEN FOOD INSTITUTE

Frozen Food Foundation Presents Dr. Craig Hedberg with 2023 Freezing Research Award

Toronto – The Frozen Food Foundation, in conjunction with the International Association for Food Protection (IAFP), presents Dr. Craig Hedberg, professor in the division of environmental health sciences at the University of Minnesota, with the fourteenth annual Frozen Food Foundation Freezing Research Award. Throughout his career, Dr. Hedberg has made several contributions to enhancing foodborne illness surveillance and applying the results to improve food safety. Dr. Hedberg has been a key contributor to many expert panels, including, but not limited to, an American Frozen Food Institute (AFFI) panel on current Listeria monocytogenes science.

The award, which recognizes individuals or organizations whose research contributes to the continued enhancement of food quality and safety through freezing, will be presented to Dr. Hedberg at the IAFP 2023 Annual Meeting in Toronto on July 19. IAFP has long presented awards to members of the research community for their work to enhance food safety. The Frozen Food Foundation Freezing Research Award is the only award presented at the IAFP Annual Meeting specifically for frozen food-related research.

Dr. Hedberg has contributed to a range of scientific research regarding the prevalence of pathogens in foods and implications for public health. In 2022 he co-authored research published in the International Journal of Food Microbiology which included a retrospective analysis of the prevalence and levels of L. monocytogenes in different food categories relative to their consumption patterns and attribution to listeriosis incidences. The researchers analyzed the impact of removing food products with varying levels of L. monocytogenes from commerce and demonstrated that establishing an allowable level in food could lead to improved public health outcomes.

“The Frozen Food Foundation is excited to recognize Dr. Hedberg for his significant role in advancing the field of research in foodborne illness and informing risk-based food safety and public health polices,” said Dr. Sanjay Gummalla, executive director of the Frozen Food Foundation. “Dr. Hedberg’s career dedication to foodborne disease surveillance has led to a greater understanding of the epidemiology of listeriosis and improving the safety of frozen foods, that can help advise future policy considerations.”

Dr. Hedberg has held multiple positions within the University of Minnesota School of Public Health since 1999. He also participated as a visiting scientist with the Public Health Agency of France from 2005-2006, where he evaluated the country’s Listeria surveillance systems. Prior to this, he served as a supervisor in the Minnesota Department of Health, where he helped establish surveillance of L. monocytogenes infections. Dr. Hedberg received the President’s Recognition Award from IAFP in 2022, among multiple professional recognitions throughout his career. He holds a Ph.D. in epidemiology and an M.Sc. in environmental health from the University of Minnesota.

About the Frozen Food Foundation

The Frozen Food Foundation exists to foster scientific research, public awareness and industry education regarding the nutritional, safety and societal attributes of frozen foods for the benefit of the common good. The Frozen Food Foundation is affiliated with the American Frozen Food Institute.

 

'Super premium' industrial motor that benefits both business and the environment

KERI achieves Korea's first IE4 class efficiency and establishes an open platform to spread technology

Business Announcement

NATIONAL RESEARCH COUNCIL OF SCIENCE & TECHNOLOGY

 

IMAGE: KERI'S RESEARCH TEAM (FROM LEFT, DRS. PILWAN HAN, DONGJUN KIM, AND JAEHAK CHOI) HAS DEVELOPED A SUPER-PREMIUM (IE4) CLASS INDUSTRIAL MOTOR AND ESTABLISHED AN OPEN PLATFORM FOR TECHNOLOGY DIFFUSION. view more 

CREDIT: KOREA ELECTROTECHNOLOGY RESEARCH INSTITUTE

After its successful development of industrial electric motors (three-phase induction motors) with super-premium class efficiency (IE4) for the first time in Korea, the Electric Machine and Drive Research Center of Korea Electrotechnology Research Institute (KERI) has established an "open platform" that enables SMEs to utilize related technologies.

Industrial motors are the machines that consume the most considerable amount of electricity in the world. Industrial motors account for more than 50% of total electricity consumption in Korea. In 2018, KERI published a report1) finding that increasing the efficiency of electric motors by just 3% would replace building 108 1GW nuclear power plants and save about KRW 34 trillion in value.
1) 'Special Report on the Development of High-Efficiency Electric Motors Worldwide' published by the working group A1.47 responsible for rotating generators and electric motors at the world's largest power industry technical organization (CIGRE). KERI's Dr. Dohyun Kang chaired the working group and led the publication.

Industrial motors' efficiency improvement is one of the most effective ways to save energy and reduce GHG emissions. Many countries are implementing policies to phase out low-efficiency motors, requiring more efficient ones and investing significant budgets in their development.

The International Electrotechnical Commission (IEC) categorizes electric motors according to international efficiency standards as standard effieicncy (IE1), high efficiency (IE2), premium (IE3), super premium (IE4), and ultra-premium (IE5). Korea has been taking action to mandate the production and sale of only IE3 motors in the industrial sector since 2018. However, some developed countries started regulations to promote IE4 class getting ahead of others.

KERI's achievement is developing the core source technology to increase the capacity of motors with a total of 15kW or less, accounting for 80% of domestic industrial motors, to IE4 level. Even IE3-class motors boast high efficiency as labeled as premium. To develop motors with higher efficiency than that, KERI's research team has developed IE4 class motors after years of research and development, which are 1-2 percentage points higher in efficiency than IE3 class motors and reduce energy loss by 20%.

However, not only efficiency improvement but cost reduction of material is also essential for developing IE4 class motors. While achieving high efficiency with expensive materials is easy, KERI focused on securing market competitiveness for domestic SMEs. To this end, KERI partnered with top research institutes in each field: the Korea Electronics Technology Institute for electric motors, the Korea Institute of Industrial Technology for production and manufacturing, and the Korea Institute of Materials Science for materials technology. KERI and partners' expertise has brought about a synergy effect to achieve high efficiency and price reduction.

The research team has established a web-based open platform (URL: iexdesign.com) to expand and apply IE4-class motors to industrial sites. Companies need a lot of R&D investment, experts' design skills, and expensive commercial import softwares to produce high-efficiency motors well. It has been a big huddle for small and medium-sized enterprises. Against this backdrop, KERI was able to provide an open platform at a lower cost by utilizing the design and open source-based analysis programs developed in partnership with the Korea Electronics Technology Institute and an engineering software company, Clew. During the project period (2019-2022), participating companies have shown excellent results, with increased annual sales of electric motors by more than 20% on average. It raises many expectations regarding the impact of the technology.

"An open platform to provide electric motor design, material utilization, and production process database will significantly lower the barriers for domestic companies to access IE4 industrial high-efficiency motor technology," said Dr. Pilwan Han of KERI. "Policy support and promotion are also needed to help domestic companies in need actively adopt IE4 high-efficiency motors to respond to the energy crisis."

The global industrial motor market is estimated at USD 68 billion in 2023. The domestic market is expected to reach USD 2 billion, with an annual growth rate of 7.9%. Korea is expected to implement IE4 class motor regulations by 2026 to achieve carbon neutrality, and many motor companies are expected to grow during this period.

With its publishment of 11 SCI(E) papers and application for 11 patents related to the technology, KERI aims to meet the demands of the times by developing IE4-class motors for medium and large capacities between 15kW and 200kW and developing variable-speed and non-rare-earth permanent magnet motors for IE5-class.

  

An open platform website developed by KERI to spread super premium (IE4) 

class industrial motors and technologies.

 

KERI's research team (from left, Drs. Pilwan Han, Dongjun Kim, and Jaehak Choi) has developed a super-premium (IE4) class industrial motor and established an open platform for technology diffusion.

CREDIT

Korea Electrotechnology Research Institute

This research was conducted under the project 'A Construction and Operation of Open Platform for Next-Generation Super Premium Efficiency (IE4) Motors' (May 2019 ~ Dec 2022). This project was supported through the 'Energy Demand Side Management Program' organized by the Korea Institute of Energy Technology Evaluation and Planning under the Ministry of Trade, Industry and Energy. Based on the support of the Korea Institute of Energy Technology Evaluation and Planning, KERI has been carrying out research to secure high-efficiency motor technology for SMEs, such as 'Premium-class high-efficiency induction motors', 'High-efficiency induction motors under the minimum efficiency regulation,' and 'Inverter-driven super-premium (IE4) synchronous reluctance motors.' <KERI>

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DOI

10.3390/app112411673 

 

New method for polyurethane synthesis using fluorine compound developed jointly by Kobe University and AGC Inc.

Peer-Reviewed Publication

KOBE UNIVERSITY

 

IMAGE: A NOVEL SYNTHETIC METHOD OF NON-ISOCYANATE POLYURETHANE (NIPU) view more 

CREDIT: TSUDA AKIHIKO

Main points

• A manufacture method of polyurethane not using isocyanate (a highly toxic raw material).
• Achieves an environmentally friendly polyurethane manufacture method not using either solvents or catalysts.
• By using a fluorinated carbonate jointly developed by Kobe University and AGC, enables the synthesis of a variety of polyurethanes from the conventional raw material of polyurethane in a safe, inexpensive, simple and environmentally friendly manner.
• This synthesis method exhibits utility and versatility and enables the synthesis of 12 types of general-purpose urethanes and one (special) type of fluorinated polyurethane.
• Because the polymerization reaction proceeds at a lower temperature than the non-isocyanate methods reported to date, a high-quality polyurethane is obtained which is highly transparent without discoloration and has high strength and high elasticity (a high molecular weight having a regular structure).
• The fluorinated alcohol which is the only byproduct can be recovered and can be reconverted to fluorinated carbonate in the photo-on-demand organic synthesis method.
• This is a novel and very useful synthesis method enabling the replacement of several of the current isocyanate methods and contributes to implementing a sustainable society.
• This is an example of the success of university-industry cooperation between Kobe University and AGC, which was in receipt of support from the JST A-STEP* cultivating success (2018 – 2021) program
   (*Adaptable and Seamless Technology Transfer Program through target-driven R&D)

Background of the research

Polyurethane is highly elastic, wear resistant and durable, and is used, for example, in cushions, fibers, thermal insulation materials, dyes, adhesives and automobile parts. Polyurethane is an industrially-important polymer material, with an estimated worldwide market value of 75 billion dollars (2023 Grand View Research Inc. investigation). Most polyurethane is currently synthesized by means of reacting diisocyanate with diol (FIG. 1, reaction (a)). However, isocyanate compounds are highly toxic, and the tightening of regulations on the use of diisocyanate are progressing recently, particularly in the EU, because of health and environmental concerns. In recent years, active research is proceeding into the synthesis of polyurethane without using isocyanate compounds with a view to implementing a sustainable society. However, most of current methods have low utility, high environmental costs, and the quality of the derived polyurethane is low as well as being expensive, and are not practicable because of the variety of problems associated with them.

In this background, Kobe University Associate Professor Tsuda and AGC, with the support of funding from the JST A-STEP program, combined their efforts to jointly develop a novel polyurethane synthesis method (FIG. 1, reaction (b)). University-industry cooperation between the research group of Associate Professor Tsuda, pioneers of the Photo-on-demand organic synthesis method (http://www2.kobe-u.ac.jp/~akihiko/index.html）and AGC, a manufacturer of fluorinated compounds and polyurethane raw materials, created a new academic field and industrial activity based on the development of a new polyurethane synthesis method and functional materials.

Content of the research

A variety of fluorinated biscarbonates (BFBC) were synthesized (FIG. 2) by a condensation reaction of fluorinated carbonates, synthesized in the photo-on-demand synthesis method from fluorinated alcohols and chloroform, with diols. The BFBC generated could be purified by merely drying the derived sample solution at reduced pressure, enabling the quantitative derivation of the target substance by a simple operation.

The synthesis of a non-isocyanate polyurethane (NIPU) with an average molecular weight in excess of 10,000 was achieved by polycondensation of the derived BFBC with diamine. The NIPU synthesized without solvent was only slightly discolored at over 120°C, and that discoloration was not observed up to 100°C. On the other hand, if a solvent is used, it can be polymerized at a lower temperature, and a high molecular weight colorless NIPU is derived at a high-yield. They were able to form a highly-elastic colorless and transparent polyurethane by an appropriate combination of BFBC and diamines in hard and soft segments (FIG. 3, Reactions (1) and (2)). They also succeeded in synthesizing a novel fluorinated polyurethane which is a colorless transparent oil (FIG. 3, Reaction (3)).

The variety and types of polyurethane synthesized, with a range from general purpose to specific applications, have the following benefits when compared to the previously reported synthesis methods of NIPU:

1. Any NIPU can be synthesized which employs commercially available diols or diamines employed in the industrial manufacture of polyurethane by the isocyanate method, or which was originally used in the synthesis of NIPU.
2. This is a synthesis method which does not use organic bases, metallic catalysts or solvents in the synthesis, such that a high quality NIPU can be derived which does not contain any of them.
3. The average molecular weight and terminal functional groups can be controlled by the admixture ratio of BFBC and the diamines. An NIPU prepared by this method with the molecular weight of the order of 10,000 can be employed as a prepolymer in order to synthesize even larger polymers or networked polymers.
4. The reagents, solvents and eliminated fluoroalkyl alcohols can basically be recovered, and be re-utilized in the synthesis of these NIPU.

Future perspectives

The conventional polyurethane synthesis method using isocyanate has advantages from a cost perspective. However, the novel and useful non-isocyanate polyurethane (NIPU) synthesis method using these newly developed fluorinated carbonates and fluorinated biscarbonates can replace several conventional methods with a view to implementing a sustainable society, in addition to enabling the creation of functional polyurethanes which conventional methods cannot synthesize. Research is proceeding at present, both from an academic and industrial perspective, with a view to bringing this process to market.

  

Examples of Synthesizing Non-Isocyanate Polyurethanes (NIPUs) Reported in This Study

Synthesis of Fluorinated Biscarbonates (BFBC)

Examples of Synthesizing Non-Isocyanate Polyurethanes (NIPUs) Reported in This Study

CREDIT

TSUDA Akihiko

Acknowledgements

This research was in receipt of funding support from the Japan Science and Technology Agency (JST) Adaptable and Seamless Technology Transfer Program through Target-driven R&D (A-STEP), University-industry Cooperative phase results promotion research topic: "The development of high-functionality/high-added-value polyurethane materials by means of a safe manufacture process involving the inclusion of fluorinated carbonates as a key intermediate" (Project name: AGC Inc., Project representative:Takashi Okazoe, Research Representative: Akihiko Tsuda)

Patent Information

Title of the patent: Manufacture method of polyurethane
Japanese Patent Application: JP2020-83148, Patent Application date: May 11, 2020
International Patent Application：PCT/JP2021/17511, Patent Application date: May 7, 2021
Laid-open publication：WO 2021/230151 A1 [Nov. 18, 2021]
Inventors: TSUDA Akihiko, OKAZOE Takashi, WADA Hiroshi, TANAKA Hideaki, SUNAYAMA Yoshitaka, KAKIUCHI Toshifumi
Patent Applicants: Kobe University and AGC Inc.

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JOURNAL

Bulletin of the Chemical Society of Japan

DOI

10.1246/bcsj.20230066 

METHOD OF RESEARCH

Data/statistical analysis

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Non-Isocyanate Polyurethane Synthesis by Polycondensation of Alkylene and Arylene Bis(fluoroalkyl) Bis(carbonate)s with Diamines

ARTICLE PUBLICATION DATE

21-Jul-2023

 

Digital pathology set to be a game changer in the medical industry

Business Announcement

UNIVERSITY OF QUEENSLAND

 

IMAGE: PROFESSOR BRIAN LOVELL WITH A DIGITAL MICROSCOPE SCANNER view more 

CREDIT: THE UNIVERSITY OF QUEENSLAND

Patients will receive faster and more accurate pathology results following a decade-long research project that is set to transform medical diagnosis.

The University of Queensland and Sullivan Nicolaides Pathology (SNP) have automated a microscope scanning and analysis system in Brisbane that has been tested, implemented and accredited ready for rollout around the world.

UQ Professor of AI Brian Lovell said the system significantly improved tests in terms of cost, quality and speed.

“This digital pathology technology processes thousands of tests a day and has been accredited by the National Association of Testing Authorities (NATA),” Professor Lovell said.

“At times the system can increase the productivity of pathologists and scientists by factors of 10 or more.

“The system also provides the ability to obtain second opinions via telepathology and dramatically improves record keeping and access of historical records, as the glass slides are no longer needed to be archived for years.”

SNP Chief Executive Officer Dr Michael Harrison said the technology is a game changer in many areas of healthcare.

“SNP laboratories in Brisbane are already using the system to improve the speed and accuracy of diagnoses,” Dr Harrison said.

“Our scientists now use a digitised image often with associated AI instead of being tied to a microscope for many hours.”

“This is the most significant change in the performance of morphological tests for decades.”

Professor Lovell said there had previously been major problems with obtaining sharp, in-focus images with no human intervention.

“Digital pathology images are often thousands of times larger than typical digital photos,” he said.

“This had meant microscopy for diagnosing from tissue, blood and other specimen types was unable to be automated until now.

“Our active scanner knows what it is scanning and where it should scan, using image analysis and artificial intelligence.

“This greatly increases image quality and reduces file size.”

CEO of UQ commercialisation company UniQuest, Dr Dean Moss, said the technology demonstrated the benefits of industry collaboration with innovative researchers.

“It’s exciting to see the advancement of a project that promises to have a transformative impact on better health outcomes,” Dr Moss said.

This research is supported by SNP, two Australian Research Council projects, and an Advance Queensland Fellowship from the Queensland Government.

Interviews, B-roll and images available here.

\METHOD OF RESEARCH

News article

SUBJECT OF RESEARCH

Not applicable