Carbon nanotubes
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Carbon nanotubes are cylindrical carbon molecules that have extraordinary strength and unique electrical properties. They can be produced through several methods including arc discharge, laser ablation, and chemical vapor decomposition. Carbon nanotubes are promising for applications in electronics, optics, and other materials due to their strength, conductivity, and thermal properties. However, concerns remain regarding their potential toxicity if inhaled.
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carbon nanotubes
Carbon nanotubes are cylindrical carbon molecules that exhibit extraordinary strength, unique electrical properties, and efficient heat conduction. They can be produced via arc discharge, laser ablation, and chemical vapor decomposition. Carbon nanotubes have the highest tensile strength and modulus of elasticity of any known material. Their electrical properties depend on their structure, and they can conduct electricity efficiently. Potential applications of carbon nanotubes include electronics, quantum computing, and elevators to space. However, concerns exist regarding their potential toxicity if inhaled.
Carbon nanotubes (1)
Carbon nanotubes (CNTs) are allotropes of carbon. These cylindrical carbon molecules have interesting properties that make them potentially useful in many applications in nanotechnology, electronics, optics and other fields of materials science, as well as potential uses in architectural fields. They exhibit extraordinary strength and unique electrical properties, and are efficient conductors of heat. Their final usage, however, may be limited by their potential toxicity.
Presntation
This presentation provides an overview of nanotechnology. It begins by defining nanotechnology as the study and manipulation of matter at the atomic scale, around 1 to 100 nanometers. The history of nanotechnology is then summarized, noting Richard Feynman's 1959 concept and key developments like the scanning tunneling microscope. Tools for nanotechnology like atomic force microscopes and lithography techniques are outlined. Specific nanomaterials like carbon nanotubes, nanorods, and potential nanobots are then described briefly, noting their properties and applications in areas such as electronics, medicine, and materials science.
Carbon nanotubes bc
Carbon nanotubes are allotropes of carbon that are extremely small, with diameters on the nanometer scale. They have a variety of potential applications due to their unique properties like strength, conductivity, and thermal properties. Some applications discussed include use in clothing, electronics, displays, filters, and hydrogen storage. However, concerns remain about their potential toxicity and more research is needed to address public confusion and fully realize their promise.
Nanotechnology
Nanotechnology involves engineering materials at the nanoscale, around 1 to 100 nanometers. Richard Feynman is considered the father of nanotechnology. Nanotechnology has applications in many fields including electronics, computing, medicine, cosmetics, foods, the military, and energy. By 2020, products with nanotechnology components could be worth $1 trillion. Materials behave differently at the nanoscale compared to larger scales due to statistical mechanics and quantum effects. Nanotechnology is approached through top-down methods like lithography or bottom-up methods like self-assembly.
Carbon Nanotubes
This document discusses carbon nanotubes (CNTs), including their discovery, structure, properties, synthesis, applications, and future potential. Some key points:
- CNTs were discovered in 1991 and have a rolled-up graphene sheet structure that gives them unique mechanical and electrical properties.
- CNTs exhibit extraordinary strength and conductivity, with current-carrying capacity 1000 times higher than copper.
- Common synthesis methods are arc discharge, laser ablation, and chemical vapor deposition.
- Applications include energy storage, conductive composites, electronics, and more. Mass production is increasing and CNTs are already used in some products.
- CNTs show promise for applications across many industries
CNT BASED CELL BY MOHD SAFIL BEG
This document summarizes a seminar presentation on carbon nanotube based solar cells. It begins with an introduction to carbon nanotubes, describing their cylindrical nanostructure formed from graphene sheets rolled at specific angles. It then discusses properties of carbon nanotubes that make them suitable for solar cells, such as their electrical conductivity. The document reviews different generations of solar cell technology and their limitations before describing how carbon nanotubes can be incorporated into dye-sensitized solar cells as transparent electrodes, replacing conventional materials like ITO. It presents results showing a carbon nanotube-based solar cell achieved 7.04% efficiency compared to 7.34% for a standard platinum electrode cell. In conclusion, carbon nanotube electrodes
Carbon nano tube (cnts) by a.wahab
This document discusses carbon nanotubes (CNTs). It defines nanochemistry as the study and synthesis of nanoparticles between 1-100 nanometers in size. CNTs are cylindrical carbon molecules with unusual properties valuable for applications in nanotechnology, electronics, optics, and other fields. There are two main types of CNTs - single-walled and multi-walled. CNTs can be produced through methods like arc discharge, laser ablation, and chemical vapor deposition. CNTs have remarkable mechanical, electrical, and thermal properties and are being researched for applications in areas like medicine, composites, microelectronics, chemicals, and more, though more study is still needed on their toxicity and environmental impact.
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carbon nanotubes
Carbon nanotubes are cylindrical carbon molecules that exhibit extraordinary strength, unique electrical properties, and efficient heat conduction. They can be produced via arc discharge, laser ablation, and chemical vapor decomposition. Carbon nanotubes have the highest tensile strength and modulus of elasticity of any known material. Their electrical properties depend on their structure, and they can conduct electricity efficiently. Potential applications of carbon nanotubes include electronics, quantum computing, and elevators to space. However, concerns exist regarding their potential toxicity if inhaled.
Carbon nanotubes (1)
Carbon nanotubes (CNTs) are allotropes of carbon. These cylindrical carbon molecules have interesting properties that make them potentially useful in many applications in nanotechnology, electronics, optics and other fields of materials science, as well as potential uses in architectural fields. They exhibit extraordinary strength and unique electrical properties, and are efficient conductors of heat. Their final usage, however, may be limited by their potential toxicity.
Presntation
This presentation provides an overview of nanotechnology. It begins by defining nanotechnology as the study and manipulation of matter at the atomic scale, around 1 to 100 nanometers. The history of nanotechnology is then summarized, noting Richard Feynman's 1959 concept and key developments like the scanning tunneling microscope. Tools for nanotechnology like atomic force microscopes and lithography techniques are outlined. Specific nanomaterials like carbon nanotubes, nanorods, and potential nanobots are then described briefly, noting their properties and applications in areas such as electronics, medicine, and materials science.
Carbon nanotubes bc
Carbon nanotubes are allotropes of carbon that are extremely small, with diameters on the nanometer scale. They have a variety of potential applications due to their unique properties like strength, conductivity, and thermal properties. Some applications discussed include use in clothing, electronics, displays, filters, and hydrogen storage. However, concerns remain about their potential toxicity and more research is needed to address public confusion and fully realize their promise.
Nanotechnology
Nanotechnology involves engineering materials at the nanoscale, around 1 to 100 nanometers. Richard Feynman is considered the father of nanotechnology. Nanotechnology has applications in many fields including electronics, computing, medicine, cosmetics, foods, the military, and energy. By 2020, products with nanotechnology components could be worth $1 trillion. Materials behave differently at the nanoscale compared to larger scales due to statistical mechanics and quantum effects. Nanotechnology is approached through top-down methods like lithography or bottom-up methods like self-assembly.
Carbon Nanotubes
This document discusses carbon nanotubes (CNTs), including their discovery, structure, properties, synthesis, applications, and future potential. Some key points:
- CNTs were discovered in 1991 and have a rolled-up graphene sheet structure that gives them unique mechanical and electrical properties.
- CNTs exhibit extraordinary strength and conductivity, with current-carrying capacity 1000 times higher than copper.
- Common synthesis methods are arc discharge, laser ablation, and chemical vapor deposition.
- Applications include energy storage, conductive composites, electronics, and more. Mass production is increasing and CNTs are already used in some products.
- CNTs show promise for applications across many industries
CNT BASED CELL BY MOHD SAFIL BEG
This document summarizes a seminar presentation on carbon nanotube based solar cells. It begins with an introduction to carbon nanotubes, describing their cylindrical nanostructure formed from graphene sheets rolled at specific angles. It then discusses properties of carbon nanotubes that make them suitable for solar cells, such as their electrical conductivity. The document reviews different generations of solar cell technology and their limitations before describing how carbon nanotubes can be incorporated into dye-sensitized solar cells as transparent electrodes, replacing conventional materials like ITO. It presents results showing a carbon nanotube-based solar cell achieved 7.04% efficiency compared to 7.34% for a standard platinum electrode cell. In conclusion, carbon nanotube electrodes
Carbon nano tube (cnts) by a.wahab
This document discusses carbon nanotubes (CNTs). It defines nanochemistry as the study and synthesis of nanoparticles between 1-100 nanometers in size. CNTs are cylindrical carbon molecules with unusual properties valuable for applications in nanotechnology, electronics, optics, and other fields. There are two main types of CNTs - single-walled and multi-walled. CNTs can be produced through methods like arc discharge, laser ablation, and chemical vapor deposition. CNTs have remarkable mechanical, electrical, and thermal properties and are being researched for applications in areas like medicine, composites, microelectronics, chemicals, and more, though more study is still needed on their toxicity and environmental impact.
Introduction to nannotechnology
A nanometer (nm) is one thousand millionth of a meter.
A single human hair is about 80,000 nm wide, a red
blood cell is approximately 7,000 nm wide, a DNA
molecule 2 to 2.5 nm, and a water molecule almost
0.3 nm. The term ”nanotechnology” was created by
Norio Taniguchi of Tokyo University in 1974 to describe
the precision manufacture of materials with nanometer
tolerances1, but its origins date back to Richard
Feynman’s 1959 talk
Carbon nanotube
Carbon Nanotubes
Graphene
Introduction
Types Of CNT's
Structures of CNT's
Properties of CNT's
Application of CNT's
Growth of nanotechnology
This document discusses nanotechnology and its history, synthesis, applications, advantages, disadvantages, and future. It describes how nanotechnology involves manipulating matter at the nanoscale (1-100 nanometers). Examples are given of early developments in nanotechnology from the 1600s to present day. Applications discussed include transistors, batteries, targeted drug delivery, and stronger/lighter materials. Both promises such as universal immunity and threats like new environmental risks are mentioned. The document concludes that nanotechnology will lead to new research areas and technology while most applications are still years away.
Bucky nanotech
Buckypaper is a macroscopic aggregate of carbon nanotubes that is only one tenth the weight of steel yet potentially 500 times stronger. It is made of carbon nanotubes arranged in a grid that are 50,000 times thinner than a human hair. Buckypaper has high strength and flexibility as well as the ability to conduct electricity and disperse heat. Potential applications include filters, protective coatings, energy storage materials, and use in aircraft composites to improve strength while reducing weight. However, buckypaper is currently very expensive to produce.
Carbon nanotubes in solar panel technology
This is the advancement of solar panels in which the carbon nano tubes are going to boost their performance.
Carbon Nanotubes Properties and its Applications
This document discusses carbon nanotubes. It defines a carbon nanotube as a tube-shaped material made of carbon that has a diameter on the nanometer scale, which is about 10,000 times smaller than a human hair. Carbon nanotubes are categorized as either single-walled or multi-walled. The document lists several applications of carbon nanotubes, including in thermal conductivity, energy storage, structural materials, fibers, biomedicine, filtration, electronics, and bioengineering. Several synthesis methods for carbon nanotubes are also described, such as arc discharge, laser ablation, chemical vapor deposition, and ball milling.
Carbon nanotube and its application
Carbon nanotubes have many potential applications including:
1. Electrical circuits like transistors that can operate at room temperature and digital switching. Mass production has been a challenge but some processes have been developed.
2. Electrical cables and wires that can carry high currents. Some carbon nanotube composites have conductivity exceeding copper.
3. The first computer was built using carbon nanotubes instead of silicon, demonstrating this technology could replace silicon in future computers. However, carbon nanotube transistors need to be smaller than the prototype.
Carbon nanotubes
Carbon nanotubes were discovered in 1991 and come in two main types: single-walled and multi-walled. They have a unique cylindrical structure that gives them remarkable electronic, thermal, and structural properties depending on their structure. There are several methods for synthesizing carbon nanotubes, such as arc discharge, chemical vapor deposition, and laser ablation, each with their own advantages and disadvantages related to yield, purity, and scalability. Carbon nanotubes have many potential applications due to their low density, high strength, and ability to conduct heat and electricity well. However, they are also very expensive to produce and questions remain about their environmental and health impacts.
cnt ppt
This document discusses the use of carbon nanotubes in solar panels to improve efficiency. It provides background on solar panels and carbon nanotubes, explaining their properties. It then details the history of carbon nanotube solar panels, how they are constructed, and how double-walled carbon nanotubes can be used as both light absorbers and charge carriers. Using carbon nanotubes allows solar panels to utilize infrared light and increase efficiency to potentially 80%. Their properties like high mobility and strength make them suitable for more efficient solar energy conversion.
Carbon nanotubes
This document discusses carbon nanotubes. It describes carbon nanotubes as having a diameter as small as 1nm and being made of rolled graphene sheets. Carbon nanotubes can be single-walled, multi-walled, or double-walled. They have extraordinary properties including high tensile strength, electrical and thermal conductivity. Potential applications include conductive plastics, structural materials, electronics, and biosensors. Common fabrication methods are electric arc discharge, laser ablation, and chemical vapor deposition.
Carbon nanotubes
This document discusses the properties of carbon nanotubes including their diameter ranging from 1 nanometer, band gap ranging from 0-2 electronvolts, and structure as either single-walled or multi-walled tubes made of concentric graphene cylinders. It also notes that carbon nanotubes can be metallic or semiconducting depending on their structure and that they are expected to be very good thermal conductors. The document mentions potential applications of carbon nanotubes as probes for scanning electrochemical microscopy and as modifiers for electrodes to detect trace heavy metals.
Carbon nano tubes and its synthesise
This document discusses carbon nanotubes. It provides a brief history and timeline of carbon nanotube discoveries. Carbon nanotubes can be single-walled or multi-walled and are composed entirely of sp2 bonds. They exhibit exceptional mechanical, electrical and thermal properties. Common synthesis methods include arc discharge, laser ablation and chemical vapor deposition.
carbon nanotube antenna
This document discusses carbon nanotube antennas in the sub-terahertz range. It provides background on carbon nanotubes, describing their properties including strength, electrical conductivity, thermal conductivity, and defects. Methods for synthesizing carbon nanotubes are covered, including arc discharge, laser ablation, chemical vapor deposition, and ball milling. The document serves as an introduction to carbon nanotube antennas and their potential applications in the sub-terahertz range due to carbon nanotubes' conductive properties.
Carbon nanotube
The goal of presentation on carbon nanotubes(CNTs) is to briefly introduce to this growing novel area of material science. I feel it is important to create an awareness of the nanosciences and their potential applications in the future of nanotechnology. The typical question of “when are we going to use this stuff”,? If some one ask such a question, then they are also responsible for finding answers to satisfy their curiosity. In the case of carbon nanotubes and their properties, hopefully this paper will help them in their quest. This ppt is focussed on the discovery, synthesis,growth processes, properties and the latest research advances of carbon nanotubes developed over the past 12 years. Because of their remarkable electronic and mechanical properties, carbon nanotubes are unique and exciting. The field has been developed rapidly, and the number of publications per year is increasing almost exponentially. Various technological applications are likely to arise using nanotubes for fabrication of flat panel displays, gas storage devices, toxic gas sensors, Li+ batteries, robust and light weight composites, conducting paints, electronic nanodevices etc. Further experimental and theoretical research is still necessary so these novel technologies will become a reality in the early 21 century.
Carbon has four electrons in its outer valence shell; the ground state configuration is 2s2 2p2. Diamond and graphite are considered as two natural crystalline forms of pure carbon. In diamond, carbon atoms exhibit sp3 hybridization, in which four bonds are directed toward the corners of a regular tetrahedron. The resulting three-dimensional network (diamond) is extremely rigid, which is one reason for its hardness. The bond length between sp3 carbons (e.g., diamond) is 1.56 ˚A. In graphite, sp2 hybridization occurs, in which each atom is connected evenly to three carbons (120◦) in their plane, and a weak π bond is present in the z axis. The C–C sp2 bond length is 1.42 ˚A. The sp2 set forms the hexagonal (honeycomb) lattice typical of a sheet of graphite.
Carbon nanotubes and their economic feasibility
These slides use concepts from my (Jeff Funk) course entitled analyzing hi-tech opportunities to analyze how the economic feasibility of carbon nanotubes is becoming better through developing new forms of carbon nanotubes, new methods of synthesis, and increasing the scale of production equipment. New forms of carbon nanotubes continue to be developed; new ones include carbon nanobuds, doped carbon nanotubes, and graphenated carbon nanotubes, each of which includes many variations. The large number of variations suggests that carbon nanotubes will likely experience improvements in performance and the number of applications will continue to grow.
APPLICATION OF CARBON NANOTUBES
# ENGINEERING PHYSICS #
-------------------------------------------------------------------------------------
APPLICATION OF CNT’S
-------------------------------------------------------------------------------------
CONTENT
-------------------------------------------------------------------------------------
>WHAT IS CNT?
Carbon Nano Tube
Buckytubes
>STRUCTURES OF CNTs
Armchair structure
Zigzag structure
Helical or Chiral structure
>CATEGORIES OF CNTs
Single-Walled Carbon Nanotubes(SWCNT)
Multi-Walled Carbon Nanotubes(MWCNT)
>APPLICATIONS OF CNTs
Nanoscale electronic devices
Battery electrodes, electrical devices & reinforcing fibers
Flat-panel display
Vacuum tube lamps
Switching devices & display devices
The sensitive detector of various gases
Battery technology
Nanoprobes
Serve as catalyst
Tiny electronic circuits
Interconnects in chip
Designing a light-weight shielding material
>APPLICATIONS OF CNTs IN CIVIL
-In concrete
-Nano silica
-In steel
Sandvik nano flex
MMFX2
-In glass
Self-cleaning glass
>REAL LIFE EXAMPLES
-Nano House
-The basic computer using carbon nanotubes
-------------------------------------------------------------------------------------
CREATIVE SLIDES
Nano tubes technology in solar
- Carbon nanotubes are being used in solar panel technology to improve efficiency by allowing the panels to utilize infrared radiation. The nanotubes act as photoconversion sites and help transport charge carriers. This can increase theoretical efficiency to 80%.
- Double-walled carbon nanotubes are directly incorporated into thin film solar cells, creating a p-n heterojunction with silicon. Nanotubes serve as both a light absorber and charge transport layer. Initial tests show an efficiency over 1%.
- Advantages of carbon nanotube solar panels include improved efficiency, ability to operate at night, increased output voltage, and reduced material needs. However, the technology remains in the experimental stage.
Carbon nanotubes cnts
This document discusses carbon nanotubes (CNTs) and fullerenes. It describes that single-wall CNTs are made by rolling graphene into tubes, while multi-walled CNTs contain multiple concentric tubes. CNTs were discovered in 1991 and have unique properties like strength, conductivity, and optical activity due to their structure as rolled graphene. CNTs can be synthesized through arc discharge, laser ablation, or chemical vapor deposition. Current applications include electronics, sensors, batteries, and biomedicine. Future applications may include molecular transistors and components for spacecraft and space elevators.
Synthesis of CNT by Arc discharge method
The document summarizes the arc-discharge method for synthesizing carbon nanotubes. In the arc-discharge method, a plasma is generated between two graphite electrodes in an inert gas atmosphere by applying a voltage. Parameters like gas pressure, electrode material/purity, distance between electrodes, cooling, and current/voltage determine the structures formed. Single-walled nanotubes are produced when metals like iron and nickel are added to the anode along with sulfur, which acts as a surfactant. The arc-discharge method can produce high-quality multi-walled and single-walled carbon nanotubes for applications in electronics, batteries, solar cells, and more.
Carbon nanotube
This document discusses carbon nanotubes (CNTs). CNTs were first discovered in 1991 and have a nanoscopic cylindrical structure. There are two main types: single-walled and multi-walled. CNTs can be synthesized through arc discharge, chemical vapor deposition, and laser ablation methods. CNTs have extraordinary mechanical and thermal properties, such as being 200 times stronger than steel but also excellent conductors of electricity and heat. Potential applications include use in bulletproof vests, water filters, and other future technologies. However, challenges remain around production mechanisms and skilled workforce development.
Carbon nanotubes
Carbon nanotubes are cylindrical nanostructures made entirely of carbon atoms. They have a length-to-diameter ratio of up to 132,000,000:1. There are two main types: single-walled nanotubes consisting of a single graphene cylinder, and multi-walled nanotubes containing multiple graphene cylinders. Carbon nanotubes were first discovered in the 1970s and were fully characterized in the early 1990s. They exhibit extraordinary strength and electrical conductivity and have a wide variety of potential applications, including in materials science, electronics, optics, and biomedical engineering.
Applications of carbon nanotubes
This document discusses applications of carbon nanotubes for drug delivery systems. Carbon nanotubes have unique properties like high surface area and thermal conductivity that make them promising candidates for drug transport and delivery. They can be functionalized for biomedical applications through covalent and non-covalent methods. Carbon nanotubes show potential as drug carriers for cancer treatment, transdermal drug delivery, cardiac regulation, and tissue regeneration. Different synthesis techniques like arc discharge, laser ablation, and chemical vapor deposition are used to produce carbon nanotubes in large quantities.
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Introduction to nannotechnology
A nanometer (nm) is one thousand millionth of a meter.
A single human hair is about 80,000 nm wide, a red
blood cell is approximately 7,000 nm wide, a DNA
molecule 2 to 2.5 nm, and a water molecule almost
0.3 nm. The term ”nanotechnology” was created by
Norio Taniguchi of Tokyo University in 1974 to describe
the precision manufacture of materials with nanometer
tolerances1, but its origins date back to Richard
Feynman’s 1959 talk
Carbon nanotube
Carbon Nanotubes
Graphene
Introduction
Types Of CNT's
Structures of CNT's
Properties of CNT's
Application of CNT's
Growth of nanotechnology
This document discusses nanotechnology and its history, synthesis, applications, advantages, disadvantages, and future. It describes how nanotechnology involves manipulating matter at the nanoscale (1-100 nanometers). Examples are given of early developments in nanotechnology from the 1600s to present day. Applications discussed include transistors, batteries, targeted drug delivery, and stronger/lighter materials. Both promises such as universal immunity and threats like new environmental risks are mentioned. The document concludes that nanotechnology will lead to new research areas and technology while most applications are still years away.
Bucky nanotech
Buckypaper is a macroscopic aggregate of carbon nanotubes that is only one tenth the weight of steel yet potentially 500 times stronger. It is made of carbon nanotubes arranged in a grid that are 50,000 times thinner than a human hair. Buckypaper has high strength and flexibility as well as the ability to conduct electricity and disperse heat. Potential applications include filters, protective coatings, energy storage materials, and use in aircraft composites to improve strength while reducing weight. However, buckypaper is currently very expensive to produce.
Carbon nanotubes in solar panel technology
This is the advancement of solar panels in which the carbon nano tubes are going to boost their performance.
Carbon Nanotubes Properties and its Applications
This document discusses carbon nanotubes. It defines a carbon nanotube as a tube-shaped material made of carbon that has a diameter on the nanometer scale, which is about 10,000 times smaller than a human hair. Carbon nanotubes are categorized as either single-walled or multi-walled. The document lists several applications of carbon nanotubes, including in thermal conductivity, energy storage, structural materials, fibers, biomedicine, filtration, electronics, and bioengineering. Several synthesis methods for carbon nanotubes are also described, such as arc discharge, laser ablation, chemical vapor deposition, and ball milling.
Carbon nanotube and its application
Carbon nanotubes have many potential applications including:
1. Electrical circuits like transistors that can operate at room temperature and digital switching. Mass production has been a challenge but some processes have been developed.
2. Electrical cables and wires that can carry high currents. Some carbon nanotube composites have conductivity exceeding copper.
3. The first computer was built using carbon nanotubes instead of silicon, demonstrating this technology could replace silicon in future computers. However, carbon nanotube transistors need to be smaller than the prototype.
Carbon nanotubes
Carbon nanotubes were discovered in 1991 and come in two main types: single-walled and multi-walled. They have a unique cylindrical structure that gives them remarkable electronic, thermal, and structural properties depending on their structure. There are several methods for synthesizing carbon nanotubes, such as arc discharge, chemical vapor deposition, and laser ablation, each with their own advantages and disadvantages related to yield, purity, and scalability. Carbon nanotubes have many potential applications due to their low density, high strength, and ability to conduct heat and electricity well. However, they are also very expensive to produce and questions remain about their environmental and health impacts.
cnt ppt
This document discusses the use of carbon nanotubes in solar panels to improve efficiency. It provides background on solar panels and carbon nanotubes, explaining their properties. It then details the history of carbon nanotube solar panels, how they are constructed, and how double-walled carbon nanotubes can be used as both light absorbers and charge carriers. Using carbon nanotubes allows solar panels to utilize infrared light and increase efficiency to potentially 80%. Their properties like high mobility and strength make them suitable for more efficient solar energy conversion.
Carbon nanotubes
This document discusses carbon nanotubes. It describes carbon nanotubes as having a diameter as small as 1nm and being made of rolled graphene sheets. Carbon nanotubes can be single-walled, multi-walled, or double-walled. They have extraordinary properties including high tensile strength, electrical and thermal conductivity. Potential applications include conductive plastics, structural materials, electronics, and biosensors. Common fabrication methods are electric arc discharge, laser ablation, and chemical vapor deposition.
Carbon nanotubes
This document discusses the properties of carbon nanotubes including their diameter ranging from 1 nanometer, band gap ranging from 0-2 electronvolts, and structure as either single-walled or multi-walled tubes made of concentric graphene cylinders. It also notes that carbon nanotubes can be metallic or semiconducting depending on their structure and that they are expected to be very good thermal conductors. The document mentions potential applications of carbon nanotubes as probes for scanning electrochemical microscopy and as modifiers for electrodes to detect trace heavy metals.
Carbon nano tubes and its synthesise
This document discusses carbon nanotubes. It provides a brief history and timeline of carbon nanotube discoveries. Carbon nanotubes can be single-walled or multi-walled and are composed entirely of sp2 bonds. They exhibit exceptional mechanical, electrical and thermal properties. Common synthesis methods include arc discharge, laser ablation and chemical vapor deposition.
carbon nanotube antenna
This document discusses carbon nanotube antennas in the sub-terahertz range. It provides background on carbon nanotubes, describing their properties including strength, electrical conductivity, thermal conductivity, and defects. Methods for synthesizing carbon nanotubes are covered, including arc discharge, laser ablation, chemical vapor deposition, and ball milling. The document serves as an introduction to carbon nanotube antennas and their potential applications in the sub-terahertz range due to carbon nanotubes' conductive properties.
Carbon nanotube
The goal of presentation on carbon nanotubes(CNTs) is to briefly introduce to this growing novel area of material science. I feel it is important to create an awareness of the nanosciences and their potential applications in the future of nanotechnology. The typical question of “when are we going to use this stuff”,? If some one ask such a question, then they are also responsible for finding answers to satisfy their curiosity. In the case of carbon nanotubes and their properties, hopefully this paper will help them in their quest. This ppt is focussed on the discovery, synthesis,growth processes, properties and the latest research advances of carbon nanotubes developed over the past 12 years. Because of their remarkable electronic and mechanical properties, carbon nanotubes are unique and exciting. The field has been developed rapidly, and the number of publications per year is increasing almost exponentially. Various technological applications are likely to arise using nanotubes for fabrication of flat panel displays, gas storage devices, toxic gas sensors, Li+ batteries, robust and light weight composites, conducting paints, electronic nanodevices etc. Further experimental and theoretical research is still necessary so these novel technologies will become a reality in the early 21 century.
Carbon has four electrons in its outer valence shell; the ground state configuration is 2s2 2p2. Diamond and graphite are considered as two natural crystalline forms of pure carbon. In diamond, carbon atoms exhibit sp3 hybridization, in which four bonds are directed toward the corners of a regular tetrahedron. The resulting three-dimensional network (diamond) is extremely rigid, which is one reason for its hardness. The bond length between sp3 carbons (e.g., diamond) is 1.56 ˚A. In graphite, sp2 hybridization occurs, in which each atom is connected evenly to three carbons (120◦) in their plane, and a weak π bond is present in the z axis. The C–C sp2 bond length is 1.42 ˚A. The sp2 set forms the hexagonal (honeycomb) lattice typical of a sheet of graphite.
Carbon nanotubes and their economic feasibility
These slides use concepts from my (Jeff Funk) course entitled analyzing hi-tech opportunities to analyze how the economic feasibility of carbon nanotubes is becoming better through developing new forms of carbon nanotubes, new methods of synthesis, and increasing the scale of production equipment. New forms of carbon nanotubes continue to be developed; new ones include carbon nanobuds, doped carbon nanotubes, and graphenated carbon nanotubes, each of which includes many variations. The large number of variations suggests that carbon nanotubes will likely experience improvements in performance and the number of applications will continue to grow.
APPLICATION OF CARBON NANOTUBES
# ENGINEERING PHYSICS #
-------------------------------------------------------------------------------------
APPLICATION OF CNT’S
-------------------------------------------------------------------------------------
CONTENT
-------------------------------------------------------------------------------------
>WHAT IS CNT?
Carbon Nano Tube
Buckytubes
>STRUCTURES OF CNTs
Armchair structure
Zigzag structure
Helical or Chiral structure
>CATEGORIES OF CNTs
Single-Walled Carbon Nanotubes(SWCNT)
Multi-Walled Carbon Nanotubes(MWCNT)
>APPLICATIONS OF CNTs
Nanoscale electronic devices
Battery electrodes, electrical devices & reinforcing fibers
Flat-panel display
Vacuum tube lamps
Switching devices & display devices
The sensitive detector of various gases
Battery technology
Nanoprobes
Serve as catalyst
Tiny electronic circuits
Interconnects in chip
Designing a light-weight shielding material
>APPLICATIONS OF CNTs IN CIVIL
-In concrete
-Nano silica
-In steel
Sandvik nano flex
MMFX2
-In glass
Self-cleaning glass
>REAL LIFE EXAMPLES
-Nano House
-The basic computer using carbon nanotubes
-------------------------------------------------------------------------------------
CREATIVE SLIDES
Nano tubes technology in solar
- Carbon nanotubes are being used in solar panel technology to improve efficiency by allowing the panels to utilize infrared radiation. The nanotubes act as photoconversion sites and help transport charge carriers. This can increase theoretical efficiency to 80%.
- Double-walled carbon nanotubes are directly incorporated into thin film solar cells, creating a p-n heterojunction with silicon. Nanotubes serve as both a light absorber and charge transport layer. Initial tests show an efficiency over 1%.
- Advantages of carbon nanotube solar panels include improved efficiency, ability to operate at night, increased output voltage, and reduced material needs. However, the technology remains in the experimental stage.
Carbon nanotubes cnts
This document discusses carbon nanotubes (CNTs) and fullerenes. It describes that single-wall CNTs are made by rolling graphene into tubes, while multi-walled CNTs contain multiple concentric tubes. CNTs were discovered in 1991 and have unique properties like strength, conductivity, and optical activity due to their structure as rolled graphene. CNTs can be synthesized through arc discharge, laser ablation, or chemical vapor deposition. Current applications include electronics, sensors, batteries, and biomedicine. Future applications may include molecular transistors and components for spacecraft and space elevators.
Synthesis of CNT by Arc discharge method
The document summarizes the arc-discharge method for synthesizing carbon nanotubes. In the arc-discharge method, a plasma is generated between two graphite electrodes in an inert gas atmosphere by applying a voltage. Parameters like gas pressure, electrode material/purity, distance between electrodes, cooling, and current/voltage determine the structures formed. Single-walled nanotubes are produced when metals like iron and nickel are added to the anode along with sulfur, which acts as a surfactant. The arc-discharge method can produce high-quality multi-walled and single-walled carbon nanotubes for applications in electronics, batteries, solar cells, and more.
Carbon nanotube
This document discusses carbon nanotubes (CNTs). CNTs were first discovered in 1991 and have a nanoscopic cylindrical structure. There are two main types: single-walled and multi-walled. CNTs can be synthesized through arc discharge, chemical vapor deposition, and laser ablation methods. CNTs have extraordinary mechanical and thermal properties, such as being 200 times stronger than steel but also excellent conductors of electricity and heat. Potential applications include use in bulletproof vests, water filters, and other future technologies. However, challenges remain around production mechanisms and skilled workforce development.
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Carbon nanotubes
Carbon nanotubes are cylindrical nanostructures made entirely of carbon atoms. They have a length-to-diameter ratio of up to 132,000,000:1. There are two main types: single-walled nanotubes consisting of a single graphene cylinder, and multi-walled nanotubes containing multiple graphene cylinders. Carbon nanotubes were first discovered in the 1970s and were fully characterized in the early 1990s. They exhibit extraordinary strength and electrical conductivity and have a wide variety of potential applications, including in materials science, electronics, optics, and biomedical engineering.
Applications of carbon nanotubes
This document discusses applications of carbon nanotubes for drug delivery systems. Carbon nanotubes have unique properties like high surface area and thermal conductivity that make them promising candidates for drug transport and delivery. They can be functionalized for biomedical applications through covalent and non-covalent methods. Carbon nanotubes show potential as drug carriers for cancer treatment, transdermal drug delivery, cardiac regulation, and tissue regeneration. Different synthesis techniques like arc discharge, laser ablation, and chemical vapor deposition are used to produce carbon nanotubes in large quantities.
Carbon Nanotubes and Their Methods of Synthesis
This document discusses carbon nanotubes and their methods of synthesis. It begins by defining carbon nanotubes as sheets of graphite rolled into cylinders that can have single or multiple layers. It then discusses their extraordinary mechanical properties and classification based on chirality. Common synthesis methods are also summarized, including chemical vapor deposition, plasma enhanced CVD, arc discharge in a magnetic field, and laser ablation of metallic catalysts. Medical applications of carbon nanotubes are briefly mentioned at the end.
Carbon nanotubes : Properties, Applications and synthesis
Carbon Nanotubes; Brief Description; Synthesis procedures; Properties; Geometry; Applications;Future possibilities
Nanotechnology in building construction materials
This PPT is about the use of Nano fines in existing Building material for the enhancement in their properties .
Presentation On Nanoparticles
The document summarizes a presentation on developing paclitaxel nanoparticles using human serum albumin (HSA) as a polymer. Paclitaxel is insoluble in water and has low bioavailability. Nanoparticles can increase paclitaxel's stability, target delivery to tumor sites, and reduce toxicity. The method involves dissolving paclitaxel in chloroform and mixing it with an HSA solution to form an emulsion. The chloroform is then evaporated to form paclitaxel-loaded HSA nanoparticles.
Seminar report on Carbon Nanotubes
Carbon nanotubes have extraordinary strength and unique electrical properties. They are classified as single-walled or multi-walled nanotubes. Common synthesis methods are arc discharge, laser ablation, and chemical vapor deposition. Key milestones include the discovery of 18.5 cm long nanotubes and the thinnest freestanding single-walled nanotube of about 4.3 Angstroms in diameter. Carbon nanotubes have immense strength, are harder than diamond, and are excellent thermal and electrical conductors.
Carbon nanotubes ppt
This document discusses carbon nanotubes, including their discovery in 1952, types (single-walled and multi-walled), structure, properties, synthesis methods, and potential applications. Carbon nanotubes have extraordinary strength and stiffness, along with high thermal and electrical conductivity. However, they can also be toxic and have crystallographic defects. The three main synthesis methods are arc discharge, laser ablation, and chemical vapor deposition. Carbon nanotubes show promise for applications in materials science, electronics, medicine, and other fields due to their unique properties at the nanoscale.
Nanoparticles powerpoint
Nano particles are extremely small particles that are now being used in many products including sunscreen. There is ongoing research about whether nano particles in sunscreen are safe. While nano particles help sunscreen go on clear rather than white, some studies show they may penetrate the skin and cause harm. Alternative natural nano particles from ivy are being researched as potentially safer options. Overall, the risks of nano particles in sunscreen are still being evaluated.
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Carbon nanotubes : Properties, Applications and synthesis
Carbon nanotubes : Properties, Applications and synthesis
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Carbon Nanotubes.ppt
Carbon nanotubes are cylindrical carbon molecules that have extraordinary properties making them potentially useful in many applications. They can be produced through methods like arc discharge, laser ablation, and chemical vapor decomposition. Carbon nanotubes are the strongest and most stiff materials known, with very high thermal and electrical conductivity. However, studies also show they could pose health risks if inhaled, and more research is still needed on their toxicity. Potential applications of carbon nanotubes include electronics, elevators to space, quantum computing, and more.
carbon nanotubes
Carbon nanotubes are cylindrical carbon molecules that exhibit extraordinary strength and unique electrical properties. They can be produced through arc discharge, laser ablation, and chemical vapor decomposition. Carbon nanotubes have the highest tensile strength and modulus of elasticity of any known material. They are also very good conductors of heat and electricity. Potential applications of carbon nanotubes include building elevators into space, creating novel transistors smaller than conventional ones, and representing quantum bits for quantum computing. However, carbon nanotubes may pose health risks if inhaled in small sizes similar to asbestos fibers.
ETE444-lec4-Carbon Nanotubes.pdf
This document provides an introduction to carbon nanotubes including their history, structure, and production methods. Some key points:
- Carbon nanotubes were discovered accidentally in the 1950s but interest grew in the 1990s with the ability to produce nearly perfect multi-walled carbon nanotubes as byproducts.
- Carbon nanotubes have a unique structure of rolled graphene sheets that allows them to exist as single-walled or multi-walled tubes. This structure gives them extraordinary mechanical and electrical properties.
- Common production methods include electric arc discharge, laser ablation, chemical vapor deposition, and high pressure carbon monoxide processes. Each method uses a carbon source and sometimes a metal catalyst to help synt
ETE444-lec4-Carbon Nanotubes.pdf
This document provides an overview of carbon nanotubes. It begins with a brief introduction describing carbon nanotubes as revolutionary materials discovered by accident that will significantly influence society. The document then covers the history of carbon nanotube discovery and various synthesis methods. Key points about the structure and properties of carbon nanotubes like their mechanical strength and electrical properties are summarized. Finally, potential applications of carbon nanotubes in areas like gas storage, sensors, and SPM probes are outlined.
Carbon nanotube
This presentation provides information on carbon nanotubes and their properties and applications. It discusses different types of carbon nanotubes including single-wall nanotubes, multi-wall nanotubes, Buckminsterfullerene, and C70 fullerene. Methods for characterizing carbon nanotubes are also covered, such as scanning electron microscopy, transmission electron microscopy, and atomic force microscopy. A wide range of potential applications for carbon nanotubes are presented, such as in conductive materials, composites, filtration, biomedical uses, electronics, and more.
Nanotubes
Carbon nanotubes are hollow cylindrical structures made of carbon atoms that were discovered in 1991. They exist in different forms depending on how the graphene is rolled up, and have extraordinary strength and conductive properties. Potential applications include use in electronics, optics, energy storage and generation, and advanced materials. Significant challenges remain in controlling nanotube structure and properties at scale for widespread applications.
Carbon nanotubes
This document discusses carbon nanotubes, including their discovery in the 1950s, classification as single-walled or multi-walled nanotubes, properties like strength and conductivity, common synthesis methods like arc discharge and chemical vapor deposition, and potential applications such as for solar cells, sporting goods, and neural networks. It also notes potential health risks from short carbon nanotubes and the need for further research on impacts.
Carbon nanotubes
This document provides information about carbon nanotubes. It begins with an acknowledgement and introduction section describing carbon nanotubes. It then discusses the history, chemistry, types (single-walled and multi-walled), methods of preparation (arc evaporation, laser vaporization, chemical vapor deposition), electrical and thermal properties, defects, and applications (water filtration, strengthening materials, capacitors, bone repair, displays, energy storage). It also notes potential health hazards from inhalation of short carbon nanotubes.
NanoTechnology-In-Construction-Carbon-Nano-Tube.pptx
The document discusses carbon nanotubes, including their unique cylindrical structure and extraordinary properties like being 100 times stronger than steel but only a fraction of the weight. It covers different types of carbon nanotubes like single-walled, multi-walled, and describes their structures. The predominant methods for synthesizing carbon nanotubes are also summarized, such as arc discharge, laser ablation, and chemical vapor deposition. Potential applications are mentioned, including uses in electronics, displays, medicine, and a hypothetical space elevator.
Carbon Nanotubes
New technology Model for 1 nm Transistors better than FIN-FET Technology.This slide Tells you in general about the nanotubes, how they are formed and why they are better than MOSFETs
Carbon nanotubes ppt
Allotropes of carbon with a cylindrical structure
Can be capped on the ends with buckyballs or open ended
Composed entirely of sp2 bonds
Carbon Nano-tubes in Civil Engineering
"A presentation on Carbon Nano-tubes"
List of Contents:
Introduction
Types and Classification of CNTs
Methods of Synthesis
Properties
Defects
Applications
Health Hazards
Pros and Cons
Scope
Conclusion
Created by:
Er. Ankit Chandan
ankit29chandan@gmail.com
https://www.facebook.com/ankit29chandan
Carbon nanotubes
The presentation must be downloaded, since there are power-point effects which makes it hard to see the full content without downloading the file.
growth of carbon nanotubes
This document summarizes carbon nanotubes, which were discovered in 1991. They are cylindrical structures made of rolled graphene sheets that exist in single-walled or multi-walled varieties. Common synthesis methods are chemical vapor deposition, arc discharge, and laser ablation, with each having advantages and disadvantages. Carbon nanotubes have extraordinary mechanical and electrical properties and potential applications include conductive materials, energy storage, electronics, and more due to their strength, flexibility, conductivity and other characteristics.
application of carbon nano tube in chromatography
This document discusses the application of carbon nanotubes in chromatography. It begins by describing carbon nanotubes and how they were discovered. It then explains different methods for producing carbon nanotubes and discusses their unique electrical, thermal, and mechanical properties. The document notes that carbon nanotubes can be used in gas chromatography and HPLC columns due to their large surface area and ability to form network structures with ionic liquids. It provides examples of separations achieved using carbon nanotube-based columns and compares their performance to conventional columns. In summary, this document outlines how carbon nanotubes can enhance chromatography separation due to their unique properties and discusses their use in various chromatographic applications and columns.
Structure, Synthesis and Functionalization of CNTs & fullerene
This document provides an overview of carbon nanotubes (CNTs) and fullerenes. It discusses the structure and properties of CNTs, including their mechanical, electrical, and thermal properties. It describes common synthesis methods for CNTs, such as arc discharge, laser ablation, and chemical vapor deposition. It also covers functionalization of CNTs through covalent and non-covalent methods. Applications of CNTs include use in batteries, electronics, and sensors. The document then discusses the structure and properties of fullerenes, as well as synthesis methods like arc discharge. It describes endohedral and exohedral fullerene modifications and applications in armor, materials, and lubricants.
Carbon nanotubes
This document discusses carbon nanotubes, including their structure, properties, production methods, and applications. Carbon nanotubes have a cylindrical structure composed entirely of sp2 bonds. They have excellent mechanical and thermal properties and can be metallic or semiconducting depending on their structure. Common production methods include arc discharge, laser ablation, and chemical vapor deposition. Potential applications of carbon nanotubes include use in structural materials, electronics, energy storage, and biomedicine. However, health effects of carbon nanotube inhalation require further study.
Nanotechnology in Engineering
Nanotechnology involves manipulating matter at the nanoscale, between 1 to 100 nanometers. It can be used to create new materials and devices with unique properties. Some common nanomaterials include carbon nanotubes, nanoparticles, nanowires, and quantum dots. Nanotechnology has applications in engineering like improving the strength of materials, electronics by enabling smaller devices, medicine for targeted drug delivery, and more. However, there are also concerns about the health and environmental impacts of nanoparticles that need further research. The future prospects of nanotechnology include overcoming challenges like cost to enable widespread applications across many industries.
ETE444-lec4-Carbon-Nanotubes.ppt
- Carbon nanotubes were discovered accidentally in the 1990s and have properties that could revolutionize technology. They are sheets of graphene rolled into cylindrical shapes that are only a few nanometers wide but can be hundreds of micrometers long.
- Carbon nanotubes are incredibly strong yet lightweight. A single-walled carbon nanotube can be up to 100 times stronger than steel relative to its thickness. They also conduct heat and electricity very well.
- Potential applications of carbon nanotubes include use in composite materials, electronics, energy storage, sensors, and biomedical devices due to their unique mechanical and electrical properties at the nanoscale.
ETE444-lec4-Carbon-Nanotubes.ppt
- Carbon nanotubes were discovered accidentally in the 1990s and have properties that could revolutionize technology. They are sheets of graphene rolled into cylindrical shapes that are only a few nanometers wide but can be hundreds of micrometers long.
- Carbon nanotubes are incredibly strong yet lightweight. A single-walled carbon nanotube can be up to 100 times stronger than steel relative to its thickness. They also conduct heat and electricity very well.
- Potential applications of carbon nanotubes include use in space elevators, hydrogen fuel cells, artificial muscles, electronics, sensors, and as reinforcements in composite materials. They are being researched for uses in fields like energy storage, medicine, and electronics.
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NanoTechnology-In-Construction-Carbon-Nano-Tube.pptx
NanoTechnology-In-Construction-Carbon-Nano-Tube.pptx
Structure, Synthesis and Functionalization of CNTs & fullerene
Structure, Synthesis and Functionalization of CNTs & fullerene
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Open Channel Flow: This topic focuses on fluid flow with a free surface, such as in rivers, canals, and drainage ditches. Key concepts include the classification of flow types (steady vs. unsteady, uniform vs. non-uniform), hydraulic radius, flow resistance, Manning's equation, critical flow conditions, and energy and momentum principles. It also covers flow measurement techniques, gradually varied flow analysis, and the design of open channels. Understanding these principles is vital for effective water resource management and engineering applications.
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Null Bangalore | Pentesters Approach to AWS IAM
#Abstract:
- Learn more about the real-world methods for auditing AWS IAM (Identity and Access Management) as a pentester. So let us proceed with a brief discussion of IAM as well as some typical misconfigurations and their potential exploits in order to reinforce the understanding of IAM security best practices.
- Gain actionable insights into AWS IAM policies and roles, using hands on approach.
#Prerequisites:
- Basic understanding of AWS services and architecture
- Familiarity with cloud security concepts
- Experience using the AWS Management Console or AWS CLI.
- For hands on lab create account on [killercoda.com](https://killercoda.com/cloudsecurity-scenario/)
# Scenario Covered:
- Basics of IAM in AWS
- Implementing IAM Policies with Least Privilege to Manage S3 Bucket
- Objective: Create an S3 bucket with least privilege IAM policy and validate access.
- Steps:
- Create S3 bucket.
- Attach least privilege policy to IAM user.
- Validate access.
- Exploiting IAM PassRole Misconfiguration
-Allows a user to pass a specific IAM role to an AWS service (ec2), typically used for service access delegation. Then exploit PassRole Misconfiguration granting unauthorized access to sensitive resources.
- Objective: Demonstrate how a PassRole misconfiguration can grant unauthorized access.
- Steps:
- Allow user to pass IAM role to EC2.
- Exploit misconfiguration for unauthorized access.
- Access sensitive resources.
- Exploiting IAM AssumeRole Misconfiguration with Overly Permissive Role
- An overly permissive IAM role configuration can lead to privilege escalation by creating a role with administrative privileges and allow a user to assume this role.
- Objective: Show how overly permissive IAM roles can lead to privilege escalation.
- Steps:
- Create role with administrative privileges.
- Allow user to assume the role.
- Perform administrative actions.
- Differentiation between PassRole vs AssumeRole
Try at [killercoda.com](https://killercoda.com/cloudsecurity-scenario/)
一比一原版(uoft毕业证书)加拿大多伦多大学毕业证如何办理
原版一模一样【微信:741003700 】【(uoft毕业证书)加拿大多伦多大学毕业证成绩单】【微信:741003700 】学位证,留信认证(真实可查,永久存档)原件一模一样纸张工艺/offer、雅思、外壳等材料/诚信可靠,可直接看成品样本,帮您解决无法毕业带来的各种难题!外壳,原版制作,诚信可靠,可直接看成品样本。行业标杆!精益求精,诚心合作,真诚制作!多年品质 ,按需精细制作,24小时接单,全套进口原装设备。十五年致力于帮助留学生解决难题,包您满意。
本公司拥有海外各大学样板无数,能完美还原。
1:1完美还原海外各大学毕业材料上的工艺:水印,阴影底纹,钢印LOGO烫金烫银,LOGO烫金烫银复合重叠。文字图案浮雕、激光镭射、紫外荧光、温感、复印防伪等防伪工艺。材料咨询办理、认证咨询办理请加学历顾问Q/微741003700
【主营项目】
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二.真实使馆公证(即留学回国人员证明,不成功不收费)
三.真实教育部学历学位认证(教育部存档!教育部留服网站永久可查)
四.办理各国各大学文凭(一对一专业服务,可全程监控跟踪进度)
如果您处于以下几种情况:
◇在校期间,因各种原因未能顺利毕业……拿不到官方毕业证【q/微741003700】
◇面对父母的压力,希望尽快拿到;
◇不清楚认证流程以及材料该如何准备;
◇回国时间很长,忘记办理;
◇回国马上就要找工作,办给用人单位看;
◇企事业单位必须要求办理的
◇需要报考公务员、购买免税车、落转户口
◇申请留学生创业基金
留信网认证的作用:
1:该专业认证可证明留学生真实身份
2:同时对留学生所学专业登记给予评定
3:国家专业人才认证中心颁发入库证书
4:这个认证书并且可以归档倒地方
5:凡事获得留信网入网的信息将会逐步更新到个人身份内,将在公安局网内查询个人身份证信息后,同步读取人才网入库信息
6:个人职称评审加20分
7:个人信誉贷款加10分
8:在国家人才网主办的国家网络招聘大会中纳入资料,供国家高端企业选择人才
办理(uoft毕业证书)加拿大多伦多大学毕业证【微信:741003700 】外观非常简单,由纸质材料制成,上面印有校徽、校名、毕业生姓名、专业等信息。
办理(uoft毕业证书)加拿大多伦多大学毕业证【微信:741003700 】格式相对统一,各专业都有相应的模板。通常包括以下部分:
校徽:象征着学校的荣誉和传承。
校名:学校英文全称
授予学位:本部分将注明获得的具体学位名称。
毕业生姓名:这是最重要的信息之一,标志着该证书是由特定人员获得的。
颁发日期:这是毕业正式生效的时间,也代表着毕业生学业的结束。
其他信息:根据不同的专业和学位,可能会有一些特定的信息或章节。
办理(uoft毕业证书)加拿大多伦多大学毕业证【微信:741003700 】价值很高,需要妥善保管。一般来说,应放置在安全、干燥、防潮的地方,避免长时间暴露在阳光下。如需使用,最好使用复印件而不是原件,以免丢失。
综上所述,办理(uoft毕业证书)加拿大多伦多大学毕业证【微信:741003700 】是证明身份和学历的高价值文件。外观简单庄重,格式统一,包括重要的个人信息和发布日期。对持有人来说,妥善保管是非常重要的。
Sri Guru Hargobind Ji - Bandi Chor Guru.pdf
Sri Guru Hargobind Ji (19 June 1595 - 3 March 1644) is revered as the Sixth Nanak.
• On 25 May 1606 Guru Arjan nominated his son Sri Hargobind Ji as his successor. Shortly
afterwards, Guru Arjan was arrested, tortured and killed by order of the Mogul Emperor
Jahangir.
• Guru Hargobind's succession ceremony took place on 24 June 1606. He was barely
eleven years old when he became 6th Guru.
• As ordered by Guru Arjan Dev Ji, he put on two swords, one indicated his spiritual
authority (PIRI) and the other, his temporal authority (MIRI). He thus for the first time
initiated military tradition in the Sikh faith to resist religious persecution, protect
people’s freedom and independence to practice religion by choice. He transformed
Sikhs to be Saints and Soldier.
• He had a long tenure as Guru, lasting 37 years, 9 months and 3 days
Impartiality as per ISO /IEC 17025:2017 Standard
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Presentation on Food Delivery Systems
This presentation is about Food Delivery Systems and how they are developed using the Software Development Life Cycle (SDLC) and other methods. It explains the steps involved in creating a food delivery app, from planning and designing to testing and launching. The slide also covers different tools and technologies used to make these systems work efficiently.
Height and depth gauge linear metrology.pdf
Height gauges may also be used to measure the height of an object by using the underside of the scriber as the datum. The datum may be permanently fixed or the height gauge may have provision to adjust the scale, this is done by sliding the scale vertically along the body of the height gauge by turning a fine feed screw at the top of the gauge; then with the scriber set to the same level as the base, the scale can be matched to it. This adjustment allows different scribers or probes to be used, as well as adjusting for any errors in a damaged or resharpened probe.
SCALING OF MOS CIRCUITS m .pptx
this ppt explains about scaling parameters of the mosfet it is basically vlsi subject
原版制作(Humboldt毕业证书)柏林大学毕业证学位证一模一样
原件一模一样【微信:bwp0011】《(Humboldt毕业证书)柏林大学毕业证学位证》【微信:bwp0011】学位证,留信认证(真实可查,永久存档)原件一模一样纸张工艺/offer、雅思、外壳等材料/诚信可靠,可直接看成品样本,帮您解决无法毕业带来的各种难题!外壳,原版制作,诚信可靠,可直接看成品样本。行业标杆!精益求精,诚心合作,真诚制作!多年品质 ,按需精细制作,24小时接单,全套进口原装设备。十五年致力于帮助留学生解决难题,包您满意。
本公司拥有海外各大学样板无数,能完美还原。
1:1完美还原海外各大学毕业材料上的工艺:水印,阴影底纹,钢印LOGO烫金烫银,LOGO烫金烫银复合重叠。文字图案浮雕、激光镭射、紫外荧光、温感、复印防伪等防伪工艺。材料咨询办理、认证咨询办理请加学历顾问微bwp0011
【主营项目】
一.毕业证【微bwp0011】成绩单、使馆认证、教育部认证、雅思托福成绩单、学生卡等!
二.真实使馆公证(即留学回国人员证明,不成功不收费)
三.真实教育部学历学位认证(教育部存档!教育部留服网站永久可查)
四.办理各国各大学文凭(一对一专业服务,可全程监控跟踪进度)
如果您处于以下几种情况:
◇在校期间,因各种原因未能顺利毕业……拿不到官方毕业证【微bwp0011】
◇面对父母的压力,希望尽快拿到;
◇不清楚认证流程以及材料该如何准备;
◇回国时间很长,忘记办理;
◇回国马上就要找工作,办给用人单位看;
◇企事业单位必须要求办理的
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Carbon nanotubes
- 2. What are Carbon nanotubes. •Carbon nanotubes (CNTs) are allotropes of carbon. These cylindrical carbon molecules have interesting properties that make them potentially useful in many applications in nanotechnology, electronics, optics and other fields of materials science, as well as potential uses in architectural fields. They exhibit extraordinary strength and unique electrical properties, and are efficient conductors of heat. Their final usage, however, may be limited by their potential toxicity.
- 3. How CNTs are made • Arc discharge – CNTs Can be found in the carbon soot of graphite electrodes during an arc discharge involving high current. This process yields CNTs with lengths up to 50 microns. • Laser Ablation – In the laser ablation process, a pulsed laser vaporizes a graphite target in a high-temperature reactor while an inert gas is inserted into the reactor. Nanotubes develop on the cooler surfaces of the reactor as the vaporized carbon condenses. • Other methods where CNTs are created: - Chemical Vapor Decomposition - Natural, incidental, and controlled flame environments
- 5. Properties • Strength • Electrical • Thermal • Defects • One-Dimensional Transport • Toxicity
- 6. Strength Properties • Carbon nanotubes have the strongest tensile strength of any material known. • It also has the highest modulus of elasticity. Material Young's Modulus (TPa) Tensile Strength (GPa) Elongation at Break (%) SWNT ~1 (from 1 to 5) 13-53E 16 Armchair SWNT 0.94T 126.2T 23.1 Zigzag SWNT 0.94T 94.5T 15.6-17.5 Chiral SWNT 0.92 MWNT 0.8-0.9E 150 Stainless Steel ~0.2 ~0.65-1 15-50 Kevlar ~0.15 ~3.5 ~2 KevlarT 0.25 29.6
- 7. Electrical Properties • If the nanotube structure is armchair then the electrical properties are metallic • If the nanotube structure is chiral then the electrical properties can be either semiconducting with a very small band gap, otherwise the nanotube is a moderate semiconductor • In theory, metallic nanotubes can carry an electrical current density of 4×109 A/cm2 which is more than 1,000 times greater than metals such as copper
- 8. Thermal Properties • All nanotubes are expected to be very good thermal conductors along the tube, but good insulators laterally to the tube axis. • It is predicted that carbon nanotubes will be able to transmit up to 6000 watts per meter per Kelvin at room temperature; compare this to copper, a metal well-known for its good thermal conductivity, which transmits 385 watts per meter per K. • The temperature stability of carbon nanotubes is estimated to be up to 2800o C in vacuum and about 750o C in air.
- 9. Defects • Defects can occur in the form of atomic vacancies. High levels of such defects can lower the tensile strength by up to 85%. • Because of the very small structure of CNTs, the tensile strength of the tube is dependent on its weakest segment in a similar manner to a chain, where the strength of the weakest link becomes the maximum strength of the chain.
- 10. One-Dimensional Transport • Due to their nanoscale dimensions, electron transport in carbon nanotubes will take place through quantum effects and will only propagate along the axis of the tube. Because of this special transport property, carbon nanotubes are frequently referred to as “one-dimensional.”
- 11. Applications • Nanotubes hold the promise of creating novel devices, such as carbon-based single-electron transistors, that significantly smaller than conventional transistors.
- 12. Nanotubes’ excellent strength to weight ratio creates the potential to build an elevator to space.
- 13. Quantum Computing • Nanotubes and other Fullerenes can be filled with molecules that have either an electronic or structural property which can be used to represent the quantum bit (Qubit) of information, and which can be associated with other adjacent Qubits.
- 14. Health Hazards • According to scientists at the National Institute of Standards and Technology, carbon nanotubes shorter than about 200 nanometers readily enter into human lung cells similar to the way asbestos does, and may pose an increased risk to health. • Carbon nanotubes along with the majority of nanotechnology, are an unexplored matter, and many of the possible health hazards are still unknown.
- 15. References • http://www.news-medical.net/news/22799.aspx • Chae, H.G.; Kumar, S. (2006). "Rigid Rod Polymeric Fibers". Journal of Applied Polymer Science 100:791-802: 791. doi:10.1002/app.22680. • Hong, Seunghun; Sung Myung (2007). "Nanotube Electronics: A flexible approach to mobility". Nature Nanotechnology 2: 207–208. doi:10.1038/nnano.2007.89 • Meo, S.B.; Andrews R. (2001). "Carbon Nanotubes: Synthesis, Properties, and Applications". Crit. Rev. Solid State Mater. Sci. 26(3):145-249: 145. doi:10.1080/20014091104189. • Kolosnjaj J, Szwarc H, Moussa F (2007). "Toxicity studies of carbon nanotubes". Adv Exp Med Biol. 620: 181–204. PMID 18217344 • Ebbesen, T. W.; Ajayan, P. M. (1992). "Large-scale synthesis of carbon nanotubes". Nature 358: 220–222. doi:10.1038/358220a0