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Nano technology

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Title: Nano technology


1
Nano technology
  • John Summerscales
  • School of Engineering
  • University of Plymouth

2
Outline of lecture
  • orders of magnitude
  • nanostructures
  • carbon graphene, nanotubes
  • other monolayers
  • nanofibres
  • exfoliated clays
  • electrospinning
  • fabrication, composites and probes
  • MEMS
  • deformed crystals

3
Orders of magnitude
x 10-x 10x
3 milli- (m) kilo- (k)
6 micro- (µ) mega- (M)
9 nano- (n) giga- (G)
12 pico- (p) tera- (T)
15 femto- (f) peta- (P)
18 atto- (a) exa- (E)
  • note that capital K is used, in computing, to
    represent 210 or 1024, while k is 1000.

4
Sub-metre scales
0.0532 nm radius of 1s electron orbital 0.139
nm C-C bond length in benzene 0.517 nm
lattice constant of diamond
atto- femto- pico- nano- micro- milli- metre
5
Nanostructures
  • surface structures with feature sizesfrom
    nanometres to micrometres
  • white light optics limited to 1µm
  • use electron-beam or x-ray lithographyand
    chemical etching/deposition
  • image calcium fluorideanalog of a photoresist
    fromhttp//mrsec.wisc.edu/seedproj1/see1high.html

6
Carbon
  • Elemental carbon may be
  • amorphous
  • or one of two crystalline forms
  • diamond (cubic crystal sp3 structure)
  • graphite (contiguous sp2 sheets)
  • graphene (single atom thickness layers of
    graphite)
  • or at nanoscale can combine to form
  • spheres (buckminsterfullerenes or bucky balls)
  • and/or nanotubes
  • or other allotropes, including
  • graph(a/o/y/idy)ne and novamene (sp3/sp2)

7
Graphene
  • single atom thickness layers of graphite
  • thinnest material known
  • one of the strongest materials known
  • conducts electricity as efficiently as copper
  • conducts heat better than all other materials
  • almost completely transparent
  • so dense thateven the helium atom cannot pass
    through
  • http//www.graphene.manchester.ac.uk/

8
Graphene
Property Units Magnitude Comment Source
Thickness nm 0.33 1
Areal density µg/m2 770 1g / football field 2
Tensile modulus GPa 500 2
Tensile strength GPa 1000 333x virgin CF 1
Transparency absorption 2.3 1
  • in-plane bond length 0.142 nm (vs 0.133
    for CC bond) ... but measuring to what electron
    density in the orbital?
  • http//www.graphene.manchester.ac.uk/story/propert
    ies/
  • http//www.graphenea.com/pages/graphene-properties

9
Penta-graphene
  • announced Feb. 2015
  • stable to 1000K (727ºC)
  • semiconductor
  • auxetic

image from http//www.pnas.org/content/suppl/2015/
01/27/1416591112.DCSupplemental/pnas.1416591112.sa
pp.pdf
10
Nanotubes
  • Carbon-60 bucky-balls (1985)
  • graphitic sheets seamlessly wrappedto form
    cylinders (Sumio Iijima, 1991)
  • few nano-meters in diameter, yet (presently) up
    to a milli-meter long
  • Image from http//www.rdg.ac.uk/scsharip/tubes.ht
    m

11
Nanotubes
  • SWNT single-wall nano-tube
  • benzene rings may be
  • zigzag aligned with tube axis
  • armchair normal to tube axis
  • chiral angled to tube axis
  • Image from http//www.omnexus.com/documents/share
    d/etrainings/541/pic1.jpg via
  • http//www.specialchem4polymers.com/resources/etra
    ining/register.aspx?id541lrjec
  • MWNT multi-wall nano-tube
  • concentric graphene cylinders

12
Nanotube production
  • arc discharge through high purity graphite
    electrodes in low pressure helium (He)
  • laser vapourisation of a graphite target sealed
    in argon (Ar) at 1200C.
  • electrolysis of graphite electrodes immersed in
    molten lithium chloride under an Ar.
  • CVD of hydrocarbonsin the presence of metals
    catalysts.
  • concentrating solar energy onto carbon-metal
    target in an inert atmosphere.

13
Nanotube purification
  • oxidation at 700C (lt5 yield)
  • filtering colloidal suspensions
  • ultrasonically assisted microfiltration
  • microwave heating together with acid treatments
    to remove residual metals.

14
Nanotube properties
  • SWNT (Yu et al)
  • E 320-1470 (mean 1002) GPa
  • s 13-52 (mean 30) GPa
  • MWNT (Demczyk et al)
  • E 800-900 GPa
  • s 150 GPa

15
2D group IV element monolayers
  • Central column of periodic table
  • (covalent bonding atoms)
  • graphene (2D carbon)
  • silicene (2D silicon) unstable
  • germanene (2D germanium) rare
  • stanene (2D tin)
  • plumbene (2D lead) early days
  • other 2D monolayers
  • borophene (2D boron / Group III)
  • boron nitride (BN / Groups III/V)

16
Exfoliated clays
  • layered inorganic compoundswhich can be
    delaminated
  • most common smectite clay used for nanocomposites
    is montmorillonite
  • plate structure with a thickness of one
    nanometre or less and an aspect ratio of
    10001(hence a plate edge of 1 µm)

17
Exfoliated clays
  • relatively low levels of clay loading
  • improve modulus
  • improve flexural strength
  • increase heat distortion temperature
  • improve gas barrier properties
  • without compromising impact and clarity

18
Nano-fabrication
  • electrospinning
  • chemical vapour deposition
  • electron beam or UV lithography
  • pulsed laser deposition
  • composites
  • nano-particle agglomeration (clustering)

19
Electrospinning
  • characteristics of both
  • electrospraying, and
  • conventional solution dry spinning of fibers
  • electrical charge drawsvery fine (typically µm
    or nm) fibresfrom a liquid.
  • image from https//en.wikipedia.org/wiki/Electrosp
    inning

20
Nanocellulose reinforced polymer nanocomposites
  • Kargarzadeh et al in Polymer, December 2017.

Image https//ars.els-cdn.com/content/image/1-s2
.0-S0032386117309163-fx1_lrg.jpg
21
Curran carrot fibres
  • CelluComp (Scotland)
  • nano-fibres extracted from vegetables
  • carrot nano-fibres claimed to have
  • modulus of 130 GPa
  • strengths up to 5 GPa
  • failure strains of over 5
  • potential for turnips, swede and parsnips
  • 1st product "Just Castcomposite fly-fishing
    rod.

22
Nano-probes
  • atomic force microscope
  • scanning tunnelling microscope
  • superconducting quantum interference device
    (SQUID)

23
Atomic force microscope
measures force and deflection at nanoscale
  • image from http//en.wikipedia.org/wiki/Atomic_for
    ce_microscope

24
Scanning tunnelling microscope
  • scans an electrical probe over a surface to
    detect a weak electric currentflowing between
    the tip and the surface
  • image fromhttp//nobelprize.org/educational_games
    /physics/microscopes/scanning/index.html

25
Superconducting QUantum Interference Device
(SQUID)
  • measures extremely weak magnetic signals
  • e.g. subtle changes in the electromagnetic energy
    field of the human body.

26
MEMS micro electro mechanical systems
  • Microelectronics and micromachiningon a silicon
    substrate
  • MEMS electrically-driven motors smaller than the
    diameter of a human hair
  • Image from http//www.memsnet.org/mems/what-is.htm
    l

27
Controlled crystal growth
  • Brigid Heywood
  • Crystal Science Group at Keele
  • controlling nucleation and growthof inorganic
    materialsto make crystalline materials
  • protein templates

28
Summary
  • orders of magnitude
  • nanostructures
  • carbon graphene, nanotubes
  • other monolayers
  • nanofibres
  • exfoliated clays
  • electrospinning
  • fabrication, composites and probes
  • MEMS
  • deformed crystals

29
Acknowledgements
  • Various websites from whichimages have been
    extracted

30
To contact me
  • Dr John Summerscales
  • ACMC/SMSE, Reynolds Room 008
  • University of Plymouth
  • Devon PL4 8AA
  • 01752.5.86150
  • 01752.5.86101
  • jsummerscales_at_plymouth.ac.uk
  • http//www.plymouth.ac.uk/staff/jsummerscales
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