Mr. Rishabh Gaur – Roorkee College Of Pharmacy, Roorkee – India

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Bio

EDUCATION

• Completed M. Pharm. (Pharmacology) from Rajiv Academy for Pharmacy, Mathura (U.P.) India, (2021-2023).
• Completed B. Pharm. from Rajiv Academy for Pharmacy, Mathura (U.P.) India, (2017-2021).
• Completed Intermediate (10+2) from SRI G S I C BHUTIYA PANIGAON, Mathura (U.P.) India (2017).
• Completed High School (10th) from KENDRIYA VIDYALAY- 2, Mathura (U.P.) India (2015).

Work Experience
Designation Name of the Institute/University Duration
Assistant Professor Roorkee College of Pharmacy, Roorkee, (U.K.), India 01/01/2024 to Till now

M. PHARM RESEARCH TOPIC
Pharmacological Evaluation and Unraveling Mechanism of Thevetia peruviana Leaves for Predicted Treatment of Peptic ulcer disease.

Published/Accepted

1. Rishabh Gaur, Anuj Kumar Sharma, Devender Pathak, Mayank Kulshreshtha, “Scientific update on the Pharmacognostic, Pharmacological and Phytochemical properties of Thevetia peruviana: Phytopharmacological update on Thevetia peruviana” Phcog.Net. (Published in 2023).
2. Rishabh Gaur " A Brief History: Traditional Chinese Medicinal System" Pharmacological Research - Modern Chinese Medicine, Elsevier. (Published, Scopus Indexed).
3. Rishabh Gaur, Mayank Kulshreshtha, “A comprehensive Review on Peptic Ulcer” Current Nutraceuticals, Bentham Science (Published in 2023).
4. Mohit Sandhuja, Rishabh Gaur, Anuj Kumar Sharma, Mayank Kulshreshtha “Regulatory Pathways for Ayurvedic Formulations in India”. Current Nutraceuticals, Bentham Science (Published in 2023).

5. Prashant Kumar, Rishabh Gaur, Devender Pathak, Mayank Kulshreshtha “An overview of anti-diabetic Efficacy and Biochemical Mechanism of Anisomeles malabarica (Malabar catmint): A Review” Bioequivalence & Bioavailability Journal (MedWin Publishers, Published in 2023).
6. Aarti Rajput, Rishabh Gaur, Km. Vibha. “Development and Evaluation of Emulgel of Celecoxib by using Natural Oil”. Anti-Inflammatory & Anti-Allergy Agents in Medicinal Chemistry (Bentham Science, Scopus In

 

Prof. Ahmed Thabet Mohamed -Aswan University – Egypt

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Bio
Ahmed Thabet was born in Aswan, Egypt in 1974. He received the BSc from Faculty of Energy Engineering (FEE) Electrical Engineering degree in 1997, and MSc (FEE) Electrical Engineering degree in 2002 both from Faculty of Energy Engineering, Aswan, Egypt. PhD degree had been received in Electrical Engineering in 2006 from El-Minia University, Minia, Egypt. He joined with Electrical Power Engineering Group of Faculty of Energy Engineering in South Valley University as a Demonstrator at July 1999, until; he held Professor position at October 2017 up to date. His research interests focus in the areas of analysis and developing electrical engineering models and applications, investigating novel nanotechnology materials via addition nano-scale particles and additives for usage in industrial branch, electromagnetic materials, electroluminescence and the relationship with electrical and thermal ageing of industrial polymers. A lot of mobility’s has investigated for supporting his research experience in UK, Finland, Italy, USA and KSA …etc. In 2009, he established 1st Nano-Technology Research Centre in the Upper Egypt for developing industrial materials of ac and dc applications by nano-technology techniques through it was published many scientific in developing industrial applications using the latest technologies in nanotechnology. He is classified within TOP 2% of Scientists worldwide, September 2022 data-update for "Updated science-wide author databases of standardized citation indicators. He has high numerous quality publications which have been published and under published in cited international journals and conferences. He has many electronic and printed books in grounding systems, designing composite materials and nanodielectrics for industrial applications and investment the emerging nanotechnology applications in electrical engineering. From 2018 up to Date, he has been held a full professor position in Colleges of Engineering at Saudi Arabia.

Institutions
Aswan University 

Affiliations
Scopus
Orcid

Dr. Niranjanmurthi Lingappan – Chonnam National University – South Korea

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Bio

I have graduated my PhD in 2013, from Pukyong National University, South Korea. After my PhD I have pursued postdoctoral research for 5 years at Sungkyunkwan University, South Korea under the Institute of Basic Science Fellowship. In subsequent years, I have secured a position at University of Maryland, USA, as a Research Associate. Currently, I have been pursuing my research at Chonnam National University, South Korea.
My research has been focused on development of advanced materials for Renewable and Sustainable Energy Devices. I have also been focusing on finding crucial aspects of materials toward the performance decay of devices mainly Lithium ion batteries.

Institutions

Chonnam National University 

Affiliations

Dr. Marwa Hassan – National Research Centre – Egypt

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Bio

She holds a PhD in Bioinformatics from the Faculty of Engineering, Zagazig University, Cairo, Egypt.
She joined one of the first bioinformatics groups in Egypt in partnership with the Kasr El Aini Liver Institute to combat hepatitis C, which led to the publication of several research papers in various scientific journals. Not only that, but she is also interested in contributing to improving the process of discovering human disease-causing mutations using MLTs.
Also, she is a scientific researcher at the Institute of Engineering Research and New and Renewable Energy, NRC, Cairo, Egypt, and a patent technical expert at the Academy of Scientific Research and Technology, Cairo, Egypt.
She participated in organizing many workshops and is an active member of the Women’s Association for Science in Developing Countries. Also, she is a member of the Women’s Committee of the Research Staff Club.

Institutions

 

National Research Centre
Affiliations

Assist Prof Dr. uğur sorgucu – Nevsehir Hacı Bektas Veli University – Turkey

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Bio

Uğur SORGUCU, was born in Kayseri, Turkey. He received the BSc, MSc and PHd degrees in electrical and electronics engineering from the Erciyes University in 2009, 2011 and 2021, respectively. He is working as researcher in the Department of Electrical and Electronics Engineering at Nevsehir Hacı Bektas Veli University, Turkey His current research interests include machine learning, appyling soft computing techniques on engineering problems, effect of electromagnetic field on biological systems and electromagnetic compatibility

Institutions

Affiliations

Photovoltaics

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Introduction on Photovoltaics

Photovoltaics, often referred to as solar energy, is a transformative field of renewable energy technology that harnesses the power of sunlight to generate electricity. It involves the use of solar cells, also known as photovoltaic cells, which convert sunlight into electrical energy through the photovoltaic effect. Photovoltaics has gained significant attention and momentum as a clean and sustainable energy source, with applications ranging from residential solar panels to massive solar farms. Research in this field is dedicated to improving the efficiency, affordability, and environmental impact of solar energy systems, making them an essential part of the global transition to clean energy.

Subtopics in Photovoltaics:

Solar Cell Technologies:

The development of various types of solar cells, such as silicon-based cells, thin-film cells, and emerging technologies like perovskite solar cells. Researchers focus on enhancing the efficiency and cost-effectiveness of these technologies.

Photovoltaic Materials:

Exploring materials used in solar cell construction, including semiconductors, organic compounds, and nanostructures. Subtopics delve into the discovery of new materials and their impact on solar energy conversion.

Photovoltaic System Design:

Design and optimization of photovoltaic systems for different applications, from residential rooftops to large-scale solar farms. Research in this area aims to maximize energy output, minimize installation costs, and ensure long-term system reliability.

Solar Energy Storage:

Addressing the intermittent nature of sunlight, research on energy storage solutions like batteries and grid integration technologies. This subfield focuses on ensuring a continuous and reliable energy supply from photovoltaic systems.

Environmental Impact and Sustainability:

Investigating the environmental and sustainability aspects of photovoltaic technologies, including lifecycle assessments, recycling methods, and sustainable manufacturing practices to minimize the ecological footprint.

Thin-Film Transistors

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Introduction on Thin-Film Transistors (TFTs)

Thin-Film Transistors (TFTs) are essential components in a wide range of electronic devices, from flat-panel displays and flexible electronics to integrated circuits and sensors. Unlike traditional transistors, TFTs are fabricated on thin semiconductor films, enabling their incorporation into lightweight and flexible applications. These devices play a pivotal role in modern electronics, allowing for high-performance, low-power operation in compact and versatile form factors. As the field of TFTs continues to evolve, research is focused on enhancing their performance, exploring new materials, and expanding their applications.

Subtopics in Thin-Film Transistors:

TFT Technologies for Displays:

Thin-Film Transistors are integral to modern display technologies, such as LCDs and OLEDs. Researchers in this subfield concentrate on improving TFT performance for enhanced image quality, response times, and energy efficiency in displays.

Organic Thin-Film Transistors:

Organic TFTs are a subset of TFTs made from organic semiconductor materials. They are crucial for flexible and printed electronics. Subtopics delve into the development of organic TFTs, enhancing their electrical properties and reliability.

Flexible and Wearable Electronics:

TFTs are at the core of flexible and wearable electronics. Research in this area explores novel TFT materials and designs to create durable, bendable, and conformable electronic devices.

Amorphous Silicon TFTs:

Amorphous silicon TFTs have been widely used in active matrix displays. Subtopics within this area focus on optimizing the performance and stability of amorphous silicon TFTs for applications in TVs, laptops, and more.

TFTs for Sensor Applications:

TFTs are employed in various sensor applications, from touchscreens to chemical and environmental sensors. Research in this subfield aims to develop TFT-based sensors with improved sensitivity and selectivity.

Insulators

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Introduction on Insulators

Insulators in the realm of materials science and electrical engineering, are substances that inhibit the flow of electrical current. They are specifically designed to have high electrical resistance, making them ideal for preventing the escape of electrical energy or the passage of current between conductors. Insulators are crucial components in electrical systems and devices, serving to insulate, protect, and maintain the integrity of electrical circuits. These materials are found in various forms, from traditional ceramics and glass to advanced composite insulators, each tailored to meet specific electrical and environmental requirements.

Subtopics in Insulators:

Electrical Insulation Materials:

This subtopic delves into the materials used in electrical insulation, including polymers, ceramics, and glass. Researchers explore the electrical and thermal properties of these materials to enhance their performance in various electrical systems.

High Voltage Insulators:

High voltage insulators are engineered to withstand extreme electrical stress and environmental conditions. Subtopics within this area focus on the design, testing, and deployment of insulators for high voltage applications in power transmission and distribution.

Composite Insulators:

Composite insulators are a modern alternative to traditional materials, offering advantages in weight, durability, and pollution resistance. Research in this subfield centers on improving the design and performance of composite insulators.

Insulator Pollution and Performance:

In polluted environments, insulators may accumulate contaminants that can compromise their electrical performance. Researchers work on understanding and mitigating insulator pollution, ensuring the reliability of electrical systems.

Smart and Self-Cleaning Insulators:

Emerging technologies are bringing smart capabilities to insulators. Subtopics in this area explore self-cleaning insulators and those integrated with sensors for real-time monitoring, enabling more efficient and sustainable electrical systems.

Artificial Intelligence in Materials Discovery

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Introduction on Artificial Intelligence (AI) in Materials

Artificial Intelligence (AI) in Materials Discovery is a cutting-edge field that harnesses the power of AI and machine learning to accelerate the development of new materials with tailored properties. Traditional materials discovery and development can be time-consuming and costly, but AI offers a transformative approach by analyzing vast datasets, predicting material properties, and guiding researchers toward promising candidates. This interdisciplinary field brings together materials science, computer science, and data analytics to revolutionize the way we design and engineer materials for various applications, from advanced electronics to clean energy solutions.

Subtopics in Artificial Intelligence in Materials Discovery:

Materials Property Prediction:

AI models are used to predict the properties of materials with remarkable accuracy. Researchers focus on developing machine learning algorithms capable of forecasting mechanical, thermal, electrical, and other material properties, streamlining the design process.

High-Throughput Screening:

AI enables high-throughput screening of vast material libraries, significantly expediting the discovery of new materials. Subtopics include the development of automated platforms for testing and evaluating materials at an unprecedented scale.

Materials Genome Initiative:

The Materials Genome Initiative is a major initiative that leverages AI to create a "materials genome" - a vast database of materials and their properties. Researchers explore ways to enhance this initiative and utilize it for material discovery and design.

Accelerated Materials Development:

AI-driven approaches have the potential to reduce the time and cost required for materials development. Subtopics within this area focus on the acceleration of materials discovery for applications in renewable energy, electronics, and more.

AI in Quantum Materials:

Quantum materials are of particular interest, and AI is used to explore their unique properties and potential applications in quantum computing and technology. Research includes the prediction and discovery of novel quantum materials.

Defect Engineering

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Introduction on Defect Engineering

Defect Engineering  is a multidisciplinary field at the crossroads of materials science, engineering, and nanotechnology. It involves the controlled introduction and manipulation of defects in materials to improve their properties and performance. Rather than being unwanted imperfections, engineered defects can be strategically created and precisely tailored to enhance materials for various applications. This field has a wide range of applications, from semiconductor devices and catalysis to energy storage and materials with exceptional mechanical properties.

Subtopics in Defect Engineering:

Semiconductor Defects for Electronics:

In the semiconductor industry, defect engineering plays a crucial role in tailoring the electrical properties of materials. Researchers focus on creating and managing defects to improve transistor performance, enabling faster and more efficient electronic devices.

Defects in Catalysis:

Defect engineering can enhance catalytic reactions in materials, increasing their efficiency for applications in environmental remediation, chemical synthesis, and fuel cells. Subtopics explore how defects influence catalytic processes and the design of defect-rich materials.

Defects in Energy Storage Materials:

Energy storage devices, such as batteries and supercapacitors, can benefit from controlled defects. Researchers investigate the role of defects in improving energy storage density and charge-discharge rates for more sustainable and efficient energy solutions.

Mechanical Property Enhancement:

Defect engineering can be used to enhance the mechanical properties of materials, making them stronger, tougher, and more resilient. This is crucial for applications in aerospace, construction, and material science.

Quantum Defect Engineering:

In the emerging field of quantum technologies, defect engineering is used to create and manipulate quantum states in materials, offering novel opportunities for quantum computing and quantum communication applications.