"Bu sunum Gazi Üniversitesi Nanoteknoloji ve Uygulamaları dersinde öğrencim Rabia ŞANKAZAN tarafından hazırlanmıştır. Doğa da nano teknoloji, Geko nasıl tutunur, Kelebeğin kanatlarıve nano boyutlar, Nano ayaklar, Titiz lotus çiçeği ve kendi kendini temizleyebilme özelliği, Kum balığı çölde nasıl yaşar ve nasıl denizde yüzer gibi kumun içinde yüzer ve o güneş altında ve kum içinde dahi pırıl pırıl parlar; tüm bunların açıklamasını bu sunumda bulabilirsiniz. Prof.Dr. İbrahim USLU"
Nanoteknolojiyi insanlar mağara devrinden beri kullanmaktaydı. Devamlı ateş ve dolayısıyla külleriyle ilgilenen insanlar, günümüze kadar gelen mağara resimlerinde nanokarbon küllerden boyalar kullanmışlardı. Romalılar ürettikleri kupalarda, kiliselerin vitray resimlerinde nanoteknoloji kullanılmıştı. Bu sunumda günümzde de tıpta, askeri amaçlarla, elektronikten, çevresel uygulamalara kadar nanoteknolojinin kullanımı hakkında bilgileri verilmektedir. Normalde tüm slatlarda animasyonlar söz konusudur ancak maalesef siz burada slaytları animasyonsuz göreceksiniz. Bu sunumun animasyolu halini ücretsiz olarak Prof.İbrahim Uslu'dan temin edebilirsiniz. Ülkemin bilimsel gelişimine küçük bir katkı olarak da düşünülebilir. Nanobilim, Nanoteknoloji Ve Nanotıp Derneği Başkanı Prof.Dr. İbrahim USLU
Introduction
History
Types of Nanomaterials
Properties of Nanomaterials
Synthesis and processing of Nanomaterials
Advance nanomaterials
Fullerenes
Carbon nanotubes
Nanowires
Polymer nanostructures
Quantum dots
"Bu sunum Gazi Üniversitesi Nanoteknoloji ve Uygulamaları dersinde öğrencim Rabia ŞANKAZAN tarafından hazırlanmıştır. Doğa da nano teknoloji, Geko nasıl tutunur, Kelebeğin kanatlarıve nano boyutlar, Nano ayaklar, Titiz lotus çiçeği ve kendi kendini temizleyebilme özelliği, Kum balığı çölde nasıl yaşar ve nasıl denizde yüzer gibi kumun içinde yüzer ve o güneş altında ve kum içinde dahi pırıl pırıl parlar; tüm bunların açıklamasını bu sunumda bulabilirsiniz. Prof.Dr. İbrahim USLU"
Nanoteknolojiyi insanlar mağara devrinden beri kullanmaktaydı. Devamlı ateş ve dolayısıyla külleriyle ilgilenen insanlar, günümüze kadar gelen mağara resimlerinde nanokarbon küllerden boyalar kullanmışlardı. Romalılar ürettikleri kupalarda, kiliselerin vitray resimlerinde nanoteknoloji kullanılmıştı. Bu sunumda günümzde de tıpta, askeri amaçlarla, elektronikten, çevresel uygulamalara kadar nanoteknolojinin kullanımı hakkında bilgileri verilmektedir. Normalde tüm slatlarda animasyonlar söz konusudur ancak maalesef siz burada slaytları animasyonsuz göreceksiniz. Bu sunumun animasyolu halini ücretsiz olarak Prof.İbrahim Uslu'dan temin edebilirsiniz. Ülkemin bilimsel gelişimine küçük bir katkı olarak da düşünülebilir. Nanobilim, Nanoteknoloji Ve Nanotıp Derneği Başkanı Prof.Dr. İbrahim USLU
Introduction
History
Types of Nanomaterials
Properties of Nanomaterials
Synthesis and processing of Nanomaterials
Advance nanomaterials
Fullerenes
Carbon nanotubes
Nanowires
Polymer nanostructures
Quantum dots
This document discusses nanotechnology and its potential applications and impacts. It begins by defining nanotechnology as the manipulation of matter on an atomic, molecular, and supramolecular scale between 1 to 100 nanometers. The document then outlines some of the key people involved in developing nanotechnology, potential applications in areas like medicine, materials, and computing, as well as both advantages such as new materials and industrial uses and disadvantages such as potential health risks. It concludes by stating that nanotechnology will change almost every human-made object in the next century and inspire future scientists.
Nano-material and its benefits in the Environmental ApplicationMusaddiq Ali
Nanomaterial is defined as material with dimensions less than 100nm. Nanotechnology involves manipulating nanomaterials to create new large-scale materials with improved properties. Nanoparticles can be organic such as polymeric or inorganic such as gold. Nanomaterials provide benefits in environmental applications such as energy savings through weight reduction and optimized function in vehicles and buildings. They can also reduce use of raw materials through miniaturization.
This document discusses various applications of nanoparticles in medical fields, industries, and environmental issues. Nanoparticles can be used to more effectively deliver drugs to specific target areas in the body. They are also being researched for cancer therapy by using light-activated nano shells to kill tumor cells. In industries, nanoparticles can improve food packaging, textiles, cosmetics, sports equipment, construction materials like cement and steel, and wood products. They are also being applied to environmental cleanup by breaking down oil spills and removing pollutants from air and water.
örnek bir güneş enerji santrali raporu . bu rapor ile bazı başvurular yapılabilir. http://www.enerjibes.com/gunes-enerji-santrali-raporu-nasil-hazirlanir/
This document discusses the use of nanotechnology in civil engineering applications. It begins by defining nanotechnology and nanoscale materials like carbon nanotubes and nano-silica. It then discusses several uses of nanotechnology in concrete to improve strength, durability, and permeability. The document also discusses uses of nanotechnology in steel, wood, stone, and coatings/paints to provide benefits like increased strength, corrosion resistance, self-cleaning properties, and insulation. Specific products discussed include Cuore concrete, SandvikNanoflex steel, MMFX2 steel, and the Nansulate insulation coating.
Nanotechnology involves manipulating matter at the nanoscale, which is approximately 100 nanometers or smaller than the width of a human hair. It has applications in electronics, automotive, engineering, medicine, cosmetics, textiles, sports, and chemicals. Some examples include nano transistors in electronics, fuel cells, OLED displays, batteries, and solar cells. Nanotechnology promises advantages like increased strength, lighter weight, lower cost, and more precision and durability. However, there are also disadvantages like potential job losses, health risks from carbon nanotubes, high initial costs, and concerns about enabling more destructive weapons. Researchers are optimistic about the future products enabled by this new technology and nanotechnology is poised to usher in a
This presentation provides an introduction to nanotechnology. It defines nanotechnology as the understanding and control of matter at the nanoscale, between 1 to 100 nanometers. At this scale, materials exhibit unique properties not present at larger scales. The presentation outlines potential applications of nanotechnology in electronics, materials, and life sciences, such as nano transistors, targeted drug delivery, and tissue regeneration. It also discusses advantages like medical advances and industrial uses, as well as potential disadvantages like job losses. In conclusion, nanotechnology offers powerful new materials and products but also intersects with other emerging technologies that could widely change society.
Nanotechnology allows the precise placement of small structures at low cost, leading to economic growth, enhanced security, improved quality of life, and job creation. There are top-down and bottom-up approaches to nanoscale fabrication. Key tools include carbon nanotubes, quantum dots, and nanobots. Carbon nanotubes have exceptional strength and can penetrate cell walls, making them useful for applications like cancer treatment, sensors, electronics, and solar cells. Quantum dots can be used in displays and MEMS due to their reflectivity properties. Nanobots only a few nanometers in size could count molecules and potentially be used for detection, drug delivery, and biomedical instrumentation. Nanotechnology has many applications including electronics, energy,
chaminaameen@gmail.com
Amina Ameen
Ask me for any other help for PowerPoint slides on my email I'd. I will love to help you in your PowerPoint assignments.
Thanks.
The document discusses the use of nanomaterials in plastics. It provides examples of common nanomaterials like carbon nanotubes, fullerenes, nanoclays, metal and metal oxide nanoparticles, and POSS nanostructures. These nanomaterials have precise structures at the 1-100 nanometer scale that can improve properties like strength, conductivity, and barrier performance when added to plastics. The document also notes that while nanotechnology is new term, nanomaterials themselves are not new and have existed for a long time in nature.
Nanotechnology has applications across many areas of national defense, including armor, sensors, weapons, vehicles, aircraft, and satellites. It can enable lightweight, strong materials for body armor and helmets. Sensors built from nanomaterials can detect chemical and biological agents. Nanotechnology may also lead to adaptive camouflage, stealth capabilities, and self-healing structures for vehicles and aircraft. While improving military capabilities, nanotechnology enables new threats like easier production of nuclear weapons and hard-to-monitor weapons. Overall the document discusses both beneficial and concerning applications of nanotechnology in national defense.
Nanoteknoloji bir çok alanda olduğu gibi sağlıkta da önemli gelişmelere sebep olmuştur. Hastalık tedavisinde önemli bir yere sahip olan ilaçların, sağladığı yararın yanında getirdiği zararları önlemesinde ve hastalıklarının tedavi edilmesinde nanoteknoloji umut vadetmektedir. Yapay DNA, nanorobotlar, kanser teşhisi ve tedavisi, nanoilaçlar, respirositler ve nanopankreas gibi önemli çalışmaların yapılması, bu sürecin devam ederek gelişeceğini göstermektedir.
Nanotechnology is the science and engineering of building and manipulating materials at the nanoscale (1-100 nm). Richard Feynman is considered the father of nanotechnology. Nanotechnology has many applications including in sports equipment to make items lighter, stronger, and improve performance. Some examples where nanotechnology has been applied to sports include using carbon nanotubes in bicycle frames to make them lighter, nanoparticles in running shoes for comfort and stability, and nano-silver in sports equipment to inhibit bacterial growth.
Nanotechnology involves the study and manipulation of matter at the nanoscale, roughly 1 to 100 nanometers. The field originated from a talk by physicist Richard Feynman in 1959 and allows control of materials at the atomic and molecular levels. Key tools like scanning tunneling microscopes and atomic force microscopes enable seeing and working at the nanoscale. Nanotechnology has applications in medicine like improved drug delivery and medical imaging, as well as uses in energy production, consumer goods, and more sustainable industrial practices.
This document discusses nanotechnology, which deals with structures and devices that are 100 nanometers or smaller. It outlines the origin and theory of nanotechnology, and describes potential uses in areas like medicine, electronics, energy, sensors, and daily life. The document also discusses two approaches to nanotechnology - top-down and bottom-up - and explains how bottom-up manufacturing can produce structures with higher precision and perfect surfaces. While nanotechnology holds promise, the document notes there are also health and environmental concerns to consider regarding its development and use.
This presentation talks about the nano composites and its applications. Les propriétés mécaniques des nanocomposites sont différentes de celles des matériaux composites traditionnels à cause d’un rapport surface/volume élevé du renfort, et de son facteur de forme important. Le renfort peut être sous forme de particules (minéraux), de feuillets (argiles exfoliées) ou de fibres (nanotubes de carbone). L’interface matrice-renfort présente une grande surface qui est typiquement un ordre de grandeur plus grand que celle dans le cas d’un matériau composite traditionnel. Cette interface implique qu'une faible quantité de renfort nanométrique peut avoir un effet observable sur les propriétés macroscopiques du composite. Par exemple, l’ajout de nanotubes de carbone améliore les conductivités électrique et thermique d’un matériau composite. D’autres types de nanoparticules peuvent conduire à l’amélioration des propriétés optiques, diélectriques, la résistance au feu, ou des propriétés mécaniques.
Also, very good science.
Hello nano composite has graphere also carbon nano tubes depends if you're looking for a 1D, 2D or 3D texture.
Nanotechnology involves manipulating materials at the atomic or molecular scale between 1 and 100 nanometers. It has applications in medicine such as nano-devices for imaging and monitoring health, in civil engineering by adding nanoparticles to improve materials like concrete and coatings, and in energy through developing more efficient solar cells. The military uses nanotechnology for fabrics, robotics, security, weapons, and monitoring soldier health. While nanotechnology holds promise, its future effects are difficult to predict and it could potentially transform the world in both positive and negative ways.
This document discusses nanotechnology and its potential applications and impacts. It begins by defining nanotechnology as the manipulation of matter on an atomic, molecular, and supramolecular scale between 1 to 100 nanometers. The document then outlines some of the key people involved in developing nanotechnology, potential applications in areas like medicine, materials, and computing, as well as both advantages such as new materials and industrial uses and disadvantages such as potential health risks. It concludes by stating that nanotechnology will change almost every human-made object in the next century and inspire future scientists.
Nano-material and its benefits in the Environmental ApplicationMusaddiq Ali
Nanomaterial is defined as material with dimensions less than 100nm. Nanotechnology involves manipulating nanomaterials to create new large-scale materials with improved properties. Nanoparticles can be organic such as polymeric or inorganic such as gold. Nanomaterials provide benefits in environmental applications such as energy savings through weight reduction and optimized function in vehicles and buildings. They can also reduce use of raw materials through miniaturization.
This document discusses various applications of nanoparticles in medical fields, industries, and environmental issues. Nanoparticles can be used to more effectively deliver drugs to specific target areas in the body. They are also being researched for cancer therapy by using light-activated nano shells to kill tumor cells. In industries, nanoparticles can improve food packaging, textiles, cosmetics, sports equipment, construction materials like cement and steel, and wood products. They are also being applied to environmental cleanup by breaking down oil spills and removing pollutants from air and water.
örnek bir güneş enerji santrali raporu . bu rapor ile bazı başvurular yapılabilir. http://www.enerjibes.com/gunes-enerji-santrali-raporu-nasil-hazirlanir/
This document discusses the use of nanotechnology in civil engineering applications. It begins by defining nanotechnology and nanoscale materials like carbon nanotubes and nano-silica. It then discusses several uses of nanotechnology in concrete to improve strength, durability, and permeability. The document also discusses uses of nanotechnology in steel, wood, stone, and coatings/paints to provide benefits like increased strength, corrosion resistance, self-cleaning properties, and insulation. Specific products discussed include Cuore concrete, SandvikNanoflex steel, MMFX2 steel, and the Nansulate insulation coating.
Nanotechnology involves manipulating matter at the nanoscale, which is approximately 100 nanometers or smaller than the width of a human hair. It has applications in electronics, automotive, engineering, medicine, cosmetics, textiles, sports, and chemicals. Some examples include nano transistors in electronics, fuel cells, OLED displays, batteries, and solar cells. Nanotechnology promises advantages like increased strength, lighter weight, lower cost, and more precision and durability. However, there are also disadvantages like potential job losses, health risks from carbon nanotubes, high initial costs, and concerns about enabling more destructive weapons. Researchers are optimistic about the future products enabled by this new technology and nanotechnology is poised to usher in a
This presentation provides an introduction to nanotechnology. It defines nanotechnology as the understanding and control of matter at the nanoscale, between 1 to 100 nanometers. At this scale, materials exhibit unique properties not present at larger scales. The presentation outlines potential applications of nanotechnology in electronics, materials, and life sciences, such as nano transistors, targeted drug delivery, and tissue regeneration. It also discusses advantages like medical advances and industrial uses, as well as potential disadvantages like job losses. In conclusion, nanotechnology offers powerful new materials and products but also intersects with other emerging technologies that could widely change society.
Nanotechnology allows the precise placement of small structures at low cost, leading to economic growth, enhanced security, improved quality of life, and job creation. There are top-down and bottom-up approaches to nanoscale fabrication. Key tools include carbon nanotubes, quantum dots, and nanobots. Carbon nanotubes have exceptional strength and can penetrate cell walls, making them useful for applications like cancer treatment, sensors, electronics, and solar cells. Quantum dots can be used in displays and MEMS due to their reflectivity properties. Nanobots only a few nanometers in size could count molecules and potentially be used for detection, drug delivery, and biomedical instrumentation. Nanotechnology has many applications including electronics, energy,
chaminaameen@gmail.com
Amina Ameen
Ask me for any other help for PowerPoint slides on my email I'd. I will love to help you in your PowerPoint assignments.
Thanks.
The document discusses the use of nanomaterials in plastics. It provides examples of common nanomaterials like carbon nanotubes, fullerenes, nanoclays, metal and metal oxide nanoparticles, and POSS nanostructures. These nanomaterials have precise structures at the 1-100 nanometer scale that can improve properties like strength, conductivity, and barrier performance when added to plastics. The document also notes that while nanotechnology is new term, nanomaterials themselves are not new and have existed for a long time in nature.
Nanotechnology has applications across many areas of national defense, including armor, sensors, weapons, vehicles, aircraft, and satellites. It can enable lightweight, strong materials for body armor and helmets. Sensors built from nanomaterials can detect chemical and biological agents. Nanotechnology may also lead to adaptive camouflage, stealth capabilities, and self-healing structures for vehicles and aircraft. While improving military capabilities, nanotechnology enables new threats like easier production of nuclear weapons and hard-to-monitor weapons. Overall the document discusses both beneficial and concerning applications of nanotechnology in national defense.
Nanoteknoloji bir çok alanda olduğu gibi sağlıkta da önemli gelişmelere sebep olmuştur. Hastalık tedavisinde önemli bir yere sahip olan ilaçların, sağladığı yararın yanında getirdiği zararları önlemesinde ve hastalıklarının tedavi edilmesinde nanoteknoloji umut vadetmektedir. Yapay DNA, nanorobotlar, kanser teşhisi ve tedavisi, nanoilaçlar, respirositler ve nanopankreas gibi önemli çalışmaların yapılması, bu sürecin devam ederek gelişeceğini göstermektedir.
Nanotechnology is the science and engineering of building and manipulating materials at the nanoscale (1-100 nm). Richard Feynman is considered the father of nanotechnology. Nanotechnology has many applications including in sports equipment to make items lighter, stronger, and improve performance. Some examples where nanotechnology has been applied to sports include using carbon nanotubes in bicycle frames to make them lighter, nanoparticles in running shoes for comfort and stability, and nano-silver in sports equipment to inhibit bacterial growth.
Nanotechnology involves the study and manipulation of matter at the nanoscale, roughly 1 to 100 nanometers. The field originated from a talk by physicist Richard Feynman in 1959 and allows control of materials at the atomic and molecular levels. Key tools like scanning tunneling microscopes and atomic force microscopes enable seeing and working at the nanoscale. Nanotechnology has applications in medicine like improved drug delivery and medical imaging, as well as uses in energy production, consumer goods, and more sustainable industrial practices.
This document discusses nanotechnology, which deals with structures and devices that are 100 nanometers or smaller. It outlines the origin and theory of nanotechnology, and describes potential uses in areas like medicine, electronics, energy, sensors, and daily life. The document also discusses two approaches to nanotechnology - top-down and bottom-up - and explains how bottom-up manufacturing can produce structures with higher precision and perfect surfaces. While nanotechnology holds promise, the document notes there are also health and environmental concerns to consider regarding its development and use.
This presentation talks about the nano composites and its applications. Les propriétés mécaniques des nanocomposites sont différentes de celles des matériaux composites traditionnels à cause d’un rapport surface/volume élevé du renfort, et de son facteur de forme important. Le renfort peut être sous forme de particules (minéraux), de feuillets (argiles exfoliées) ou de fibres (nanotubes de carbone). L’interface matrice-renfort présente une grande surface qui est typiquement un ordre de grandeur plus grand que celle dans le cas d’un matériau composite traditionnel. Cette interface implique qu'une faible quantité de renfort nanométrique peut avoir un effet observable sur les propriétés macroscopiques du composite. Par exemple, l’ajout de nanotubes de carbone améliore les conductivités électrique et thermique d’un matériau composite. D’autres types de nanoparticules peuvent conduire à l’amélioration des propriétés optiques, diélectriques, la résistance au feu, ou des propriétés mécaniques.
Also, very good science.
Hello nano composite has graphere also carbon nano tubes depends if you're looking for a 1D, 2D or 3D texture.
Nanotechnology involves manipulating materials at the atomic or molecular scale between 1 and 100 nanometers. It has applications in medicine such as nano-devices for imaging and monitoring health, in civil engineering by adding nanoparticles to improve materials like concrete and coatings, and in energy through developing more efficient solar cells. The military uses nanotechnology for fabrics, robotics, security, weapons, and monitoring soldier health. While nanotechnology holds promise, its future effects are difficult to predict and it could potentially transform the world in both positive and negative ways.
Top 10 lead cra interview questions and answerstonychoper7906
This document provides materials and advice for answering common interview questions for a lead craft position. It includes sample answers for 10 typical lead craft interview questions, such as why the applicant wants the job, what challenges they are seeking, their biggest weakness, and why the company should hire them. The document emphasizes showing passion for the role and company, providing specific experiences and examples, and researching the company beforehand.
Top 10 clinical trial assistant interview questions and answersgarajom
This document provides resources for clinical trial assistant interviews, including common interview questions, answers, and tips. It includes links to ebooks on interview questions and secrets to winning interviews. Suggested questions cover why the applicant wants the job, challenges they seek, describing a typical work week, weaknesses, why the company should hire them, and questions for the employer. Overall, the document aims to help applicants prepare and succeed in interviews for clinical trial assistant roles.
This presentation is a simple explain of Bionanoimaging which introduce this area completely. You can use this PPTx File to present in your class and seminars as well. I prepare this file to present in Tabriz University of Medical Sciences when I was a MSc Medical Nanotechnology student. It will be useful for you too.
Nanotechnology and Its Applications which are related to the field of engineering and mainly bio-nanotechnology, electronics and green nanotechnology in India.
Top 52 clinical research associate interview questions and answers pdfHarrisonFord888
Here are the key points to cover in your answer:
- The company's core business/industry and their main products/services
- Their size (annual revenue, number of employees etc)
- Their leadership/management - who the key decision makers are
- Any recent major events/deals/expansion plans
- Their mission/vision statement and company values
- Their culture/work environment
- Clientele/target market
The level of detail you provide will depend on the role. Focus on relating what you've learned to why you're a good fit and excited about the opportunity. Keep it brief (under 2 minutes) while demonstrating you've done your research on them.
Top 52 clinical research coordinator interview questions and answers pdfHarrisonFord888
The document provides tips and sample answers for 18 common interview questions, including questions about the applicant's background, work experience, strengths, weaknesses, goals, and knowledge of the company. The summaries focus on highlighting relevant experience and skills, giving specific examples, emphasizing strengths that align with the job requirements, and demonstrating research into the company.
Pharmaceutical imaging techniques provide visual representations of objects like body parts or pharmaceutical products for quality control, data collection, or disease diagnosis using computerized methods like ultrasound or spectroscopy. Imaging technologies are gaining attention in the pharmaceutical industry due to their potential to accelerate drug discovery and development. Common techniques discussed in the document include chemical imaging, elemental imaging, digital imaging, fluorescence correlation spectroscopy, and micro-X-ray fluorescence, which are used for applications like content uniformity testing, particle characterization, counterfeit detection, and detecting drug distribution.
2. TAKDİM PLANITAKDİM PLANI
NANAOTEKNOLOJİ VE SPORNANAOTEKNOLOJİ VE SPOR
TENİS RAKETİTENİS RAKETİ
TENİS TOPUTENİS TOPU
GOLF SOPASIGOLF SOPASI
GOLF TOPUGOLF TOPU
KAYNAKÇAKAYNAKÇA
3. NANOTEKNOLOJİ VENANOTEKNOLOJİ VE
SPORSPOR
NanoteknolojiNanoteknoloji
günümüzde tüketicigünümüzde tüketici
ihtiyacını karşılayanihtiyacını karşılayan
çeşitli ürünlerinçeşitli ürünlerin
üretilmesindeüretilmesinde
kullanılmaktadır.kullanılmaktadır.
Ana uygulamaAna uygulama
alanlarından biridealanlarından biride
sağlık ve sporsağlık ve spor
alanıdır.alanıdır.
4. NANOTEKNOLOJİ VENANOTEKNOLOJİ VE
SPORSPOR
Sporda, nanoteknoloji ekipman veSporda, nanoteknoloji ekipman ve
sporcunun performansınısporcunun performansını
arttırabilmek için özel sporarttırabilmek için özel spor
ekipmanları ve kıyafetlerleekipmanları ve kıyafetlerle
birleştirilmiş farklı element vebirleştirilmiş farklı element ve
materyallerin kullanımınımateryallerin kullanımını
içermektedir.içermektedir.
5. Nano büyüklükteki içerikler özellikle deNano büyüklükteki içerikler özellikle de
karbon nanotüplerin kullanımıyla spordakarbon nanotüplerin kullanımıyla sporda
büyük bir patlama yapmıştır.büyük bir patlama yapmıştır.
NANOTEKNOLOJİ VENANOTEKNOLOJİ VE
SPORSPOR
6. Karbon nanotüplerin elmas kadar sert veKarbon nanotüplerin elmas kadar sert ve
çelikten 100 kat güçlü ve 6 kat daha hafifçelikten 100 kat güçlü ve 6 kat daha hafif
olması güç ve hafifliğin yüksek önemeolması güç ve hafifliğin yüksek öneme
sahip olduğu spor malzemelerindesahip olduğu spor malzemelerinde
kullanılması ideal malzemeler halinekullanılması ideal malzemeler haline
gelmelerine neden olmuştur.gelmelerine neden olmuştur.
7. Nano malzemelerleNano malzemelerle
geliştirilmiş ekipmanlargeliştirilmiş ekipmanlar
dünyaca ünlü pek çokdünyaca ünlü pek çok
marka tarafındanmarka tarafından
tenis, golf, bisiklet,tenis, golf, bisiklet,
kayak, yüzme gibikayak, yüzme gibi
sporlar için kullanımasporlar için kullanıma
sunulmuştur.sunulmuştur.
8. Golf SopasıGolf Sopası
Golf sopası yapımındaGolf sopası yapımında
kullanılan nanometalkullanılan nanometal
kaplamanın kristalkaplamanın kristal
yapısı şu an kullanılanyapısı şu an kullanılan
metallere göre 1000metallere göre 1000
kat daha küçük ve 4kat daha küçük ve 4
kat daha güçlüdür.kat daha güçlüdür.
9. Golf sopasında;Golf sopasında;
Hafif/Sağlam şaft,Hafif/Sağlam şaft,
Arttırılmış güç/hassasiyet,Arttırılmış güç/hassasiyet,
Daha az top devri,Daha az top devri,
Daha uzun ve düz atışlar,Daha uzun ve düz atışlar,
nanoteknoloji ile sağlanmıştır.nanoteknoloji ile sağlanmıştır.
10. GOLF TOPUGOLF TOPU
NDMX adı verilenNDMX adı verilen
nanoteknolojinanoteknoloji
kullanılarakkullanılarak
yapılmış golf topuyapılmış golf topu
iç ağırlığı önemliiç ağırlığı önemli
ölçüdeölçüde
değişebildiği içindeğişebildiği için
normal toplaranormal toplara
göre daha düzgöre daha düz
uçabilmektedir.uçabilmektedir.
11. Ağırlığının değişmesiAğırlığının değişmesi
topun, vurucununtopun, vurucunun
gitmesini istediği yeregitmesini istediği yere
gitmesini sağlar.gitmesini sağlar.
Uçuş rotasını düzelmekUçuş rotasını düzelmek
için ağırlığın dağıtılmasıiçin ağırlığın dağıtılması
topun uçuş süresinitopun uçuş süresini
azaltan enerji gerektirir.azaltan enerji gerektirir.
Bunu engellemek içinBunu engellemek için
NDMX’in dış yüzeyi diğerNDMX’in dış yüzeyi diğer
toplara göre daha serttoplara göre daha sert
yapılmıştır.yapılmıştır.
12. TENİS RAKETİTENİS RAKETİ
Babolat markasıBabolat markası
tarafından üretilen Puretarafından üretilen Pure
Drive isimli tenis raketiDrive isimli tenis raketi
üzerindeki nano karbonüzerindeki nano karbon
fiber kaplama raketinfiber kaplama raketin
%20 daha dayanıklı%20 daha dayanıklı
hale gelmesinihale gelmesini
sağlamıştır.sağlamıştır.
13. Bu teknoloji ile raket çerçevesindekiBu teknoloji ile raket çerçevesindeki
karbon fiberler arasındaki boşluklarkarbon fiberler arasındaki boşluklar
silikon oksit kristalleriylesilikon oksit kristalleriyle
doldurulmaktadır. Bu şekilde üretilendoldurulmaktadır. Bu şekilde üretilen
raket daha güçlü ve daha dayanıklı haleraket daha güçlü ve daha dayanıklı hale
gelmektedir.gelmektedir.
14. TENİS TOPUTENİS TOPU
Wilson markası tarafındanWilson markası tarafından
üretilen Double Core tenisüretilen Double Core tenis
topunun iç kısmı Air D-topunun iç kısmı Air D-
Fence marka kauçuk ileFence marka kauçuk ile
kaplanarak hava basıncınınkaplanarak hava basıncının
topun içine hapsedilmesitopun içine hapsedilmesi
sağlanmıştır.sağlanmıştır.
Bu kaplama topun en az 2Bu kaplama topun en az 2
kat daha fazla zıplamasınıkat daha fazla zıplamasını
ve topun ömrününve topun ömrünün
uzamasını sağlamıştır.uzamasını sağlamıştır.
15. Topun içindeki sıvı polimere kurutulmuşTopun içindeki sıvı polimere kurutulmuş
kil parçacıkları eklenir.kil parçacıkları eklenir.
Kil tabakaları birbirlerini paralel şekildeKil tabakaları birbirlerini paralel şekilde
kaplar.kaplar.
İçerde sıkışan hava dışarı çıkabilmek içinİçerde sıkışan hava dışarı çıkabilmek için
oluşan katmanlar arasında dolaşmakoluşan katmanlar arasında dolaşmak
zorunda kalır.zorunda kalır.
Bunun sonucunda da hava içerde dahaBunun sonucunda da hava içerde daha
fazla kalır.fazla kalır.
16. Tenis topundaki nano kaplamaTenis topundaki nano kaplama
topun içindeki ikinci çekirdeğetopun içindeki ikinci çekirdeğe
püskürtülmüş yada sarılmışpüskürtülmüş yada sarılmış
olabilir.olabilir.
Bu kaplama birbirlerini örtenBu kaplama birbirlerini örten
tabakalar halindeki kiltabakalar halindeki kil
parçacıklarından oluşmuştur.parçacıklarından oluşmuştur.
Bu tabakalar yaklaşık olarak 1Bu tabakalar yaklaşık olarak 1
nanometre kalınlığındadır.nanometre kalınlığındadır.