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Month: June 2021

BSBI featured in United Nations publication

Posted on by Global University Systems

Berlin School of Business and Innovation (BSBI) is proud to announce that Professor Dr Kyriakos Kouveliotis, Provost and Chief Academic Officer at BSBI, was recently featured in the UN Chronicle, the publication of the United Nations.

The UN Chronicle, produced by the United Nations Department of Global Communications, has served as the Organization’s flagship platform since 1946, providing authoritative information and debate on the activities of the larger United Nations system. The now digital publication continues to feature authoritative articles from a wide range of international experts and stakeholders.

Professor Kouveliotis contributed with an article outlining the idea of the ‘Global Degree’, the proposal for a new institutional model for higher education. He said: “The Global Degree was conceived to fill a gap in international higher education, developing a concise and innovative system blending conventional and distance learning without abolishing existing structures.

“This concept aims to acknowledge that learning has evolved alongside technology and international mobility, whilst devising a new approach to deliver a truly global education experience reflecting on the themes of accessibility and inclusion.”

Committed to this approach, BSBI has recently announced new partnerships to offer students a multi-city, global education experience between Germany, France and Greece. Starting from September 2021, students will have the opportunity to enrol in a selection of courses awarded by BSBI’s academic partners, the University for the Creative Arts (UCA), International Telematic University UNINETTUNO and Concordia University Chicago (CUC), whilst studying in prestigious locations in Europe.

Working with PPA Business School in Paris and Independent Studies of Science & Technology College (IST) in Athens, BSBI will allow students to study in either France or Greece’s capital, then concluding their studies in at BSBI in Berlin.

Professor Kouveliotis said: “We are excited to launch this new project, taking studying abroad to a new level. Working with these amazing partners we aim to broaden our students’ cultural and knowledge exchange, whilst maintaining the excellent standards of education and student services our partners strive to deliver.”

BSBI launched in 2018 with bachelor’s and master’s degrees in business administration, tourism hospitality, events management, marketing and finance. Over recent years, the institution has expanded its portfolio through partnerships with universities in the UK and North America, as well as developing initiatives and services to accompany students during and after their studies.

“Our institution has its roots in Germany, but we’ve always looked to provide a worldwide learning experience, in line with the concept of the Global Degree. This is the brand of education BSBI believes in and wishes to implement,” Professor Kouveliotis added.

Scientists find a way to use visible light to decompose CO2 with high efficiency

Posted on by NITech

To tackle the challenge of global warming, scientists have been looking into green and sustainable methods of breaking down carbon dioxide in emissions and in the atmosphere. Now, a group of researchers from Nagoya Institute of Technology, Japan, have developed a novel, easy to synthesize composite compound that enables the efficient use of solar energy to reduce carbon dioxide, taking us one step closer to achieving a green economy.

A team of scientists led by Drs. Shinji Kawasaki and Yosuke Ishii from Nagoya Institute of Technology, Japan, has been at the forefront of efforts to achieve efficient solar-energy-assisted CO2 reduction. Their recent breakthrough is published in Nature’s Scientific
Reports.

Their research began with the need to solve the limited applicability problem of silver iodate (AgIO3), a photocatalyst that has attracted considerable attention for being useful for the CO2 reduction reaction. The problem is that AgIO3 needs much higher energy than that which visible light can provide to function as an efficient photocatalyst, and visible light is the majority of solar
radiation.

Scientists have attempted to work around this efficiency problem by combining AgIO3 with
silver iodide (AgI), which can efficiently absorb and utilize visible light. However, AgIO3–AgI composites have complicated synthesis processes, making their large-scale manufacturing impractical. Further, they don’t have structures that offer efficient pathways for the transfer of photoexcited electrons (electrons energized by light absorption) from AgI to AgIO3, which is key to the composite’s catalytic activity.

“We have now developed a new photocatalyst that incorporates single-walled carbon nanotubes (SWCNTs) with AgIO3 and AgI to form a three-component composite catalyst,” says Dr. Kawasaki, “The role of the SWCNTs is multimodal. It solves both the synthesis and
the electron transfer pathway problems.”

The three-component composite’s synthesis process is simple and involves just two steps: 1. Encapsulating iodine molecules within the SWCNT using an electrochemical oxidation method; and 2. Preparing the composite by immersing the resultant of the previous step in an aqueous solution of silver nitrate (AgNO3).

Spectroscopic observations using the composite showed that during the synthesis process, the encapsulated iodine molecules received charge from the SWCNT and converted into specific ions. These then reacted with AgNO3 to form AgI and AgIO3 microcrystals, which, due to the initial positions of the encapsulated iodine molecules, were deposited on all the SWCNTs uniformly. Experimental analysis with simulated solar light revealed that the SWCNTs also acted as the conductive pathway through which photoexcited electrons moved from AgI to AgIO3,  enabling the efficient reduction of CO2
to carbon monoxide (CO).

The incorporation of SWCNTs also allowed for the composite dispersion to be easily spray-coated on a thin film polymer to yield flexible photocatalytic electrodes that are versatile and can be used in various applications.

Dr Ishii is hopeful about their photocatalyst’s potential. “It can make the solar reduction of industrial CO2 emissions and atmospheric CO2 an easy-to-scale and sustainable renewable energy-based solution tackling global warming and climate change, making people’s lives safer and healthier,” he says.

The next step, the team says, is to explore the possibility of using their photocatalyst for solar hydrogen generation. Perhaps, humanity’s future is bright after all!

Thammasat University partners with TCG to offer Finance and Business Administration course

Posted on by Thammasat University

The Faculty of Economics, Thammasat University organized the MOU signing ceremony with the Thai Credit Guarantee Corporation (TCG), a state-owned specialized financial institution serving to assist small and medium enterprises (SMEs) through credit guarantees, represented by Assoc. Prof. Dr. Supachai Srisuchart, Dean of the Faculty of Economics and Dr.Rak Vorrakitpokatorn, Director and General Manager of TCG on Friday March 12, 2021 at the 5th Floor Meeting Room, Faculty of Economics, Thammasat University, Tha Prachan Campus.

The Memorandum of Understanding (MOU) aims to enhance the workforce by employing the strengths of both institutions. The Faculty of Economics, Thammasat University, is a leading educational institution with highly qualified faculty members.

They are devoted to educating and developing future assets of the national workforce. TCG will strengthen the confidence of financial institutions in providing credits and assisting potential SMEs entrepreneurs who have insufficient guarantee by ensuring that they receive sufficient credit

The objective of this collaboration is to strengthen the expertise of students and the public. Faculty of Economics, Thammasat and TCG, therefore, design the course together according to the expertise or experience of TCG and its partners by striving to produce academic outputs that meet the business needs.

In addition, internships and job visits at TCG and SMEs will provide business experiences to students and encourage students to undertake business promotion projects for their own future careers and sustainable growth. The course is expected to be open by May 2021.

TPU acquires reactor operation license for 10 Years

Posted on by Tomsk Polytechnic University

The TPU IRT-T Nuclear Research Reactor has extended an operation license for another 10 years.

“License acquisition from the Federal Service for Environmental, Technological and Nuclear Supervision (Rostechnadzor), a supervisory body, is always a very complicated process, especially when it refers to such a long-term period. We submitted the document set proving installation safety for approval in 2019. After that, the Federal Service for Environmental, Technological and Nuclear Supervision commissioned a formal safety assessment that was conducted by the expert organization. These works lasted about nine months. As a result, we received expert findings including all remarks and recommendations. Ultimately, we acquired a license,” Artem Naymushin, Head of the TPU Nuclear Research Reactor, says specifying that an operation license was initiated by the order of TPU Rector Andrey Yakovlev.

“We are deeply thankful to the entire team of the Reactor taking an active part in all the stages of license acquisition. At the moment, having acquired a license, we will keep improving our work.”

He adds that expert findings include a lot of aspects related to compliance with the requirements of physical protection, nuclear and radiation safety, staff and population protection, and others. Moreover, the Reactor staff prepares annual reports on the condition of the unique research installation for the supervisory body.

The TPU Nuclear Research Reactor is the one operating university reactor in Russia. The regular remanufacturing operations were completed within the Federal Targeted Program for Research and Development in the last year.

The project provided the renewal of the research complex and expansion of functional capabilities through the inclusion of the unique set of global user stations: an experimental automated complex for doping semiconductor materials, a multipurpose complex for irradiation of target samples on extracted neutron fluxes, a gamma-ray laser, an installation for research of interaction of nuclear materials with active gases, a digital spectrometric complex for positron annihilation spectroscopy, a complex for the production of industrial and medical isotopes, a complex for the production of radiopharmaceuticals.

The IRT-T Nuclear Research Reactor is aimed at research neutrons, neutron radiation, objects of the microcosm, conducting fundamental and applied research at the forefront of science. It helps to create new materials and technology in the energy industry, to develop promising medication and technology of nuclear medicine.

Mining University Graduate on how he ended up in Germany

Posted on by St. Petersburg Mining University

Maxim Vorona, a graduate of St. Petersburg Mining University, moved to Germany more than ten years ago. Over these years, he has advanced to the Deputy CEO at MIBRAG Consulting International, part of the Germany-based coal producer MIBRAG.  

“I always wanted to build a career in mining. My father was a chief engineer at the expedition that explored diamond deposits in Arkhangelsk Oblast, Russia. They worked at the Lomonosov mine, one of the largest diamond mines in Russia and the world, consisting of, for instance, the V. Grib and Pomorskaya kimberlite pipes. He often let me join him when I was on holidays. And as a teenager, I already knew how a drilling rig works or what the term ‘geological prospecting’ stands for.

In 2002 I entered St. Petersburg Mining University, which even then differed from other Russian universities. It had research labs, agreements with industry-specific companies on internships and work placements. Finally, its graduates had high employability. All these factors combined plus my knowledge and skills earned me the job position I’m in now,” says Maxim.

In his fifth year, the soon-to-be graduate competed for a one-year internship at Freiberg University of Mining and Technology and won. Leaving abroad for internships is a common practice in Russia nowadays, offered by many higher institutions. Back then, the programme, co-funded by the Russian Ministry of Education and the German Academic Exchange Service (DAAD), was gaining momentum. Only one postgraduate student and one undergraduate student were chosen. They went to Saxony, lucky to have been provided with an opportunity to study in Germany and collect data for their theses.

“I indicated that I wanted to study milling machines. Back then, I did not know German and had only English to rely on. I was helped, however. Half a year later, Professor Carsten Drebenstedt, who was lecturing to us, called me in. He is an internationally acclaimed scientist with vast knowledge of open-pit mining, then serving Vice-Rector for Research at Freiberg University of Mining and Technology. He suggested I undertake an internship at Rheinkalk, which I did.

This company is part of the Lhoist Group, the world’s largest producer of lime and dolomite. Lhoist planned to utilise milling machines at one of their deposits because of switching over to an extraction technique not involving blasting. During the next three months, I personally participated in the tests done at the quarry. Upon their completion, I compiled a detailed report, which included data on economic efficiency and technical characteristics, and presented it to the commissioner,” recalls Maxim.

As a result of the Mining University’s student staying in Europe, his studies lasted a year longer than initially expected. This is not unusual in Germany, as well as in many other European countries. Both postgrads and undergrads intentionally look for and readily agree to lengthy internships, typically done abroad. Thereby the future engineers acquire additional competencies and at the same time gather material for research articles.

In contrast to the Russian educational system, the German one favours such an approach. It allows students to be more flexible when deciding which course to take and when to take it. The downside is that many do not complete their master’s degrees until becoming 26-27 years old. 

 

As the internship had come to an end, Maxim returned to St. Petersburg to present his thesis. Shortly after finishing his education at Mining University, he returned to Freiberg – this time, to pursue PhD studies.

Upon graduation, Maxim was approached by several companies. He decided to take his chances on MIBRAG and started as a project manager, gradually moving up the career ladder. By now, he has progressed to the positions of Deputy CEO and Director of Mining.

  

“When I took the job, the corporation needed people with a deep understanding of the market. Aside from being highly qualified engineering specialists, they had to be familiar with trends in the global economy.

My current role is to develop the growth strategy of the business. I also have to ensure that the company will adapt to political or economic changes if they occur. MIBRAG is one of the largest employers in Saxony. And given Germany’s commitment to phasing out the use of coal as an energy source, the level of responsibility is enormous,” notes Maxim.

The Mining University’s graduate rarely visits Russia nowadays. One of the few events he tries to make an exception for is the Russian-German Raw Materials Dialogue, traditionally held in St. Petersburg. Due to the COVID-19 pandemic, it was decided to move it online this year. 

UiTMLaw raises international awareness on the impact of Covid-19 on wetlands and the environment

Posted on by harizsufi

Issues concerning environmental law have long been discussed on an international scale, as the problems faced by nations are interconnected. The Faculty of Law of Universiti
Teknologi MARA (UiTMLaw) environmental law expert, Dr Irini Ibrahim, shared her knowledge at the International Share Lecturer and University Collaboration lecture series.

The event was part of a series of lectures, a collaboration between Universiti Teknologi MARA, Malaysia, Universitas as-Zahra and Universitas Tulungagung, both from Indonesia. This platform encourages multidisciplinary knowledge-sharing among lecturers from various ASEAN universities.  The sharing session was attended by academicians and students, who posed questions on, among others, the role of wetlands as the “Kidneys of the Earth”, wildlife and migratory birds.

Dr Irini said, “Despite the devastating impact of the Covid-19 pandemic on public health, economy and social movements, the pandemic can be seen to be a blessing to the environment. When the global community went into isolated lockdown within the confines of their homes, the environment sighed a relieved breath. Nature blossomed. Global
pollution rates plummeted drastically.”

She continued, “The Ganga and Yamuna rivers of India became extremely clean. Closer to home, the pH levels of the Malacca River have improved. Faunas of the world enjoyed momentary freedom as animals roam the Earth more freely.”

She concluded that these are solid evidence of the negative impact that the human race has on the environment.

Dr Irini added that issues of the wetlands are not new issues. Under the RAMSAR Convention, several wetlands in Malaysia are registered for possessing international importance. However, more needs to be done to spread awareness of the importance of wetlands as the “Kidneys of the Earth”.

UiTMLaw takes pride in Dr Irini for shedding light on issues of the wetlands during these troubled times. The session illustrates the serious need to tackle issues concerning the environment. It is hoped that the audience benefitted from this sharing session.

Physics research from AUS provides new insights into how living matter originated

Posted on by Amy Robinson

Research impacting our knowledge of how life in the universe began has been released by scientists from American University of Sharjah (AUS). A team of researchers led by Dr. Ali Alnaser, Head of the Department of Physics in the university’s College of Arts and Sciences, in collaboration with renowned scientists from Ludwig-Maximilians-Universität München and the Max Planck Institute for Quantum Optics in Germany, and Manipal Academy of Higher Education in India, has published the results of experiments, using intense laser light to irradiate water molecules absorbed on nano-particles, in the prestigious Nature Communications Journal.

The experiments have led to the discovery of a new reaction that led to the production of Trihydrogen ion (H3+), arguably the most important triatomic ion (a molecule consisting of three atoms) for generating living matter in the universe. Up until this point, it was not possible to generate this type of ion from water using conventional chemical synthesis techniques. This ion is fundamental to the production of many organic compounds in the cosmos and is regarded as an important precursor for the origin of life in the universe.

Dr. Alnaser said of the impact of the research: “The findings reveal a new mechanism for the production of H3+ that mimics the conditions of outer space. The research, therefore, provides new insights into the process governing the beginning of life in the universe.”

In addition to providing a greater understanding of how life began, the research findings also have the potential to be extended to the production of other new molecules. Such molecules may have significant biological and environmental applications in both terrestrial and non-terrestrial situations.

The significance of the research has been recognized by the global scientific community, with Nature Communications publishing the research this week in the article “Anomalous Formation of Trihydrogen Cations from Water on Nanoparticles.” Nature Communications forms part of the Nature portfolio, a group of journals forming one of the world’s most respected and prestigious sources of new scientific research. Every month, approximately nine million people worldwide read news, analysis and commentary on Nature.com.

Dr. Alnaser believes the materials science and engineering research facilities at AUS played an important role in the success of the research.

“Our research brought together many technologies across laser physics, molecular dynamics, quantum optics and nanotechnology. AUS’ advanced laboratories allowed for such technologies to be successfully married together,” he said.

Dr. Alnaser noted that research of this magnitude acts as inspiration for existing and future students of AUS, demonstrating how a degree from AUS can lead to remarkable achievements, even in the early days after graduation.

He said that a driving force behind much of the lab-based experiments for this research was M. Said Alghabra, who graduated from AUS in 2020 with a Bachelor of Science in Computer Science with summa cum laude honours. Alghabra spent about two years working on this project under the supervision of Dr Alnaser in the AUS Department of Physics. During his time working on this project, Said received help and guidance from Mazhar Iqbal, Senior Laboratory Instructor in the Department of Physics, as well as visiting professor Rami Ali.

The next step in Alghabra’s career is to pursue a graduate degree at the prestigious Technische Universität München, Germany, one of the top schools in Europe and the world. He has received a DAAD scholarship to pursue his graduate studies. These scholarships are aimed at graduate students and awarded for study and research visits to the university and non-university research institutions in Germany.

“His story will no doubt inspire many students currently enrolled at AUS, or who plan to undertake their studies at the university once completing high school,” Dr. Alnaser said.

Thammasat University inks MoU on climate change

Posted on by Thammasat University

Associate Professor Dr. Suppachai Srisuchat, Dean of the Faculty of Economics, Thammasat University, along with Associate Professor Chol Bunnag, Director of SDG Move, participated in the signing ceremony of the memorandum which outlines the understanding on the development of potential and promotion of knowledge on climate change held at True Digital Park.

It also marked the launching of the Gen C Climate Actions, a project in collaboration with the Thailand Greenhouse Gas Management Organization (Public Organization) or TGO and participating universities to the younger generation on the digital platform of their choice. The program aims to promote understanding and incorporating the knowledge gained into daily life as a way to battle climate change.

The Gen C Climate Actions project was initiated by TGO as part of the TGO – Climate Action Academy in collaboration with the Global Compact Network (GCNT), SDG Move, The Association of Siamese Architects under Royal Patronage, and four universities (Chulalongkorn University, Thammasat University, Burapha University, and Chiang Mai University).

The aim of the project is to educate the younger generation in order to prepare them for the combat of climate change through various fields of studies. This project will be implemented for three years (2021-2023).

In order to ensure the continuation and cooperation between all parties involved, the memorandum of understanding was signed between TGO and the four universities. The goal of this memorandum is focused on cooperation in the development of knowledge in climate change and promotion of the development of university personnel and student potential in interesting ways.

The enhancement of their capabilities in reducing greenhouse gas emissions and adjustments in response to climate change with appropriate practice. Success in reducing greenhouse gas emissions, including the organizing of e-learning workshops by the TGO Climate Action Academy for dissemination of climate change knowledge among the participating universities.

Towards the end of the event, the “C Generation Together Solving Global Warming” discussion was held with representatives from all four universities participating in exchanges about the roles and importance of the academic sector in raising awareness in society, especially the younger generation, such that they recognize the need to solve global warming.

Each university discussed teaching efforts and integration of environmental issues as part of the curriculum. They jointly agreed that environmental issues are important issues that have created a space for discussions and exchanges among all subject files in order to solve these problems.

From Thammasat University, Associate Professor Chol Bunnag participated in the exchanges and expressed the opinion that global warming is a major challenge to sustainable development goals (SDGs) and that raising the awareness of citizens is necessary but not only to promote initiatives and actions but to also echo the voice of society for policymakers to bring about efforts to solve global warming as part of policy agendas on every level and that these need to be implemented seriously.

As for future projects, activities will be organized to provide information about climate change in E-learning format on the platform of the TGO with participating universities, which includes active learning under the Gen C Climate Actions Program.

TPU scientists say wheat bran can be used as fuel

Posted on by Tomsk Polytechnic University

Scientists of Tomsk Polytechnic University have discovered that fusible wheat bran combined with additives can be used as fuel. It could help to reduce greenhouse gases and the number of landfills, as well as to optimize the creation of mixtures for the efficient energy use of biomass. The research findings are published in the Fuel academic journal.

According to TPU scientists, various types of biomass, such as agricultural waste, have been increasingly used as fuel in recent years. They conducted a research where they examined wheat bran from one of the flour mills in the Siberian region of Russia.

The researchers discovered that bran is a fusible fuel. The mineral part of wheat bran is already sintered at a temperature above 675°С, which is much lower than the temperature in the boiler. During combustion, the biomass under investigation forms a glasslike deposit of slag ash, removing that it is possible to damage the heating surface. As a result, it will reduce the heat transfer, reliability of operation and boiler output.

According to scientists, wheat bran contains a lot of potassium. It strongly influences the melting point of the mass and the formation of a glasslike deposit. To investigate the mineral content of wheat bran in more detail, the wheat bran was divided into fractions of different densities by sedimentation (the settling of particles in a liquid or gas under the action of a gravitational field or centrifugal force). The scientists obtained four fractions, two of which form a crumbly mass when combusted.

“Having studied the mineral composition of the obtained fractions, we found that the key factor influencing the sintering of bran ash is the ratio of calcium to high potassium content. To confirm it, we conducted experiments by adding calcium carbonate to the bran, which resulted in crumbly and powderlike ash residue. It evidences that the combustion of this mixture results in the cleaning of heating surfaces without much difficulty,” Kanipa Ibraeva, Engineer of the TPU Butakov Research Centre, told Sputnik news agency.

There are several approaches to prevent the sintering of ash during biomass combustion, the researchers noted. They mainly include the addition of additives that can raise the melting temperature.

“To select an additive with active chemical composition and an economically attractive cost is quite difficult. We believe that combustion of fusible biomass with the addition of calcium carbonate will reduce operating costs,” Ibraeva commented.

Moreover, the experts claim that fuel from various types of biomass will allow reducing greenhouse gases from combustion, as well as will reduce the number of landfills and recycle industrial waste.

The research team is currently planning to conduct comprehensive research of the mineral part of the biomass and examine the effects of volatile ash compounds on accelerated corrosion of the metal surfaces of power plants.

Researchers from Japan develop a model to explore the dynamics of movement in cheetahs

Posted on by NITech

In a new study, a team of researchers from Japan propose and validate an analytical model for studying cheetah galloping by comparing its predictions with cheetah data. While improving upon the current understanding of cheetah’s locomotion, their findings pave the way for designing legged robots!

“All animal running constitutes a flight phase and a stance phase, with different dynamics governing each phase,” explains Dr. Tomoya Kamimura from Nagoya Institute of Technology, Japan, who specializes in intelligent mechanics and locomotion.

During the flight phase, all feet are in the air and the center of mass (COM) of the whole body exhibits ballistic motion. Conversely, during the stance phase, the body receives ground reaction forces through the feet.

“Due to such complex and hybrid dynamics, observations can only get us so far in unravelling the mechanisms underlying the running dynamics of animals,” Dr. Kamimura says.

Consequently, researchers have turned to computer modelling to gain a better dynamic perspective of the animal gait and spine movement during running and have had remarkable success using fairly simple models. However, few studies so far have explored the types of flight and spine motion during galloping (as seen in a cheetah).

Against this backdrop, Dr. Kamimura and his colleagues from Japan have now addressed this issue in a recent study published in Scientific Reports, using a simple model emulating vertical and spine movement.

The team, in their study, employed a two-dimensional model comprising two rigid bodies and two massless bars (representing the cheetah’s legs), with the bodies connected by a joint to replicate the bending motion of the spine and a torsional spring. Additionally, they assumed an anterior-posterior symmetry, assigning identical dynamical roles to the fore and hind legs.

By solving the simplified equations of motion governing this model, the team obtained six possible periodic solutions, with two of them resembling two different flight types
(like cheetah galloping) and four, only one flight type (unlike cheetah galloping), based on the criteria related to the ground reaction forces provided by the solutions themselves. Researchers then verified these criteria with measured cheetah data, revealing that cheetah galloping in the real world indeed satisfied the criterion for two flight types through spine bending.

Additionally, the periodic solutions also revealed that horse galloping only involves gathered flight due to restricted spine motion, suggesting that the additional extended flight in
cheetahs combined with spine bending allowed them to achieve such great speeds!

“While the mechanism underlying this difference in flight types between animal species still remains unclear, our findings extend the understanding of the dynamic mechanisms underlying high-speed locomotion in cheetahs. Furthermore, they can be applied to the mechanical and control design of legged robots in the future,” speculates an optimistic Dr Kamimura.