7th International Conference on
Nanomaterials Research

Nanotechnology has the potential to revolutionize healthcare by enabling the development of new diagnostic tools, targeted drug delivery systems, and regenerative therapies. Here are some examples of how nanotechnology is being used in healthcare. Nanoparticles can be engineered to carry drugs directly to diseased cells or tissues, reducing the need for high doses and minimizing side effects. This approach is particularly promising for cancer treatment, as nanoparticles can accumulate in tumors and release drugs directly into the cancer cells. While nanotechnology offers many exciting opportunities for improving healthcare, there are also potential risks associated with the use of nanoparticles, such as toxicity and environmental impact. Further research and regulation are needed to ensure the safe and effective use of nanotechnology in healthcare.

This track could cover a range of topics, including the fundamental physics principles that govern the behavior of nanomaterials, as well as the engineering approaches used to design and manipulate these materials. Sessions could cover topics such as quantum mechanics, electromagnetism, and thermodynamics, as well as specific applications of nanomaterials in areas such as energy, electronics, and biomedicine. Other possible session topics could include nanomechanics, nanophotonics, and computational methods for studying nanoscale phenomena. The track could also include invited talks from experts in both physics and nanomaterials, as well as poster sessions and other opportunities for networking and collaboration.

Nanomaterials are materials with structures or features that have dimensions on the nanometer scale, typically ranging from 1 to 100 nanometers. They can be engineered to have unique physical, chemical, and mechanical properties that differ from their bulk counterparts. In the context of aerospace structures, nanomaterials are materials that are used to build aircraft, spacecraft, or related components, and which have been specifically designed or modified at the nanoscale to enhance their performance in terms of strength, stiffness, toughness, thermal stability, or other key properties. Examples of nanomaterials that are commonly used in aerospace applications include carbon nanotubes, graphene, nanoceramics, and nanocomposites. These materials offer the potential to create lighter, stronger, and more durable aerospace structures, which can improve fuel efficiency, reduce emissions, and enhance overall performance.

Computational and Theoretical Nanoscience is a branch of science that uses computational methods, models, and theories to study the properties and behavior of nanomaterials and nanosystems. This field combines principles from physics, chemistry, materials science, and computer science to develop computational models and simulations that can predict and explain the behavior of nanomaterials at the atomic and molecular scale. Theoretical nanoscience focuses on developing theoretical frameworks and mathematical models to describe the fundamental principles governing the behavior of nanomaterials, while computational nanoscience involves using computer simulations and modeling techniques to study nanomaterials and nanosystems. The ultimate goal of Computational and Theoretical Nanoscience is to gain a better understanding of the properties and behavior of nanomaterials, and to use this knowledge to design new materials and devices with desired properties and functionality.

Smart materials are able to react to an external stimulus or a change in any physical activity, show a response in line with the change, and then revert to their initial state after the stimulus has been removed. According to the type of stimulus and response, smart material properties are categorized, and the calibre of the materials will change as we move into a new era. It is typically a hybrid material, which increases function reliability and application compatibility. This should be discussed in Nanomaterials Conference 2023 in a clear and concise manner

Biomaterials are substances that are primarily employed in medicine for tissue replacement or repair. It significantly affects tissue distribution and cell growth. As a result, amplify, who has redefined treatment and the development of bionic devices in the fields of tissue engineering and pharmaceuticals, has created one of these bio-compatible materials, such as implants. This should be discussed in Nanomaterials Conference 2023 in a clear and concise manner

A polymer or copolymer with nanoparticles or nanofillers dispersed in the polymer matrix is called a polymer nanocomposite (PNC), and nanoscience is the study and application of nanotechnology in this field. This varies depending on the shape (platelets, fibres, spheroids, for example), but at least one dimension needs to fall within the 1 to 50 nm range. Controlled compounding and dispersion phase stabilisation are needed. This should be discussed in detail at the Nanomaterials Conferences 2023.

Nanotechnology and biotechnology have advanced significantly in recent years, according to computational studies on NanoParticles. However, some significant obstacles were also noted, such as the need for a deeper understanding of the behaviour of NanoParticles in vivo and the creation of more potent NanoParticle therapeutics. Computing efforts are evolving into a crucial tool for addressing both of these issues as well as for facilitating and accelerating translational research based on Nanotechnology in general. Nano informatics is a brand-new area of study that involves managing raw data, analysing data from biomedical applications, simulating the interaction of NanoParticles with biological systems, and integrating informatics to lay the groundwork for computational Nanomedicine. It is widely used in biology and Nanotechnology. This should be discussed in Nanomaterials Conference 2023 in a clear and concise manner

Nanomaterials have been used in various applications in civil engineering, such as enhancing the mechanical properties of construction materials, improving the durability of infrastructure, and developing innovative building designs. Overall, nanomaterials have the potential to revolutionize the field of civil engineering by enabling the development of stronger, more durable, and more sustainable infrastructure. In this session the tracks and subtracks are not exhaustive, but they can provide a starting point for exploring the various applications of nanomaterials in Civil Engineering.

The process of atomic, molecular, and supramolecular levels is known as nanotechnology. A fascinating aspect of nanotechnology is how many materials' characteristics alter as they go closer to the nanometer range in size. Materials Scientists and engineers study these changes in nanomaterials in order to employ them in processing at the nanoscale. The discovery, development, structure, and use of nanomaterials are all included in the field of synthetic materials. In order to develop metrology and synthesis applications of micro fabrication research, nanomaterials research adopts a scientifically grounded approach to nanotechnology. Nanoscale structures can have various optical, electrical, or mechanical characteristics.

Nanoscience is the study of structures and processes that can be controlled and is applicable to all other scientific disciplines, including biology, physics, chemistry, material science, and engineering. Electronics, medical technology, energy generation, and the development of biomaterials are just a few of the many fields where nanotechnology is expanding its manufacture of materials and systems. At the nanometer scale, a physico - mechanical, electromagnetic, optical, and physical and chemical properties are altered, enabling the development of new useful materials.

Nanomedicine is the use of manmade nanodevices or nanotechnology for the molecular monitoring, conservation, construction, and management of human biomolecules. It is a field of medicine that uses nanotechnology prominence and resources to treat and prevent disease. Biocompatible nanoparticles and robotics are used in nanomedicine for a myriad of purposes, including drug delivery, sensing, and diagnosis in life forms.

Nanoelectronics is centred on the use of nanotechnology to the field of electronics, electronic components, and research for the advancement of electronics comprising visibility, dimension, and power consumption of the devices for practical use. It discusses the semiconductors, single-dimensional nanotubes, nanowires, hybrid materials, and other materials quantum mechanical characteristics. Advanced nanoelectronics have numerous applications and are particularly helpful for identifying pathogens and illness biomarkers. Point-of-care monitoring consequently increases prominence as a result of nanoelectronics' engagement. Nanophotonics can be defined as the science and engineering of illumination and light-matter interactions that occur on wavelength and sub-wavelength scales where the chemical or structural, physicochemical characteristics of naturally occurring or artificially created nanostructured matter controls the interaction. 

The fusion of chemistry and nanoscience is called nanochemistry. Building blocks that depend on size, surface, form, and defect qualities are synthesised as a result of this process. Engineering, biology, and medicine are merely a handful of the fields where nanochemistry has applications, along with the sciences of chemistry, materials, and physics.

For smart machines or robots at the minuscule scale of a nanoscale, nanorobotics is an emerging field. Nanorobots typically come in sizes between 0.1 and 10 micrometres. Carbon in the form of fullerene/diamond nanocomposites will be the primary ingredient that can be utilised because of their durability and chemical inertness. Advancements of nanorobotics can be widely used in the fields of medicine. They might be applied for haematology, biohazard defence, cancer treatment, etc. In addition to these, nanorobotics is used in the disciplines of electronics-communication engineering, molecular chemistry, automotive and aerospace, and automation industries.

A combination of nanoscience and biotechnology is known as nanobiotechnology. The use of nanotechnology in the life sciences is included in this. The term "nanobiotechnology" is used to characterize the fusion of biological research and numerous nanotechnology fields. Characteristics that are enhanced with nanobiology include that associated to nanoscale, nanodevices, and nanoparticle phenomena that occur in the field of nanotechnology. Nanobiotechnology examines the special physicochemical and biological characteristics of nanostructures as well as their uses in industries like agriculture and health.

Nanotechnology cancer treatments include the identification and elimination of cancer cells prior to subsequent growth into malignancies, as well as the eradication of cancerous tissue with minimal toxicity to healthy tissue and organs. Nanotechnology presents immense potential for imaging, diagnostics, and cancer treatment, but it is challenging to overcome the translational gap. The majority of research in nanomedicine is concerned with cancer. Because leaky vasculature and decreased lymphatic outflow are prominent in solid tumours, the higher permeability and retention effect causes nanoparticles to concentrate locally. Because of this, nanoparticles are perfect for delivering diagnostic and/or imaging agents, chemotherapeutics, oligonucleotides, and immune regulators to enhance their therapeutic index. The majority of approaches to treat cancer using nanotechnology are primarily in the research or development phases.

Pharmaceutical nanotechnology focuses on creating customised drug delivery systems with cutting-edge technologies. The distribution, metabolism, rate of absorption, and excretion of the medication are all positively impacted by the drug delivery method. The medicine can attach to the target receptor and affect its signalling and activity according to the drug delivery system. Pharmaceutical nanotechnology covers nanomaterials and tools for drug delivery, diagnostics, imaging, and biosensors as well as pharmacy-specific nanomaterial applications of nanoscience.

Nanosensors are the tools that may be used to check for the presence of chemical and nanoparticles, or to track physical characteristics like temperature, on the nanoscale. Precision agriculture, urban farming, plant nanobionics, SERS-based sensors, prognostics and diagnostics, and numerous industrial applications are just a few of the domains where nanosensors are advancing quickly. Combining nanosensors with other practical technologies, including MEMs and microfluidic devices, is becoming more and more popular.

Nanofluidics is the study of the manipulation, control, and behaviour of fluids that are tolerant to nanometer-sized objects, and nanofluids are a family of fluids that contain nanoparticles. Nanoporous membranes, single nanopore transport, nanoconfinement, and the concentration polarisation functionality are the four main methods that nanofluidics can be used for analysis. It would be possible to manage nanoscale objects and create distinctive nanomaterials in the liquid phase by using ultra-small restricted spaces, well-defined nanofluidic systems, and unexpected effects. These new methods and technologies include Lab-on-a-chip and NCAMs. Thus, nanofluidics will open up new possibilities for the study of materials.

Metallurgy, in its broadest sense, is the process of obtaining metallic compounds in their purest form. Metallurgy entails comprehending the physical and chemical behaviour of metals from the viewpoint of material science. Alloys, which entail the fusion of two or more metals under specific conditions to create a metal with enhanced properties, are a result of the development of metallurgy. The study of metallurgy is separated into several divisions, such as extractive, physical, and mechanical metallurgy, which focuses on the more extensive classification and design of metals. Metallurgy is concerned with combining and designing metals in order to create a product that meets human needs.

Soft materials have a propensity to distort when exposed to higher temperatures or even when the environment is at typical room temperature. The integrative property of polymers and gels under specified or undefined conditions makes them soft materials. This is caused by the product's chemical substances weak molecular interactions with one another. Soft materials are advantageous in the fields of pharmacology and biotechnology because they facilitate the formulation of medications in liquid or semi-solid forms and enhance drug delivery mechanisms.

Carbon atoms are securely bound in a hexagonal honeycomb lattice to form the monolayer known as graphene. The lightest, strongest, and thinnest compound ever discovered is graphene. At ambient temperature, graphene is the best conductor of both electricity and heat (studies have indicated that graphene's electron mobility can reach values of more than 200,000 cm2 V s1). It has consistent light absorption across the visible and near-infrared spectrums. Electronics, transportation, health care, energy, defence, and desalination are just a few of the fields where graphene research is having a significant impact. The potential of graphene is only constrained by our imagination because it is capable to wide extend.

In other terms, carbon nanotubes (CNTs) are rolled-up sheets of graphene. They are cylindrical molecules made of carbon atoms bound together in hexagonal shapes. Among the most promising biopolymers for nanotechnology, nanotubes have a variety of intriguing characteristics and prospective uses in industry.

The study of nanostructured materials and phenomena, which can be applied to all other scientific disciplines including biology, physics, chemistry, material science, and engineering, is known as nanoscience and nanotechnology. The fast development of that field has aided in the change of conventional industries like food and agriculture. Nanotechnology is being used in virtually every field, which improves and enhances our quality of life.

When nanoparticles, nanotechnology tools, or strategies are employed during food production, processing, or packaging, it is considered to be the use of nanotechnology in food. It excludes food that has undergone atomic modification or that made using nanotechnology. Future uses of nanotechnology might include food products containing nanostructures, nanoscale or nano-encapsulated food additives, or better food packaging. However, numerous foods, particularly food additives, naturally include nanoscale particles.

Green nanotechnology is described as nanotechnology that improves environmental sustainability and benefits the environment. It entails creating eco-friendly nanoproducts, using less energy during production, employing eco-friendly materials, enabling product recycling after use, and utilising nanoproducts to promote sustainability.

Nanomaterials behaviour at the nanoscale can differ from that at the macroscale. Despite the fact that many applications and fields could benefit from some of these revolutionary nano characteristics, others could be dangerous. In other words, this novelty may pose threats to human health and the environment, according to the burgeoning field of nanotoxicology.