Month: March 2021

Fashion is a vibrant player in popular culture. With many things tied up in it – cultural and socioeconomic identities, for example – fashion is as important to a country’s social well-being as it is to the economy. Tapping into the creative passions of its students, sharpening their communication and organization skills along the way, is Management and Science University (MSU) via the MSU Global Leadership Programme (GLP) to UEDA College of Fashion in Osaka, Japan.

The annual UEDA GAKUEN Fashion Show has seen participation by MSU’s School of Hospitality and Creative Arts (SHCA) since 2018. This year’s UEDA GAKUEN Collection Showcase by MSU saw second-year students Siti Nur Azreen Mohd Nazri, Sofea Izlyn Shahaniza, Ameera Syazlyn Mohamad Zaki, and Nur Shahzanna Shahrun – all from the Bachelor in Fashion Design with Marketing (Hons) programme – joined by final-year students Zahirah Zulkhairi and Izyan Naqiah Abdullah Md Shahrin from the Diploma in Fashion Design programme, on the virtual 146^th UEDA GAKUEN runway.

Inspiration for the 2021 fashion collection came from none other than Malaysia’s own heritage treasures, with food and animation taking centre-stage. Extending the show’s theme into a concurrent virtual exhibition were final-year students Fitri Malinda Mohamad Shahrul and Wan Nur Izzah Aiman Wan Efendi from the Diploma in Fashion Design programme; as well as An-Nur Hazeeqah Mahfuzah Husain and Siti Fatimah Ahmad Zulkifle, both second-year students on the Bachelor in Fashion Design with Marketing (Hons) programme.

The compelling learning experience, with its on-the-job artistic training in the world of couture and honing of skills transferable to industries beyond fashion, was provided by the Fashion Design Realization course common to the 3.5-year Bachelor in Fashion Design with Marketing (Hons) and the 2.5-year Diploma in Fashion Design programmes at Management and Science University (MSU).

The MSU Global Leadership Programme (GLP) is one of three open to all students of the  University; the other two being the MSU Global Mobility Programme (GMP) and the MSU Global Internship Programme (GIP).

Russian city of St. Petersburg is at the frontlines of this ongoing war with Covid-19. To combat this situation effectively, the Russian government allocated significant funds for the research. Now, scientists from Peter the Great St.Petersburg Polytechnic University (SPbPU) have modified the existing SIR (Susceptible – Infected – Recovered) class pandemic prediction model.

The existing SIR class of models is widely known. There are many modifications to the SIR model. One of them is SEIR (Susceptible – Exposed – Infected – Recovered)

The SEIR model was taken as a basis and then expanded to include another group- individuals in isolation or quarantine. That was the modification.

This modification of the SEIR model allows the number of susceptible individuals available for infection during modelling to be adjusted according to isolation scenarios (i.e., measures designed to prevent susceptible people from becoming infected).

This means the model becomes more accurate, as the reduction of individuals in contact during the pandemic is objectively present in society. Moreover, the modification creates the possibility for scenario modelling.

Scenario modelling involves assessing the epidemiological consequences of various strategies for countering the spread of an infectious disease in a given region.

This model has been tested on data from St.Petersburg. A set of six experiments was sufficient to assess the impact of quarantine measures. The initial data for each experiment include isolated industries that indicate the timing of the introduction and lifting of isolation measures.

The results of this first group demonstrate that the dynamics of the virus’ spread have a nonlinear dependence on the number of workers employed in the isolated sectors of the economy. For example, the isolation of three economic sectors, which make up approximately 42% of the total number of workers, reduces the peak number of infected people by 6.2 times and the total number of patients by 4.83 times.

Isolation of six sectors of the economy, accounting for 80% of the total number of workers, reduces the peak number of infected people by 75 times and the total number of recovered individuals by 56 times”.

The results of the second group show that the introduction of measures to isolate the economy and public life in the early stages of virus’ spread can reduce the incidence of the disease and bring an earlier end to the pandemic. Conversely, the late introduction of isolation measures affects the dynamics of the disease’s spread to a lesser extent.

These results support assessments made by leading epidemiologists. These results indicate that the optimal disease-countering strategy is total isolation as early as possible.

This modified version of the SEIR model can be used to develop strategies for countering the spread of infectious diseases. It also enables researchers to assess the possible mortality in each case as a proportion of the total infected and recovered population.

The article develops a methodological apparatus of a SIR-class model for practical use in decision-making by regional leaders.

A courtesy call comprising the Director of Endowment Unit, Dr Aruan Effendy Mohd Ghazali and Ts. Elmi Alif Azmi, Head of Administration, Data, Strategy and Quality to Yayasan Kebajikan Aras (Aras Welfare Foundation-AWF) at Menara KL Eco City in Kuala Lumpur on 19 February 2021 was an actual follow up to the MoU that had been signed earlier between UiTM and AWF. The two organisations had agreed on a joint effort in providing quality education to excellent and determined UiTM students to continue their studies and maintain outstanding academic performance.

During the visit, the Universiti Teknologi MARA (UiTM) delegation received an amount of RM125,000.00 from Aras Welfare Foundation’s (AWF) Financial Advisor, Dr Juliawati Janius. It was the first in a series of disbursement amounting to a total of RM5 million donation pledged to UiTM Endowment Fund.

In a concluding statement of the visit, Dr Aruan Effendy Mohd Ghazali reiterated, “We would like to extend our sincere thanks and appreciation to Aras Charity Foundation for the donation. The money we receive will fortify the plans and initiatives developed by UiTM Endowment Fund towards enhancing the quality of education, students and graduates of tomorrow who will soon serve the nation”.

The collaboration between Universiti Teknologi MARA (UiTM) and Aras Charity Foundation (AWF) was formalised on 28th December 2020 at UiTM Hotel Shah Alam. Representing UiTM was Emeritus Professor Datuk Ir. Dr. Mohd Azraai Kassim, Vice-Chancellor of UiTM while Mr Afique Rahman Azizul Rahman, Director signed on behalf of Aras Charity Foundation with the Director of Endowment Unit and AWF Financial Advisor acting as witnesses.

The MoU’s intent was to strengthen the financial support through the AWF-UiTM Endowment Fund; specifically dedicated to education scholarship which covers tuition fee as well as cost of living allowance awarded to successful recipients pursuing bachelor’s degree programmes and identified as coming from low-income or poor families.

With this collaboration and support given by Aras Welfare Foundation, it is hoped that UiTM Endowment Fund will continue to uphold the national higher education aspirations through continuous engagements with the community as well as industry in its plans and initiatives.

The 18th annual Urban Research Plaza Forum will be held on 8-9 March 2021. Hosted by Chulalongkorn University‘s Faculty of Fine & Applied Arts (FAA), the Forum is a collaboration between FAA and Osaka City University.

Professor Dr Shin Nakagawa and FAA Dean, Professor Dr Bussakorn Binson are the co-directors of the Urban Research Plaza. This year’s forum is being held under the twin themes of “Saving Our Urban Habitat – Creating A Sustainable Future” and “Arts and Cultural Activities with COVID-19”.

Research papers presented at the forum include a wide range of topics focused on creating sustainability in an urban context and art and cultural activities during the Covid-19 pandemic crisis. The forum is open to the public via a conference link and visitors need to register to attend online.

Modern electronics is approaching the limit of its capabilities, which are determined by the fundamental laws of physics. Therefore, the use of classical materials, for example, silicon, is no longer able to meet the requirements for energy efficiency of the devices. Currently, it is necessary to start searching for new materials, new principles of electronic devices’ functioning.

To solve this problem, researchers of Peter the Great St.Petersburg Polytechnic University (SPbPU) are developing thin films, the elements for biomolecular electronics. Scientists believe that biological macromolecules such as nucleic acids, proteins, amino acids can become a promising material for modern electronics. It obtains several unique properties, for example, the self-organization ability, which is why the molecules can be assembled into certain structures, for example, into biomolecular films.

“Our scientific group is investigating various properties of thin films based on the albumin protein. In the course of experiments, we dilute the protein in various concentrations and use the method of isothermal dehydration (water evaporation at a certain temperature and pressure) to form the biomolecular films. Depending on the composition of the initial samples and drying parameters, we obtain different structures inside the films, ” notes Maxim Baranov, an assistant at the Higher School of Applied Physics and Space Technologies SPbPU.

Using an optical microscope, the scientists fixed the structures inside the dried albumin proteins, and also developed software in Python, which can isolate and analyze images of biomolecular films with a help of the special mathematical apparatus. Molecular modeling for solving this problem is carried out at the facilities of the Supercomputer Center “Polytechnic”. The research results were published in the first quartile journal Symmetry by MDPI.

Maxim Baranov adds, “Semiconductor integrated circuits, which are currently used in electronic devices, have a stationary configuration. In turn, the functioning of proteins is based on dynamics, i.e. a biological system can transform in the process of interaction with other objects. Therefore, the molecules can perfectly repeat the required structure, for example as in integrated circuits. However, we expect a lower number of defects in the biomolecular thin films.”

“We can’t say that the biomolecular platform will completely replace the classic semiconductor devices. Rather, we are talking about its symbiosis. Our scientific group believes that thin films will be introduced not in the mass market of electronics, but rather in single applications.

According to scientists, various types of proteins can be used for further research, including plant proteins. Perhaps in the future, it will simplify the creation of biomolecular thin films. Currently, it is necessary to create a certain set of mathematical parameters for a more accurate description of the thin films and their properties. A large number of experiments will be carried out before a prototype of the element is created, which could be implemented into the future device.

Students from the Bachelor of Arts Program in Service Innovation (BSI) College of Innovation, Thammasat University, have developed an application for businesses to help them get through COVID-19.

The aim is to help businesses by developing an AI application to cope with the reduction of sales and traffic to their stores. Businesses can create an omni-channel and seamless distribution channel that is convenient, clean, and safe to target groups and also sell their products and services as usual. Assistant Professor Dr Arsa Tangjitsomkit has supervised  project.

The application is ready and available for download to be used with companies and organizations such as Baan Kanyapat Foundation, Guss Damn Good, SOS-SENSE OF STYLE, Baimiang Retail Co.Ltd., Rod Dee Ded, Home Service by GK Home, and Krua Pruk Sa by Khun Jeaw.

In the mid-2020, the European Commission published “A Hydrogen Strategy for a Climate-Neutral Europe.” The Brussels-based institution hopes it will be hydrogen alongside renewables that enable the European countries to build a low-carbon economy and consequently minimise environmental pollution.

It is expected that the generating capacity of electrolysers across the EU will have surpassed 40 gigawatts by 2030, which is a little less than 4% of the total power generation of 2018. The same amount of energy will be imported from Russia and elsewhere in the world.

Some analysts say that Russia should backdoor its way into the hydrogen industry, design process trains and start exporting nature’s lightest gas. It may seem reasonable as, according to supporters of green energy, hydrocarbons will soon be of no use. Provided it happens, the Russian economy, overly dependent on oil & gas revenues, will be in a deep decline; unless we succeed in reorienting it to producing hydrogen. 

Yet there is another opinion. Experts with profound knowledge of hydrogen solutions claim that the existing technologies – be it electrolysis or production from methane – are too costly to consider the gas a future global energy source. Neither households nor business consumers will manage to pay that much for electricity. Besides, it is not really clear how this explosive gas should be stored and transported.

The pipeline system currently in use will not suffice. Unlike methane, hydrogen is more reactive and will cause significant damage, primarily to weld joints and areas around them.

About 85 million tons of hydrogen are consumed worldwide, mostly by the oil refining and chemical industries. In comparison, the demand on the part of the energy and transport sectors is low. Although cars, buses, and trains running on hydrogen fuel are no longer something totally unheard of, for now, they are only prototypes. These test models will not be manufactured on an industrial scale either – it is too expensive.

Meanwhile, less global projects have some potential. For instance, Russian scientists are working on new train models, which will operate on fuel hydrogen cells. Such trains may have demand in places lacking the infrastructure to transmit electricity and subsequently replace diesel-powered locomotives.

“We believe that hydrogen won’t become a global source of energy. However, it may be one of the tools that humankind needs to solve environmental problems. Our civilisation is facing a serious challenge – we must significantly reduce the anthropogenic burden on nature but remain committed to sustainable development,” says Georgy Buslaev, Head of the Arctic Competence Centre in St. Petersburg Mining University.

“Through research, we aim to learn how to achieve both goals simultaneously. One of our research areas is related to improving technologies for hydrogen production, storage, and transportation.”

“These studies are being conducted with grants provided by Hazret Sovmen. He is a business investor who had literally revolutionised the gold-mining industry long before his presidential term in the Republic of Adygea began. This man knows that science is the driver of Russia’s socio-economic progress. Fostering science requires encouraging young researchers to focus on academic pursuits,” adds Buslaev.

Buslaev notes that many Western-European policymakers state that complete abandonment of oil and natural gas consumption is a prerequisite for reaching carbon neutrality. This is not a realistic task, though; it will take decades before green technologies can fully replace fossil fuels as the foundation of national economies.

It may even happen as late as at the end of the 21st century. Hence, scientists looking for alternatives to hydrocarbons should also look for ways to reduce harmful emissions from the extraction, transportation, and use of hydrocarbon fuels.

One of the most acute environmental issues attributable to the fuel & energy sector arises from the flaring of associated petroleum gas (APG). It is a gas by-product that is released when oil is being pumped out of a well. Earlier anywhere around the world, the gas was burnt off in flares, leading to the emissions of CO2 and other hazardous substances. The situation has been changing now, but the negative environmental impact is still very high.

As surprising as it seems but exporting hydrogen, or more specifically, its derivatives, can make the difference. One of the possible solutions is being elaborated by the Mining University’s researchers. They are involved in modelling process chains based on capturing APG at the polar oil fields and transporting it to gas chemical facilities situated near the Northern Sea Route. Therein the gas is transformed into some kind of a semi-product for producing hydrogen. 

“Storing and transporting hydrogen is an ambitious task that requires breakthrough scientific solutions. Letting it flow via an existing pipeline just won’t work because the hydrogen molecule is so small it can permeate the crystal lattice of steel. Making any guesses on how long a pipeline transferring hydrogen will last isn’t really useful accordingly. In contrast, technologies for transporting bound hydrogen look much more promising,” explains Buslaev.

“I am talking here about shipping natural and, for that matter, associated gases to a gas chemical complex to synthesise methanol, ammonia, and cyclohexane. If they are then brought in to a storage & handling facility by tanker, they can be further used to produce hydrogen and other valuable components. By implementing a project of this kind, we will significantly reduce carbon emissions caused by hydrocarbon extraction. We will also ensure that both European and Asian consumers are provided with an in-demand energy carrier,” adds Buslaev.

The university’s research team aims to adapt extraction in the Arctic to what low-carbon energy requires yet produce high-margin goods, helping build a new economy. It does not mean that Arctic oil and gas will be abandoned altogether. Still, the share of primary raw materials in Russia’s export profile should be decreasing, with high-added-value products taking over eventually. Hydrogen derivatives may be one way to achieve this goal, thereby minimising man’s impact on the environment and increasing budget revenues.

“We definitely don’t have to give up on oil & gas production, on which some Western decision-makers insist. Demand for hydrocarbons will keep growing, with most of the growth ensured by Asian consumers. Hydrogen won’t ever wholly replace them; however, stricter rules are coming into play on the global markets. We need to take that into account. One area for improvement is developing renewable technologies in regions where the climate favours doing so. In this connection, hydrogen can actually prove itself quite useful.

As is known, the main disadvantage of wind turbines and solar panels, which drastically limits their potential, is the lack of affordable technology for accumulating energy on an industrial scale. Furthermore, current storage systems are highly susceptible to low atmospheric temperatures, making them, as a result, hard to use. By producing hydrogen from surpluses of flow energy, we will partially solve the problem of energy accumulation,” continues Georgy Buslaev.

Last December, Vladimir Putin declared that the country’s future is directly linked to the Arctic and its development and particularly emphasised the role of mineral extraction in the region. Gazprom Neft intends to raise its total production output coming from the polar region to 30% in the foreseeable future already. Rosneft and Novatek are also heavily investing in the projects in that area, specifically in infrastructure construction.

In the next 10 to 15 years, Russia’s Far North will doubtlessly turn into a region generating a significant part of the country’s incomes. The practical challenge to be solved by business and scientific communities is how to manufacture marketable products and lower the carbon footprint at the same time. One of the tools to accomplish this goal is undoubtedly hydrogen technologies. That said, it is unlikely they will ever become a source of much importance to the global energy industry. The gas is too expensive to produce, corrosive to metals, and most importantly, highly flammable. Whether science will find a way to offset these significant drawbacks and when, if it ever will, is, for now, an open question. 

The Academy of Language Studies, Universiti Teknologi MARA, Cawangan Pulau Pinang (UiTMCPP) organised the International Workshop, Seminar & Innovations (IWSI) with the theme Japanese Meet Malays: When Languages and Cultures Dance Together virtually on 27 January 2021.

The webinar commenced with an uplifting speech on Colours of Language by Professor Ts. Dr Salmiah Kasolang, the rector of UiTMCPP and the president of the Malaysian Tribology Society (MYTRIBOS) who touched on diverse Malay and Japanese cultural aspects while stressing that language is knowledge, and it adds colours to human lives.

Your Excellency Mr Kanoya Shinichiro from Consulate-general of Japan in Penang proceeded to feature numerous aspects of Japan including its regions, initiatives implementation in Japan, cultural project collaborations to introduce Japan in Malaysia, and tertiary education opportunities for Malaysians in Japan.

The following panellist, Professor Dr Kanao from the Department of Mechanical Precision Engineering, Malaysia-Japan International Institute of Technology, Universiti Teknologi Malaysia who is also a Guest Professor at Kyushu University, Japan shared his insightful perspectives in terms of engineering and cultural aspects in Malaysia and Japan as well as collaboration through shared expertise, and knowledge sharing between Malaysia and Japan towards a prosperous society.

Professor Ir. Dr Syahrullail Samion from the Department of Thermofluids, Faculty of Engineering, Universiti Teknologi Malaysia who completed his undergraduate and post-graduate studies in Japan mentioned fascinating similarities and differences between Malay and Japanese languages in terms of sentence structure, meaning, content and context. The senpai and kōhai mentor system at education and work levels, and the simplicity elements in technology and work culture were also discussed.

Ts. Dr Nik Roselina Nik Roseley from the Faculty of Mechanical Engineering, Universiti Teknologi MARA Shah Alam shared her personal experience of being an undergraduate at Kobe University, Japan by describing the cultural environment, Kansai dialect, Japanese waste disposal system, Malay and Japanese cultural activities, and part-time job experience in Kobe, Japan.

The final panellist, Dr Rofiza Aboo Bakar from the Academy of Language Studies, UiTMCPP who participated in the Youth Exchange Programme in Katsushika, Tokyo in 2003 focused on the remarkable origins, characteristics, and close affinities between Malays and Japanese in exploring their languages and cultures.

The webinar ended with a question-and-answer session by the moderators, Ms Marni Jamil and Ms Jihan Johari from UiTMCPP.

The afternoon session proceeded with three interactive online segments on Malay and Japanese cultures as Ms Emi Yamazaki, the President of the Pink Hibiscus Club awed the participants with an easy-to-follow Yukata demonstration, which was followed by Kanji (Japanese calligraphy) and Haiku vs Pantun competitions hosted by the committee.

IWSI reached more than 3000 views and it has established educational and social connections between academicians and non-academicians across languages and cultures besides uplifting the spirit of collaboration through global exposure in the borderless world.

Management and Science University (MSU) has become the first university ever in Malaysia to initiate a comprehensive collaboration with Malaysia’s Fire and Rescue Department (JBPM) in combatting COVID-19.

The University ran the MSU Public Sanitization Campaign on February 26, there days ahead of its students returning to campus beginning March 1.

Such proactivity indicates a high commitment to ensuring health and safety for all, said JPBM Director YS PKPjB Norazam Khamis; who led two teams of a combined twenty from the Shah Alam Section 15 and the Kota Anggerik stations carrying out disinfection of MSU’s U-Plaza, U-Concourse, The Hub, Cinnamon Café, Library and Resource Centre, and lecture halls.

MSU President, Professor Tan Sri Dato’ Wira Dr Mohd Shukri Ab Yajid, said that committing to health and safety on campus is crucial to ensuring uninterrupted continuity and quality in the University’s teaching and learning through the blended mode of delivery.

Such a commitment has led MSU to offer the University’s private specialist hospital MSU Medical Centre (MSUMC) as a future vaccine centre.

Situated adjacent to the MSU main campus in Shah Alam Section 13 and the University’s student accommodation The Residence, MSUMC is the first hospital in Malaysia purpose built by a private university.

Image caption: This photo shows the possible mechanism of increased homology-directed repair efficiency and suppression of off-target effects by controlled activation of CRISPR-Cas9 depending on the cell cycle phase.

This story was first published on the Hiroshima University website.