Track Categories
The track category is the heading under which your abstract will be reviewed and later published in the conference printed matters if accepted. During the submission process, you will be asked to select one track category for your abstract.
Material chemistry involves the use of chemical compounds in the synthesis of energy or useful substances, such as magnetic, physical, chemical, or regulatory processes. It involves the formation, processing and understanding at the molecular level of these substances. It shows the chemistry of different materials and its specific chemical & mechanical properties. Semi-conducting soft materials with metal organic framework provides a compact structure & strength.
Nanotechnology is the process of atomic, molecular, and supramolecular levels. An interesting feature of nanotechnology is that the properties of many materials change as the size of their size approaches nanometres. Materials Scientists and engineers work to understand those changes in materials and use them to process and process things at the Nano scale level. The field of synthetic materials includes the discovery, shape, structure, and application of Nano scale materials. Nano materials research uses scientific-based approach to Nano-technology, influencing advances in metrology and synthesis applications of micro fabrication research. Structured objects at the Nano scale o level have different optical, electronic, or mechanical properties
Biological Chemistry highlights recent advances in regulatory and molecular biology, signal transduction, biochemistry and biomarkers for chronic diseases, and bioinformatics. It highlights the most important issues in the world of medicine: diabetes, obesity and malnutrition, cancer, and cardiovascular disease, and discusses the role of nutrition and exercise in medicine.
Biomaterials from a health care perspective can be defined as building blocks that have specific novel properties that make them ready to quickly interact with living tissues without triggering an overactive reaction. Biomaterials worked for mankind in ancient times but subsequent evolution made them more versatile and increased their use. Biomaterials have transformed areas such as bioengineering and tissue engineering to create strategies to combat life-threatening diseases. These ideas and techniques are used in the treatment of various diseases such as heart failure, fractures, severe skin damage, etc. Research is being done to improve existing methods and to develop new methods.
Organic Materials Chemistry plays a vital role in the field of research that leads to the development of high-quality organic and polymeric materials by investigating the process of assembling, processing, controlling, marking, and establishing structural relationships between these materials. Characteristic properties were investigated and related applications will be considered to have played an essential role. Structural chemistry involves the determination of a chemical structure using a variety of metallic techniques and the acquisition of the desired results by a detailed study of the conclusions taken during the analysis.
Inorganic Materials Chemistry involves the study of elements with metal or non-metallic structures. Most materials are metals such as alkali metals, alkaline earth metals, flexible metals, and so on. The non-metallic phase mainly consists of gases in the environment, such as hydrogen, oxygen, and other elements, including fine gas. All of this is divided into the production of advanced inert compounds that are dependent on a particular fusion process. Inorganic nanotubes have a composition of metal oxides such as carbon nanotube.
2D building materials have been changing the science and technology of modern society in an unprecedented way. Their chemical properties are extremely important because they encompass the real scientific aspects of cell formation, synthesis, imitation, and chemical reactions. Most importantly, material chemistry provides an irreplaceable way to use physical properties and the corresponding use of 2D materials on small, optical and large scales.
The rapid development of 3D printing in analytical instrumentation, in particular, in making prototypes of new equipment and production components with complex internal configurations, has been proven to be excellent performance. The use of 3D printing for the production of new high-resolution analytical devices, such as compact chromatographic columns for high-performance liquid chromatography, flow tools and flow cells for mechanical devices, toxic chemical processing devices and various integrated devices allow significant improvements in analysis.
Optical fibres are widely used to transmit light from meters to miles. Synthesis, classification and theoretical understanding of the Nanostructual materials which emit or interact with electromagnetic or quasiparticles with similar properties. Advanced research includes dielectric and semiconductor equipment, plasmonic & Meta materials and light emitters. Research based on applications using photonic materials has been covered by other research areas.
Photonics can be regarded as one of the key technology-enabled technologies, and is often integrated with micro- and Nano electronics, biotechnology or nanotechnology. The field of photonic materials is extremely wide, including well-shaped glass surfaces and semiconductor materials, polymer materials, Nano composites and metamaterials, and bio-photonic materials. Design technology plays a very important role in the development of new photonic building materials and devices. Compatible with standard CMOS technologies that support the creation of modern integrated circuits
Over the past two decades the field of molecular magnetism has shifted rapidly from the development of new magnetic resins to high-temperature molecules, to the more complex magnetic fields with one or more interesting functional elements (strong magnetic elements with variable, or dual-materials), in the investigation of Nano magnetic molecules and other nanostructures that show quantum effects, and finally on the use of targeted applications.
Electrochemistry as it works in biological systems especially in relation to chemical and physical processes (such as electron transfer), as it relates to biological, biomedical, and biotechnological applications (such as biosensors or immunoassays). Bio-electrochemistry is a multidisciplinary field, influencing many areas in chemistry, from the storage of energy to understanding biological processes at a basic level. Given the rapid development in the field in recent years, this apparent problem aims to highlight the latest advances in all aspects of bio-electrochemistry.
The novel materials will serve as the basis for the formation of sensors based on Microscopic design and Nano probes for biological applications and scanning microscopy for testing. Now fast-track technology toolboxes and remedies are available, which will have a huge impact on the MEMS and NEMS sector (cost reduction, design simplicity and advanced facilities).
Industrial chemistry continues with advances in science and technology. It incorporates other advanced methods such as biotechnology, microelectronics, and pharmacology as well as material science. It deals with physical and chemical processes regarding the conversion of raw materials into useful products for humanity. Chemicals or chemical materials are a wide range of chemicals including polymers, many petrochemicals and compounds, other raw materials and basic industries, abnormal chemicals, and fertilizers. Major industrial demand includes rubber and plastic products, textiles, clothing, petrol filters, gin and paper, and key metals.
Chemistry research analysers use the tools and methods used to classify, identify, and evaluate matter. Tool methods can be used to separate samples using chromatography, electrophoresis or field flow fractionation. After that quality and quantity analysis can be done, often with the same metal and can use simple connections, thermal connections, electric fields or magnetic fields.
Scientists and researchers are developing new methods of precisely observing and controlling the activity of atoms and cells; new techniques for combining atomic and molecular performance in physical structures; and new ways of building the elements of a defined structure, structures and function. Sustainable economic and environmental technologies will require new methods of chemical science and technology. This leads to the charge for cellular construction of economically viable products and has little impact on the environment, while being acquired by hand, recycled and recycled at the end of their useful life.