Nanotechnology/Nanomaterials

From Wikibooks, open books for an open world
Jump to navigation Jump to search
Nanotechnology

01. Introduction02. Seeing Nano03. Physics at the Nanoscale04. Nanomaterials
05. Nanosystems06. Nanoengineering07. Nano and Biotechnology08. Environmental Nanotech
09. Nano and Society10. Glossary



Nanotechnology Wikibook Chapters: 01020304050607080910

Navigate
<< Prev: Background Material
>< Main: Nanotechnology
>> Next: Overview of Production Methods

<<< Prev Part: Physics - on the nanoscale
>>> Next Part: Nanosystems


This part will give an overview of nanomaterials - the production methods, their properties, brief examples of applications and demonstrations of their capabilities.

Apart from a general overview of production methods, we have divided the materials as

  • Semiconducting
  • Metallic
  • Organic

A division that might be up for revision shortly.

One way to classify a material is its electronic structure

Overview of the electronic structure of the different fundamental classes of materials. Atoms have discrete energy levels for each electronic state. Electronic transitions by eg. optical excitation can change the state of the atom. Molecules can also have discrete energy levels, but the more complex structure also gives a much more complex diagram of electronic states. In addition, the molecules con rotate and vibrate which modulates the oberserved energy levels. Insulators can be seen as a condensed phase of molecules with little electronic connection between neighboring molecules for conducting a current. Only when excitation is made with an energy above the several eV bandgap will conduction be possible. Semiconductors have a more narrow bandgap and even at room temperature a few conduction electrons will be excited into the conductance band. Doped Semiconductors have higher electrical conductance because added dopants provide conduction electrons. Metals can be considered as ionized metal atoms in a sea of free electrons, giving a high conductivity and high reflectivity of light (as long as it is not too high in frequency).

Another is according to their geometry

overview of nanoscale structure geometries

Overview of nanomaterials[edit | edit source]

A brief overview table of nanostructures
Type Structure Production Properties
Buckyballs/ C60
Buckminsterfullerene C60 -60 Carbon atoms arranged as in football
Single Wall Carbon Nanotubes (SWCNT)
This animation of a rotating Carbon nanotube shows its 3D structure. A single shell of carbon atoms arranged in a cylindrical chicken-wire-like hexagonal structure with diameter from about 2 nm.
Semiconducting or metallic depending on how the carbon lattice is twisted.
Multi Wall Carbon Nanotubes (MWCNT) Concentric shells of SWCNT, diameter up to hundreds of nm
Silicon Nanowires and heterostructures Silicon crystals with diameters from a few nm Typically VLS growth
III-V Nanowires crystals with diameters from a few nm typically VLS growth. A wealth of heterostructures can be formed to make tunnel barrier junctions etc. Semiconducting, often optically active and fluorescing due to direct bandgap (unlike silicon).
Gold nanoparticles
Silica nanoparticles
Platinum nanoparticles small metallic clusters Used as catalysts in many reactions

Further reading[edit | edit source]

References[edit | edit source]

See also notes on editing this book about how to add references Nanotechnology/About#How_to_contribute.




Nanotechnology Wikibook Chapters: 01020304050607080910