Abstract

In nature daily we encountered with complex structures including the structure of human body. A fractal is a never-ending pattern. Fractals are infinitely complex patterns that are self-similar across different scales. They are created by repeating a simple process over and over in an ongoing feedback loop. Driven by recursion, fractals are images of dynamic systems – the pictures of Chaos. Geometrically, they exist in between geometrical dimensions. Fractal patterns are extremely familiar, since nature is full of fractals. Selfsimilar objects look the same on any scale; no matter how many times you magnify it, it will look similar. Fractals are composed of smaller versions of itself. The most important fractals are the Mandelbrot-set, Julia set, Cantor set, Henon attractor, Rossler attractor, Lorenz attractor, Ikeda attractor, Horseshoe map, Chua’s circuit, Lyapunov exponent. A fractal canopies is created by taking a line segment and splitting it into two smaller segments at the end. Iterate this process infinitely. A fractal canopies has the following properties: the angle between two neighboring line segments has to be the same throughout the fractal; the ratio of the lengths of consecutive lines must be constant; points at the end of the smallest line segments should be interconnected. Fractal dichotomous branching is seen in the lung, small intestine, blood vessels of the heart, and some neurons. Fractal branching greatly amplifies the surface area of tissue, be it for absorption (e.g. lung, intestine, leaf mesophyll), distribution and collection (blood vessels, bile ducts, bronchial tubes, vascular tissue in leaves) or information processing (nerves). 

Biography

Prof. Rashmi Bhardwaj, Fellow of Institute of Mathematics & Applications (FIMA) (UK); Assessor, National Assessment and Accreditation Council (NAAC), UGC, Government of India; Fellow of Indian Society for Mathematical Modelling and Computer Simulation (FISMMACS), under IIT Kanpur, India and working as Professor of Mathematics & Head of Nonlinear Dynamics Research Lab, University School of Basic & Applied Sciences (USBAS), Guru Gobind Singh Indraprastha University (GGSIPU), New Delhi, India. Recipient of Government of India, India Meteorological Department (IMD) 27th Biennial MAUSM Award. Visiting Associate of Inter University Center for Astronomy & Astrophysics (IUCAA) Pune, Young Scientist Award of All India Council for Technical Education (AICTE), Government of India. Best Researcher Award of GGSIPU (3 consecutive years.) Topper of University of Delhi with 100% marks in Integral equation & Boundary value problem. Also, the topper of Zakir Husain college University of Delhi in M.Sc. (Mathematics) and B. Sc (Hons.) (Mathematics) examination. Life Time Achievement Award 2022 in Nonlinear Dynamics; Bharat Mata Abhinandan Samman 2022, PAAI International Award for Education Excellence 2021; FoXclues India Prime Top 100 Women Icon Award 2021; Lifetime Achievement Award 2021 for International Scientist Awards on Engineering, Science and Medicine; Dr. Sarvepalli Radhakrishnan Distinguished Professor Award 2021 in Applied Mathematics;; Best Researcher Award 2020 - International Research Award on New Science Inventions NESIN 2020; GGSIPU Indraprastha University Internal Quality Assurance Cell (IIQAC) four certificate of Appreciation along with cash of Rs. 10000/-. 4 patents, 250 research papers & book chapters, 9 books, 15 Ph.D. supervised and 6 are presently working. 28 years teaching and 33 years research experience. Visited, attended and delivered 450 invited Lectures in International/National conferences. Subject Reviewer for many International Journals of repute. Life member of several international organizations in the sphere of Mathematical Sciences including Indian National Science Congress. Attended/ delivered talks and Chaired Technical Sessions at reputed academic conferences/ workshops across the world Established Nonlinear Dynamics Research Lab and Mathematics Lab in GGSIPU. Member of Sectional Committee -Section of Mathematical Sciences (including Statistics) for 2020-2021, 2019-2020 (108th and 107th Session of Indian Science Congress); The Indian Science Congress Association (Department of Science & Technology, Ministry of Science & Technology, Government of India).

Abstract

Wood is a raw material that is in high demand because it is renewable, environmentally friendly and can be used in various industries. Therefore, a lot of people are asking themselves in which direction the woodworking experiments should go. 

Progress in woodworking must include efficiency in the production process, modernization of machinery as well as production processes, better product quality and energy savings.

The requirements for furniture manufacturers are that the resulting coatings should be resistant to mechanical factors (abrasion, impact, scratching) show good adhesion to the substrate and have high aesthetic and decorative features.

UV lacquer products belong to a very interesting solution. There were recently introduced into wood companies' technologies for finishing wood species and wood-based composites using acrylic or waterborne UV products. In this presentation some principles of UV technology were presented. 

Based on the carried out investigations and published papers, results of research was shown.

Biography

Dr. Tomasz Krystofiak in 1994 was finished study of Faculty of Wood Technology at Agriculture Academy in Poznan. In 2002 he prepared a PhD dissertation and in 2019 habilitation. Author or co-author of more than 300 scientific publications in the scope of gluing and finishing of wood and wood based composites. To his research activities belongs surface phenomena, wettability, adhesion and adherence, modification, gluability and paintability of lignocellulosic materials. He was a Management Committee Member of COST Actions FP1006 and CA15216 and Working Group Member (FP1303 and FP1407). Since 2021 Guest Editor in 6 Special Issues in Coatings, Forests, Materials journals.

Abstract

Prepregs are one of the most common raw materials for manufacturing composite components due to the possibility of obtaining higher strength, uniformity and reproducibility, reduced waste during manufacture and shorter curing times. In the process of manufacturing a prepreg, it is necessary to combine the fibres with the resin to obtain reels of this material. However, if the equipment's rollers are not aligned, the resin film deviates from them, which leads to product defects, wastage and increased manufacturing costs. In the context of this equipment, this work has two main objectives. On the one hand, the aim is to develop a mechanical roller clamping system that allows the rollers to be calibrated. As the rollers that guide the film through the process have three different types, it is necessary to develop a solution applicable to each type of roller. On the other hand, the aim is to develop an electronic system capable of measuring the alignments between rolls and transmitting the acquired data to a graphic interface. Interoperability with a supervisory interface is a fundamental requirement, as the operator will be able to visualise misalignments between rollers in real time and the necessary measures to be taken to ensure correct alignment between them. As a result of this work, the solutions developed were implemented in the equipment, the stipulated experimental validations were carried out and a functional, efficient process was achieved, allowing the equipment to be used for the manufacture of prepregs with the necessary requirements for industrial use.

Biography

Raul Campilho is an Auxiliar Professor at ISEP – School of Engineering, Porto, Portugal. He participated in 112 event(s). He supervised 5 PhD thesis(es) and e co-supervised 1. He Supervised 167 MSc dissertation(s) e co-supervised 73. He has received 16 awards and/or honors. He Participates and/or participated as Principal investigator in 1 project(s) and Researcher in 6 project(s). His research area includes material joining, adhesive joints, material characterization, polymers, composite materials, sandwich structures, advanced manufacturing systems, automation and robotics, industrial design, numerical modelling, finite element method, and cohesive zone models.

Abstract

Executive Summary This white paper explores the collective properties of 18 advanced Quantum Fractal alloys, designed for a wide range of high-performance applications across industries, from renewable energy to biomedicine. These alloys represent a leap in materials science, leveraging Quantum Fractal technology to achieve unprecedented efficiency, adaptability, and sustainability. The paper provides an overview of their combined properties, highlights interdisciplinary synergies, and outlines future research directions. 

1. Introduction to Quantum Fractal Alloys The 18 Quantum Fractal alloys share a foundational innovation: the use of Quantum Fractal technology. This approach integrates self-similar fractal patterns at the nanoscale, optimizing electron pathways, thermal management, mechanical flexibility, and light absorption. These alloys collectively address several technological challenges, such as improving efficiency in energy conversion, enhancing thermal regulation, increasing bio-compatibility, and enabling advanced communication. 

2. Combined Properties of the Quantum Fractal Alloys

 2.1 Thermal and Cryogenic Properties 

● High Thermal Conductivity and Stability: Alloys like ThermoFlow, CryoMorph, and HexaSil showcase superior thermal management capabilities, maintaining stability over a wide temperature range (-273°C to 1200°C). These alloys ensure optimized heat dissipation in electronic systems, efficient geothermal energy capture, and robust cryogenic performance in space exploration.

 ● Cryogenic Flexibility: Alloys such as CryoMorph retain structural integrity under extreme cold, minimizing brittleness through Quantum Fractal structures that evenly distribute thermal stress. 

● Adaptive Thermal Response: NeutraPhase and ChronoTherm demonstrate rapid phase-shifting and time-based thermal adjustments, enabling real-time temperature control in smart environments. 

2.2 Quantum and Electromagnetic Properties 

● Enhanced Quantum Coherence: Nyrrite and QuantumLattice are critical for advanced quantum communication and computing. They offer high coherence times, stable quantum states, and low decoherence, key for reliable quantum networks and sensors.

 ● EM Signal Precision: Alloys like MetaWave and FerroPhase provide precise electromagnetic modulation and phase shifting, ensuring signal clarity in radar, antenna systems, and secure communication channels. 

2.3 Light and Solar Efficiency

 ● Optimized Light Management: Alloys such as LuminoAlloy and QuantumReflect exhibit high luminescent and reflective efficiency, critical for displays, optical systems, and energy-efficient lighting.

 ● High Solar Absorption: SolariCloak and AetherCore are designed for solar applications, achieving up to 98% light absorption. These materials support sustainable energy solutions and adaptive building materials. 

● Dynamic Light Adaptation: Alloys like ThermoGlass adjust light transmission and thermal properties in real-time, suitable for smart windows and green construction.

 2.4 Mechanical and Structural Properties 

● Exceptional Durability: Alloys such as VoltCore and GeoSync demonstrate resilience in harsh conditions, providing reliable performance in power grids, geothermal systems, and high-pressure environments. 

● Flexible and Adaptive Structures: The Quantum Fractal approach ensures that alloys like BioNanoFract and BioSync maintain flexibility, even under mechanical stress, making them ideal for smart textiles, wearable technology, and adaptive implants. 2.5 Bio-Compatible and Eco-Friendly Properties 

● Enhanced Bio-Integration: Medical alloys such as BioNanoFract and BioSync accelerate healing, reduce rejection rates, and support advanced implants and tissue engineering.

 ● Sustainability: HexaSil and AetherCore are designed for green manufacturing and renewable energy, with a focus on recyclability, low-carbon production, and high energy efficiency. These alloys are paving the way for a more sustainable future in industrial manufacturing. 

3. Synergistic Applications Across Sectors

 3.1 Renewable Energy and Green Construction

 ● Integrated Solar-Energy Systems: Combining alloys like SolariCloak and AetherCore enables adaptive solar panels that maximize energy efficiency while providing architectural flexibility. These materials can be utilized in adaptive façades, solar-integrated smart windows, and urban energy solutions.

 ● Sustainable Manufacturing: HexaSil leads the way in green manufacturing processes, while alloys like GeoSync support geothermal and industrial applications with eco-friendly properties and high durability. 3.2 Advanced Electronics and Quantum Computing 

● Quantum Communication Networks: The combined properties of Nyrrite, QuantumLattice, and MetaWave allow for the development of high-fidelity quantum communication networks, supporting secure data transmission over extended distances with minimal interference. 

● Thermal Management in High-Performance Computing: The combination of ThermoFlow and CryoMorph ensures stable thermal regulation in high-performance processors and GPUs, preventing overheating and improving computational efficiency. 3.3 Biomedicine and Biotechnology

 ● Smart Implants and Wearable Tech: BioNanoFract and BioSync alloys support the next generation of medical implants, tissue scaffolds, and adaptive wearable devices that respond to biological changes in real time. 

● Precision Diagnostics: The sensitivity of alloys like FerroPhase and ChronoTherm enables the development of advanced diagnostic tools, capable of real-time monitoring and adaptive response to environmental changes. 3.4 Defense, Security, and Critical Infrastructure 

● Secure Communication and EM Shielding: Alloys like MetaWave and QuantumReflect provide enhanced signal clarity and EM shielding for secure communication systems, radar, and defense infrastructure. 

● Robust Infrastructure Materials: VoltCore and HexaSil deliver resilient materials that can withstand environmental stressors, ensuring the safety and reliability of critical infrastructure.

 4. Future Directions for Quantum Fractal Alloys 

4.1 Advanced Quantum Systems Future research will focus on refining alloys for topological quantum computing and error correction. This will involve improving coherence times, reducing noise, and integrating these materials into scalable quantum architectures. Alloys like Nyrrite and QuantumLattice will play central roles in creating a stable quantum internet. 

4.2 Bio-Electronics and Smart Medical Devices The integration of Quantum Fractal alloys into bio-electronic devices is a promising field. Alloys such as BioNanoFract and BioSync are expected to evolve into smart implants capable of real-time diagnostics, remote health monitoring, and personalized medical interventions.

 4.3 Adaptive and Flexible Materials Alloys with flexible and adaptive properties, like ThermoGlass and NeutraPhase, will be refined for applications in flexible electronics, wearable technology, and dynamic architecture. The goal is to create materials that seamlessly integrate with complex environments, offering intelligent adaptation to changing conditions. 

4.4 Eco-Friendly Manufacturing and Sustainable Development Research into environmentally friendly alloys like HexaSil will focus on reducing the environmental impact of industrial processes while enhancing performance. This includes developing alloys that are fully recyclable, reducing carbon emissions, and optimizing thermal management in eco-friendly construction. 

4.5 Energy Capture and Conversion The development of alloys like SolariCloak and AetherCore will expand into flexible solar films, lightweight solar panels, and off-grid energy solutions, driving the next wave of decentralized and sustainable energy systems.

 5. Conclusion The 18 Quantum Fractal alloys represent a significant advancement in materials science, offering a wide range of applications across multiple industries. By leveraging the unique properties of Quantum Fractal technology, these alloys pave the way for a future where sustainability, adaptability, and efficiency are paramount. Continued research and interdisciplinary collaboration will be key to unlocking their full potential. 

Biography

Chris McGinty is a visionary entrepreneur who has revolutionized theoretical physics and artificial intelligence. With an unquenchable thirst for understanding the universe, Chris embarked on a quest to develop a unified framework that could transform our knowledge of nature. Through extensive research, he introduced the MEQ, an extraordinary unified equation bridging quantum physics and field theory. As the founder of the L_TOE (Lagrangian Theory of Everything) framework, Chris assembled a brilliant team and harnessed cutting-edge AI technologies to explore the intricacies of the MEQ. This endeavor birthed Skywise.ai, an innovative platform uniting quantum-inspired algorithms, computational resources, and simulation tools to advance various domains. Chris's unwavering pursuit of knowledge and commitment to pushing scientific boundaries have cemented his status as a pioneering figure. His work lays the groundwork for quantum computing, artificial intelligence, and our comprehension of the universe's fundamental laws. Through interdisciplinary collaboration, Chris inspires future generations, leaving an enduring impact on scientific progress.

Abstract

An overview of advancements in electronic navigation is summarized. Electronic navigation performance on recreational marine systems is studied. Various electronic and automated navigation techniques of marine products are summarized for different style marine vehicles. Wide variety of boats such as Deep V high displacement boats to high speed boats. Stable heavy deep v boats vs unstable boats - like lightweight flat bottom boats need constant correction. Various sea state conditions such as wind, current and wave affect navigation quality. Various navigational aids such as Cartography, Sonar, Radar, Global Navigation Satellite Systems, Inertial Measurement Units, digital compass, Autopilot, Depth, Speed, Wind Sensor, Meteorological/Water conditions data, NMEA/Ethernet networking hub, AI Software and hardware the details of perfect Navigation System are explained. AIS can recognize target risks based on collision avoidance protocol adoption. Navigational aids' efficient usage for optimized routing (low emissions/fuel consumption), automated course correction, heading, anchor navigation are briefed. Marine vehicle steering, thrusting, trimming, vehicle pitch and roll control performance of different vehicles, marine power boat, fishing, cruising boats listed. Performance degradation due to rough seas, vibration and quality are reported. Solutions to reduce effects of rough seas, currents, rocks, sandbars, shallow and increasing safe navigation techniques are discussed.

Biography

Charles Bhaskaran completed his MBA from Michigan State University, MS in Mechanical Engineering from Western Michigan University, Michigan USA. He has been working as a Technical Specialist at Brunswick Corporation since 2018, Engineering Specialist at EATON Corporation, Ingersoll Rand Inc., ODL Inc. and Ferroglobe PLC corporations over the past 30 years. He has published more than 45 technical papers/ reports in reputed journals / corporate technical reports and is Managing Simulation, Prototyping, Lab testing and Proving Grounds Field Testing teams of the Brunswick Corporation Navico Group Simulation Development & Validation Center of Excellence at Lowell Technical Center in Lowell, Michigan, USA

Abstract

Atoms and Particles , New Quantum Relativistic Equations This paper dicusses the universe by using quantum -relativity. Many calculations for Particle rest-mass determination is performed studying the relationship between different particles and elementary particles . We also discuss a new Quantum Relativity gravitation theory for the universe. Different curvatures(space-time)(elliptic, flat and hyperbolic) with different light speeds and effects on particle mass is also discussed, General Variable Geometry Physics is Developed. We will here bring up The Exponential-Bi-Logarithmic Trancendental Transformation with rational and Trancendental numbers, as angles e.t.c,… and related algorithms,…

Biography

Tony Barrera is a certified autodidact math genius. He have published more than 42 Ordinary high rated scientific papers And up to several hundred publications ,computer simulations and animations In different subjects, scientific papers in mathematics , computer graphics, numerical analysis, astrophysics and Particle Atomic physics. Tony does research general together with prof Ewert Bengtsson, Prof Anders Hast and Physicist Bo Thelin and the crew of Barrera Science Lab. Tony Barrera have been working for the company AB Consonant with implementation of the Fast Fourier Transform, FFT , and as a computergrahics researcher at Cycore AB (Webbgraphics). Constructor of about 10 - 20 different Graphics Engines , Assembler ,Basic, Pascal and/or C++ computer languages. Started with mahematics and science at age 3, got the first Astronomy book (from mother Elisabeth Mercadal) at 9, the first Chemistry set at 10 , Chief (head) of Barrera Science Lab.

Abstract

The global demand for plastics continues to grow, leading to serious environmental issues and health concerns, while the need for increased plastic production further adds to the problem. Conventional methods for producing and managing plastic waste, such as recycling and disposal, fall short in providing sustainable solutions. In this context, microalgae are emerging as a promising alternative for developing sustainable materials. Microalgae not only have the capability to biodegrade plastics by breaking down plastic polymers through enzymatic processes, but they also serve as a renewable resource for creating bioplastics. This review focuses on the potential of microalgae in the biodegradation of plastics and the production of algae-based biodegradable bioplastics. Notably, microalgae-derived bioplastics offer properties like fossil fuel-based plastics, but with enhanced biodegradability. Key techniques, including bioplastic synthesis and material blending, are examined to assess their viability. This study aims to highlight the promise of microalgae as a sustainable solution, offering insights into innovative approaches for plastic waste management and future applications in the bioplastics industry. This review also evaluates the economic feasibility, scalability, and sustainability of microalgae-based bioplastics, while exploring emerging innovations and market trends in this field. The aim is to provide a thorough overview of the role of microalgae in bioplastic production, covering everything from optimizing production methods to addressing commercial challenges. Ultimately, this review contributes to understanding how microalgae can help create a more sustainable future for the plastics industry.

Biography

Amarnath Krishnamoorthy is doing his PhD in biomass conversion to energy at the School of Computing, Engineering & Physical Sciences, University of the West of Scotland (United Kingdom). His research explores the implementation of pre-treatment methods in microalgal species for cell disruption, and his research added value to the third generation of biofuels. His dissertation deploys recent studies of microalgal pre-treatment in biodiesel production and literature and leads questions about the upcoming phases of dewatering approaches and research exploration

Abstract

Advanced materials based heterogeneous catalysis involving photochemical and photoelectrochemical water splitting is an ultimate source of hydrogen generation as renewable green energy for tackling the ongoing fuel crisis. Carbon based materials are ideal for overall water splitting as a result of the excellent alignment of its band edges with water redox potentials. However, a single catalyst with a limited number of active sites does not exhibit significant photo/electrocatalytic activity for hydrogen production. Therefore, we have developed the semiconductor heterostructures of carbon materials with oxides, sulphides, selenides, other TMCs/TMDs NPs and QDs as the highly efficient nanocatalysts for enhanced hydrogen evolution reactions. The monophasic heterostructures have been designed in different weight ratios with fairly uniform distribution of nearly spherical particles and high specific surface area which creates an interfacial charge transfer between two semiconductors. As prepared heterostructures showed significant hydrogen evolution which is evident by observing high apparent quantum yield, low onset potential, lower overpotential and high electrochemical active surface area that will be presented in detail.

Biography

Prof. Tokeer Ahmad graduated from IIT Roorkee and Ph.D. from IIT Delhi. Presently, he is a full Professor at the Department of Chemistry, Jamia Millia Islamia, New Delhi since 2019. Prof. Ahmad has supervised 16 PhD’s, 84 postgraduates, 10 projects, and published 209 research papers, one patent, and three books with research citations of 8585, h-index of 55, and i10-index of 167. Prof. Ahmad is an active reviewer of 188 journals, delivered 195 Invited talks, evaluated 67 external doctoral theses, and presented 133 conference papers. Prof. Ahmad is the recipient of CRSI Bronze Medal, MRSI Medal, SMC Bronze Medal, ISCAS Medal, Inspired Teacher’s President of India Award, DST-DFG award, Distinguished Scientist Award, Maulana Abul Kalam Azad Excellence Award of Education, Teacher’s Excellence Award, Elected Member of National Academy of Sciences India and Fellow of Royal Society of Chemistry (FRSC), UK. Prof. Ahmad has been figured in World's Top 2% of Scientists for consecutive five years since 2020 in both coveted lists including career-long by Stanford University, USA.

Abstract

Electric load forecasting is a technique supporting smart grid objectives. It refers to predicting the electricity demand at aggregated levels which is mandatory for the smart grid's proper functioning and balancing electricity generation and power consumption at all times. This paper proposes multiple output sparse Gaussian processes with multiple kernel learning for hourly day-ahead short-term electric load forecasting using load, dew point, and temperature values. The mean absolute percentage error metric is used to evaluate and compare the performance of the proposed multiple output sparse Gaussian processes with multiple kernel learning and the persistence method in three scenarios (using load and dew point values, using load and temperature values, and finally, using load, dew point, and temperature values from previous days). The results showed that the proposed method achieved much lower MAPE values than the persistence method.

Biography

Alireza Ghasempour has been a faculty member in the Information and Communications Technology department at the University of Applied Science and Technology. His areas of interest include smart grids, the Internet of Things, machine learning and deep learning techniques, optimization methods, smart cities, and wireless communications and networks. He has published several papers in these areas in peer-reviewed journals and international conferences.