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1. SCPY 661 Effects and applications of low energy ion beam with polymeric- and biomaterials Harry J. Whitlow
Department of Physics
PO Box 35 (YFL)
FIN-40014 University of Jyväskylä
Finland
Harry_J.Whitlow@phys.jyu.fi
2. Part–I Course details Introduction of the lecturer
Course objectives
Mode of instruction
Topics
Examination
Mid-term examinations
Exercises
3. Harry J. Whitlow Born 1954, London UK
Career
1972- 76 University of Bath UK (BSc(hons)1976, DSc 1999 )
1977 Brighton Poly/Philips Research labs (MSc)
1977-81 University of Sussex (D. Phil 1981)
1981-83 Postdoc Univ. of Aarhus Denmark
1983-85 Researcher, University of Helsinki, Finland
1985-90 Royal Institute of Technology Stockholm (docent 1987)
1990-2004 Lund University (Professor 2000)
2004-present University of Jyväskylä, Finland (Professor 2004)
4. Course objectives Course objectives
This postgraduate course is intended to give training in the central aspects of the interaction of low-energy ions with biological and polymer materials.
After completing the course the students will have knowledge on the basic interactions, how these modify polymer and biological materials, the equipment and practical considerations as well as how these can be applied in practice in applications.
5. Instruction Mode of instruction
The course consists of 45 h of lectures and 10 h of exercises.
In addition 50 h of private study is needed.
Language
The course and exercise classes are taught in English.
Credits
3 ECTS, (= 105 hours of full-time study)
6. Topics - I Lecture 1 : Overview
Definitions of low energy ion, biological materials, polymer (electroluminescent)
Lecture 2 : Introduction to Materials Science
Introduction to Polymer e.g. electroluminescent, Introduction to Biomolecules such as DNA
Lecture 3 : Basic ion sources
Different type of ion sources
7. Topics - II Lecture 4 : Ion sources and acceleration techniques :
accelerating tube, magnetic analysis, single- and double- end accelerator, Charged particle optics, Cyclotron, Synchrotron
Lecture 5: Introduction to ion-nucleus and ion-electron interaction
stopping power and force, dose, fluence, kinematics; lambda and k, cross section, differential cross section, interaction potentials
Lecture 6 : Continuation lecture: Primary interactions:
Generation of primary particles, scattering, concept of damages, Frenkel pair, ion-electrons interactions,
Application for: RBS, ERDA, PIXE, PIGE, NRA, STM, Chiang Mai's equipment, water permeability in membrane for pharmaceutical release computer simulation: TRIM
8. Topics-III Lecture 7: Secondary or Transient effects
Cascade of moving atoms (sputtering, SIMS, plasma desorption MS, threshold sputtering, linear cascade, nonlinear cascade) and electrons (excitation and ionization, ion traps, DNA damage, exciton, heat) Computer simulation: molecular dynamics, cascade mixing and polarization hydroxyapatite
Lecture 8:Long Term effects
Incorporation of implanted ions, range distribution, mathematical definition , doping, ion-chemical synthesis (reactive implantation), prosthesis, Film stress
Lecture 9: Electron effects
Bond breaking, hydrogen extraction, side-chain scission, main chain scission, cross linking (example PVC), radiolysis, oh water, DNA damage, single strand and double strand breaking, genetic mutation
9. Topics - III Lecture 10: Chemical Effects
Positive, negative resist, SU-8 for synchrotron, PMMA for electron; H-loss in connection to irradiation of biological (living) materials, hole in onion skin, local graphitization,
Lecture 11: introduction to electrical and optical properties
Fluorphores, where the properties are from, lab-on-a-chip, telecommunication applications
Lecture 12: Modification of optical and electrical properties with ion beams;
Refraction index changes, bleaching (or quenching) of luminescent, introduction of luminescent centres, non-radiative transitions
10. Topics - IV Lecture 13: Characterization for ion irradiation studies
S-, D-SIMS, STM, AFM, ESCA and synchrotron light (chemical shift), AES, XRF, S- and T- EM, confocal and fluorescence microscopy, UV-Vis, PL, FTIR, Raman, FIB, Exercise -BioimageXD
Lecture 14: Applications - I
Deposition of transparent conducting electrodes, surface treatment, cleaning, sterisation, water proofing with SF6, biological materials, crystallization of HA, biomimetic, cell adhesion cell signalling, cell wall interaction, integrins, how to make biocompatibility, 3D growth structure, reduction of cell adhesion, antifouling
Lecture 15 : Applications - II
Manufacture and process of lab-on-a-chip, silicon glass, anisotropic silicon etching, reactive ion Etching, polymer imprint technology (PMMA), MeV ion lithography, stamping, FIA, pumps, electrokinetic devices, scaling of Reynolds number
11. Examination Examination
-Credits: 3 ECTS credits
-Grading: Pass grades run from 1 to 5.
-Passing the course requires: A minimum score of 40%
Scoring points
20% the points are given for each mid-term examination
60% points can be obtained from the examination which is a take-home essay.
Examination times
The mid-term examinations will be held on:
Wednesday 23 Jan 2008 0900-1100
Wednesday 30 Jan 2008 0900-1100
Take home essay
Please discuss the theme of your research with Somsak and Harry so we can assign a suitable topic that is associated, but not the same as your dissertation topic
The final exam paper is to be submitted by e-mail by 2400 Finnish time on the ..... of ....
12. Mid-term exams Midterm exam 1:
Wed, Jan 23, 2008 time: 09:00-11:00
Contributes 20% to final grade
Contents: L1-L7
Midterm exam 2:
Wed, Jan 23, 2008 time: 09:00-11:00
Contributes 20% to final grade
Contents: L8-L13
13. Excercise Scheduled excercises
SRIM
Ion penetration and damage studies
Download software from www.srim.org
BioImageXD
Cell imaging with confocal microscopy
Download software from http://www.bioimagexd.net/
14. Pause
15. Part-II definitions Low energy ions
What is an ion?
Positive and negative ions
What is a low-energy ion?
Biological materials
What constitutes a living organism?
What is a biological material?
Cell structure
Biological size scales
Polymeric materials
Polymer structure
Repeating units
Thermoplastic and thermosetting
16. What is an ion? Ion:
An ion is an atom, cluster or molecule that carries an electronic charge because the number of electrons differs from the sum of number of protons in the nucleus/nuclei
Electron affinity
The amount of energy that is liberated by a gaseous atom, cluster or molecule when an electron is added to it.
Ionisation energy.
The smallest amount of energy required to remove the most weakly bond electron from an atom, cluster or molecule of a gas.
17. Electron affinity
18. Single ionisation energy
19. Ionisation levels (eV)
20. Atomic Clusters Atoms can form clusters, e.g. Au8
Useful to study transtion atoms?molecules
Tendancy to forms ”magic” clusters e.g. Si4+, Si6+ and Si10+.
Cluster ions have large momentum even for small kinetic energy.
Useful for hammering a surface to produce a flat topography
21. Molecular ions Just as atoms can be ionised – molecules and radicals can too!
CH3+ , OH-, Cl2+
Plasma desorption off surfaces allows molecules of large labile biomolecules to be produced.
Used as basis for mass spectrocopy
22. Highly charged ions (HCI) Highly charged ions (HCI) are ions with a very high charge state – close to fully stripped.
Ar9+, Xe42+
HCI carry a large potential energy
Low kinetic energy implies large energy desposition close to surface.
Mechanism unknown
23. Hollow atoms Hollow atoms are ions where the inner shells are ionsied but not the outer shells.
Decay spontaniosly by X-ray, Auger and K-K transitions
24. Polymeric materials Definition:
A polymer is a substance composed of repeating structural units connected by covalent chemical bonds
History
1811 Braconnot work on cellulose
1833 Jöns Jakob Berzelius (Swedish chemist) gave name from Greek (poly+meros)
1901 Bakelite (phenolic resin)
25. Monomers Monomer
Repeating unit along the backbone
Homopolymers
Single type of monomer
E.g. Polyethylene
Copolymers
More that one type of monomer
E.g. Methylene-vinyl acetate
26. Polyelectrolytes Polyelectrolyte
Polymer containing ionisable sub-units
Dissociate in water
Form a viscous fluid
Form basis of thickeners, emusifiers, floculants
Ingredient in soaps, shampoo etc
Ionomer
Polyelectrolyte with low fraction of ionisable sub units
<~12% inonisable units
High rigidity at room temperture themoplastics
Conducting polymers
27. Conductive polymers
28. Luminescence Luminescence is the result of radiative recombination of electrons and holes
Chemoluminescence
Bioluminescence
Crystalloluminescence
Electroluminescence
Cathodoluminescence
Mechanoluminescence
Triboluminescence
Fractoluminescence
Piezoluminescence
Photoluminescence
Phosphorescence
Fluorescence
Radioluminescence
Sonoluminescence
Thermoluminescence + more
29. Singlet and triplet states in molecules Singlet and Triplet states
Singlet spin-paired
Triplet unpaired spin
Long lifetime
30. Electroluminescence Electroluminescence is luminescence brought about by an electric current
Electrons and holes injected into the semiconductor e.g. forward biased p-n junction
Direct recombination
Materials:
ZnS:Cu, ZnS:Ag
Diamond, SiC
III-V semiconductors
InP,GaAs,and GaN
Organic semiconductors
31. Biomaterials Definitions:
Somewhat vague and confused!
Any material that comprises part or whole of a living structure
Natural or man made
Biomedical device
Performs, supports or replaces natural function
32. Other meanings of biomaterials Biological matter
Biocompatible material and bioapplicable material
Biologically derived material (or biotic material)
Bio-based material
Biological material:
Biological tissue, or just tissue
Biomass, living or dead biological matter, often plants grown as fuel
Biomolecule, a chemical compound that naturally occurs in living organisms
Biotic material, from living things
Bio-based material, a processed biotic material
Cellular component, material and substances of which cells (and thus living organisms) are composed
Organic material (or organic matter), derived from living things or containing carbon
Viable material, capable of living, developing, or germinating under favourable conditions. (see: viability)
33. Bio = life Characteristics of life
Homeostasis
Regulation of internal environment
Organisation
One or more cells
Metabolism
Growth
Adaption
Change over a period of time to adapt to environment
Response to stimuli
Motion
Reproduction
Able to produce new organisms Cells are the fundamental unit of life
Self contained
Self-organised
Carry out specialised functions
Reproduce as necessary
Carries instructions for all of these activities
Non-living bioentities
Virus
Evolutionary developed DNA in protein capsid
Reproduces using host cell
Prion = PRoteinaceous Infectious particle (-on)
Reproduce by inducing refolding of normal proteins into an infectious form
34. Biological size scales
35. Generic animal cell
36. The End