The document discusses physics formulas related to speed, time, force, motion, energy, and power. It asks the reader to translate the formulas into Russian and includes an attachment of a video about Newton's Second Law of Motion.
The document discusses physics formulas related to speed, time, force, motion, energy, and power. It asks the reader to translate the formulas into Russian and includes an attachment of a video about Newton's Second Law of Motion.
Nanotechnology involves understanding and controlling matter at the nanoscale, between 1 to 100 nanometers. At this scale, materials can exhibit unusual physical and chemical properties. The field began with Richard Feynman's talk in 1959 and has advanced since the invention of the scanning tunneling microscope in 1981, allowing observation and control of individual atoms. Today, nanotechnology allows scientists to deliberately create materials with enhanced properties like strength, reactivity and light control for uses in products like bandages, toothpaste and more that we encounter every day.
Nanotechnology involves understanding and manipulating matter at the nanoscale level, between 1-100 nanometers. Materials at this scale can exhibit different properties than at larger scales due to quantum mechanics. While nanoscale materials were used for centuries, the modern field began in the 1980s with inventions like the scanning tunneling microscope that allowed visualization of individual atoms. Today, nanotechnology has applications in medicine such as using lasers to fuse chicken meat or potentially repair arteries. It works by utilizing properties that naturally occur at the nanoscale level.
Nanotechnology involves understanding and controlling matter at the nanoscale, between 1 to 100 nanometers. At this scale, unique phenomena occur that enable novel applications. Richard Feynman first outlined manipulating and controlling atoms and molecules in 1959. Later, Professor Norio Taniguchi coined the term "nanotechnology". Areas of nanotechnology application include medicine, engineering, industry, and more. Products using nanotechnology powders are common, like silver nanoparticles in wound dressings and nanoclay in power cable insulation.
Nanotechnology involves understanding and controlling matter at the nanoscale, between 1 to 100 nanometers. At this scale, materials can exhibit unusual physical and chemical properties. The field began with Richard Feynman's talk in 1959 and has advanced since the invention of the scanning tunneling microscope in 1981, allowing observation and control of individual atoms. Today, nanotechnology allows scientists to deliberately create materials with enhanced properties like strength, reactivity and light control for uses in products like bandages, toothpaste and more that we encounter every day.
Nanotechnology involves understanding and manipulating matter at the nanoscale level, between 1-100 nanometers. Materials at this scale can exhibit different properties than at larger scales due to quantum mechanics. While nanoscale materials were used for centuries, the modern field began in the 1980s with inventions like the scanning tunneling microscope that allowed visualization of individual atoms. Today, nanotechnology has applications in medicine such as using lasers to fuse chicken meat or potentially repair arteries. It works by utilizing properties that naturally occur at the nanoscale level.
Nanotechnology involves understanding and controlling matter at the nanoscale, between 1 to 100 nanometers. At this scale, unique phenomena occur that enable novel applications. Richard Feynman first outlined manipulating and controlling atoms and molecules in 1959. Later, Professor Norio Taniguchi coined the term "nanotechnology". Areas of nanotechnology application include medicine, engineering, industry, and more. Products using nanotechnology powders are common, like silver nanoparticles in wound dressings and nanoclay in power cable insulation.
2. «Предметы математики и физики настолько серьезны, что надо не
упускать случая сделать их занимательными". Б. Паскаль
«Радость видеть и понимать есть самый прекрасный дар природы»
А.Эйнштейн.
"Среди всех наук для меня особую прелесть всегда представляла физика"
Р. Пайерлс.
"Без знания математики нельзя понять ни основ современной техники, ни
того, как ученые изучают природные и социальные явления".
А.Н. Колмогоров.