Global Summit on Nanoscience and Technology January 18-19, 2023 Vancouver, Canada

The recent research which was awarded Kavli Prize in Nanoscience was on inventions of aberration-corrected lenses used in electron microscopes which enabled the researchers worldwide to see the chemical composition and structure of materials in three dimensions. The goal of nanoscience is to generate materials and devices assembled with precision on atomic scale to get novel functionalities. Hence, need to overcome several challenges in its research.

Targeting infectious diseases is possible with nanoparticle design. Anti-inflammatory medications could fight bacterial and viral infection, while nanomaterials may target the lungs to deliver powerful antibiotics. Nanoparticles may help treat neurological diseases like Parkinson's and Alzheimer's more successfully as well as arthritis. Advances in the newly-emerging discipline of immuno-oncology are likely to trigger the immune system to attack tumour cells. 

With the expansion of "nano-enabled smart gadgets" in industries including telecommunications, consumer goods, and information technology, technology is anticipated to become more widely used. Advances in nanoscience could improve food safety and reduce food contamination. It may be possible to develop sensor technologies that take use of alterations in nanostructures' surfaces to find disease-causing pathogens before they spread. Additionally, advancements in agrochemicals may result from nanoscale sensor technology

Desalination and purification of water are processes that utilise nanotechnology principles, and nanotechnology is anticipated to have a significant impact on the world's ability to supply clean water. New innovations can help decontaminate the water and thereby reducing the water shortage in major cities of the world. It will bring new revolution in the recycling of waste water.

Magic-angle twisted grapheme, was first discovered in 2018, made of three sheets of it, with each sheet twisted at an angle f 1.05 degrees. The resulting structure has unusual properties, which can be turned into an insulator or semiconductor based on number of electrons aged. It can be used in quantum information and quantum science. More research needs to be done to study superconducting gap profiles of this material

The world's smallest flow-driven motors have been built by scientists. They developed a self-configuring DNA flow-driven rotor that transforms energy from an electrical or salt gradient into effective mechanical work, drawing inspiration from both biological motor proteins and famous Dutch windmills. The findings provide fresh avenues for developing nanoscale active robotics.  There have been attempts to construct such rotary nanomotors synthetically from the ground up for the past seven years.

A wide range of medical applications for nanomaterials, biological devices, nanoelectronics, biosensors, and maybe future applications for molecular technology are covered within the field of nanomedicine. Nanomaterials are commonly functionalized to interface with biological molecules and structures because their size is compatible with the majority of them. The use of nanomaterials is frequently advantageous for in vitro and in vivo medical science analyses and applications, and their integration with biology has resulted in the development of improved diagnostic tools, therapeutic applications, analytical tools, distinction agents, and drug delivery vehicles.

Due to the same activity ranges of nanoparticles (NPs) and viruses, applied science is a potent tool for creating immunizations and immunological engineering. A current area of study in the realm of nanomedicine is the relationship between the adaptability of different nanosystems and the capacity of infectious agent vectors to convey genes and have a high infectivity. The most secure alternative to cutting-edge immunising agent creation technologies may be applied science since nanoparticles will replicate the structure and functional features of viruses.

Due to the same activity ranges of nanoparticles (NPs) and viruses, applied science is a potent tool for creating immunizations and immunological engineering. A current area of study in the realm of nanomedicine is the relationship between the adaptability of different nanosystems and the capacity of infectious agent vectors to convey genes and have a high infectivity. The most secure alternative to cutting-edge immunising agent creation technologies may be applied science since nanoparticles will replicate the structure and functional features of viruses.

Applications of nanotechnology essentially deal with particles that are one to many nanometers broad in size. This particle size offers some fascinating surface and chemical properties that make it suitable for inventive uses. Engineering science proponents assert that there is no question that research in this area could offer solutions to some of the most urgent problems that the world is currently facing, such as ensuring that developing populations have access to safe drinking water while also addressing issues with health, energy, and business.

• Nanomaterials and water filtration
• Bioactive nanoparticles for water disinfections
• Self-assembled monolayer on mesoporous supports (SAMMS)
• Bimetallic iron nanoparticles

Using building blocks with varying nanometer-sized changes, nanocomposite seeks to produce novel materials with amazing flexibility and improvements in their physical properties. This definition encompasses copolymers, colloids, gels, and porous media in its broadest sense. It is also widely used to describe solid mixes that have a bulk matrix and a nano-dimensional component with unique properties resulting from variations in their chemistry and structure.

Despite applied science's rapid expansion over the past twenty years, it is still recognised as a cutting-edge technology, and the impact of nanomaterials on human health has not yet been thoroughly examined. Nanoscale materials have completely different chemical properties from the supply material (thereby ever-changing their reactivity in biological systems). It raises the question of whether current techniques for figuring out the detrimental effects of NMs are still accurate. Using DNA-tagged gold nanoparticles to sequence the genomeNanotechnology Regulations

• Carbon Nanotube Filters
• Strategic and Nuclear Disarmaments
• Disaster management.

Small, powerful, and reasonably priced developing technologies are the main focus of this sector. Sensors, nanoelectronics, diagnostic equipment for use in medicine, and photonic lasers are a few examples. Both of these broad topics are included in the category of engineering science. They could be in the fields of biology, chemistry, organic chemistry, materials science, physics, geology, technology, engineering, data storage, and the natural and social sciences.