SYNTHESIS OF THIN FILMS

1. SYNTHESIS OF THIN FILMS

2. FILMS - FORM? • Supported - substrate type - effect of interface – single crystal (oriented) or glassy • Free standing - synthetic strategy - air/liquid or liquid/liquid interface or substrate lift-off • Epitaxial - lattice matching and tolerance with underlying substrate • Superlattice - artificial multilayer – periodic or aperiodic • Patterned - chemical or physical lithography – bottom-up synthesis or top-down physical methods

3. FILMS - WHEN IS A FILM THICK OR THIN? • Monolayer - atomic, molecular thickness • Multilayer - compositional superlattice - scale - periodicity • Bulk properties - scale - thickness greater than l(e,h) • Quantum size effect - 2D spatial confinement – quantum confined along z, free electron behavior along x,y – called quantum wells – enable range of quantum devices

4. THIN FILMS VITAL IN MODERN TECHNOLOGY • Protective coatings • Optical coatings - antireflection coatings • Electrochromic windows – photochromic spectacles • Dielectric film – low k circuit packaging – high k transistor gate insulation • Optical filters • Microelectronic devices and circuits • Optoelectronic devices and circuits • Photonic devices and circuits

5. THIN FILMS VITAL IN MODERN TECHNOLOGY • Electrode surfaces – solar cells, fuel cells, lithum solid state batteries • Xerography, photography • Electrophoretic, electrochromic, electrodewettability displays • Catalytic and photocatalytic surfaces • Nanoporous membranes – gas separation • Information storage - magnetic, magneto-resistant, magneto-optical, optical, flash

6. FILM PROPERTIES - ELECTRICAL, OPTICAL, MAGNETIC, MECHANICAL, ADSORPTION, PERMEABILTY, CHEMICAL • Thickness and Surface : Volume ratio • Surface vs bulk structure - surface reconstruction, dangling bonds – unsatisfied valencies, surface roughness • Hydrophobicity - hydrophilicy - wettability • Composition – surface vs bulk • Texture - single crystal, microcrystalline, orientation, glassy • Form - supported or unsupported (free-standing) - nature of substrate - patterned or un-patterned

7. METHODS OF SYNTHESIZING THIN FILMS • ELECTROCHEMICAL, PHYSICAL, CHEMICAL • Cathodic or anodic • Electroless deposition • Laser ablation • Cathode sputtering, vacuum evaporation, e-gun • Thermal oxidation, nitridation, sulfidation

8. METHODS OF SYNTHESIZING THIN FILMS • ELECTROCHEMICAL, PHYSICAL, CHEMICAL • Liquid/melt phase epitaxy • Self-assembly - surface molecule anchoring, organization, close-packing, monolayers or multilayers • Discharge (plasma) techniques - RF, microwave • Chemical vapor deposition CVD, metal organic chemical vapor deposition MOCVD • Molecular beam epitaxy, supersonic cluster beams, aerosol deposition

9. ANODIC OXIDATIVE DEPOSITION OF FILMS • Deposition of metal oxide films, such as alumina, titania by oxidation of metal electrode in aqueous salts or acids • Deposition of conducting polymer films by oxidative polymerization of monomer, such as thiophene, pyrrole, aniline, acetylene

10. ANODIC OXIDATION OF Al IN OXALIC OR PHOSPHORIC ACID TO FORM ALUMINUM OXIDE • Pt|H3PO4, H2O|Al ECCell • Al Al3+ + 3e- Anode • PO43- +2e- PO33- + O2- Cathode • 2Al3+ + 3O2-g-Al2O3 (annealing) a-Al2O3 • Voltage control of oxide thickness • Al3+/O2- diffuse through growing layer of Al2O3

11. ANODIC OXIDATION OF PATTERNED Al DISC TO MAKE PERIODIC NANOPOROUS Al2O3 MEMBRANE SiC patterned master harder than Al to make nanoimprint replica How to remove residual Al and Al2O3 barrier layer??? 2Al + 3PO43- Al2O3 + 3PO33- 2Al + 3C2O42- Al2O3 + 6CO + 3O2-

12. ANODIC OXIDATION OF PATTERNED Al DISC TO MAKE PERIODIC NANOPOROUS Al2O3 MEMBRANE Aqueous HgCl2 dissolves Al to give Hg and Al(H2O)63+and H3PO4 dissolves Al2O3 barrier layer to give Al(H2O)63+ - yields open channel membrane

13. ANODIC OXIDATION OF LITHOGRAPHIC PATTERNED Al TO PERIODIC NANOPOROUS Al2O3 Not bad for chemistry!!! Hexagonal close packed nanochannel membrane

14. ANODIC OXIDATION OF LITHOGRAPHIC PATTERNED Al TO PERIODIC NANOPOROUS Al2O3 40V Voltage control of channel diameter 50-500 nm accessible 60V 80V

15. PROPOSED MECHANISM OF ALUMINA PORE FORMATION IN ANODICALLY OXIDIZED ALUMINUM Electric and strain fields guide and organize hcp channel growth SELF ORGANIZED SELF LIMITING GROWTH OF PORES

16. Templated synthesis of metal barcoded nanorods

17. Collection of multi-metal nanorods imaged in an optical microscope by the different reflectivity’s of different metal segments, Science 2001, 294, 137

18. 240 nm • Optical (A) and field emission scanning electron microscopy FE-SEM (B) images of an Au-Ag multi-stripe nanorods • 550-nm Au stripes and Ag stripes of 240, 170, 110, and 60 nm -top to bottom 550 nm 170 nm 110 nm 60 nm

19. Orthogonal assembly on nanorods. Butyl isonitrile is bound non-selectively to Pt and Au surfaces. Aminoethanethiol displaces isonitriles selectively on gold but not on platinum. Rhodamine isocyanate is reacted with terminal amino groups to fluorescently label gold segments. -NH-CS-NH- thiourea linkage of rhodamine fluorescent dye to Au segment

20. DNA sandwich hybridization assay on metal barcode nanorods - Science 2001, 294, 137

21. SYNTHESIS OF CHEMICALLY POWERED NANOROD MOTORS ? Challenges: understanding origin of nanorod motion, control of velocity and direction (size, shape, surface, solvent, fuel effects), performing a purposeful task like controlled pick-up and drop-off of a payload at specific sites like anticancer drug targeted delivery Ozin et al Chem Comm, AdvMater 2006, Mallouk et al JACS 2005

23. ANODIC OXIDATION OF Si TO FORM POROUS Si: THROWING SOME LIGHT ON SILICON • Typical electrochemical cell to prepare PS by anodic oxidation of heavily doped p+-type Si • PS comprised of interconnected nc-Si with H/O/F surface passivation • nc-Si right size for QSEs and red light emission observed during anodic oxidation – electroluminescence

24. ELECTRONIC BAND STRUCTURE OF DIAMOND SILICON LATTICE • band structure of Si computed using density functional theory with local density and pseudo-potential approximation • diamond lattice, sp3 bonded Si sites • VB maximum at k = 0, the G point in the Brillouin zone, CB minimum at distinct k value • indirect band gap character, very weakly emissive behavior • absorption-emission phonon assisted • photon-electron-phonon three particle collision very low probability, thus band gap emission efficiency low, 10-5 %

25. SEMICONDUCTOR BAND STRUCTURE: CHALLENGE, EVOKING LIGHT EMISSION FROM Si • Effective Mass Approximation Rexciton ~ 0.529e/mo where e = dielectric constant, reduced mass of exciton mo = memh/(me + mh) • Note exciton size within the bulk material defines the size regime below which significant QSEs on band structure are expected to occur, clearly < 5 nm to make Si work

26. REGULAR OR RANDOM NANOSCALE CHANNELS IN ANODICALLY OXIDIZED SILICON WAFERS • Anodized forms of p+-type Si wafer • Showing formation of random (left) and regular (right) patterns of pores • Lithographic pre-texturing directs periodic pore formation

27. PORE FORMING PROCESS IN ANODICALLY OXIDIZED SILICON WAFERS • Basics of electrochemical cell - p+ Si wafer anode in contact with aqueous HF electrolyte – simplified electrochemistry: • Si  Si(4+) + 4e • Si(4+) + 6F(-)  [SiF6]2- • 4H(+) + 4e  2H2 • Mechanism of natural self-limiting process for regular pore formation based on wider band gap of PS compared to bulk Si and respective redox potentials for anodic oxidation • Hence easier for pore to elongate without increasing its diameter/thinning walls promoting formation of channels

28. KEY ISSUES: ORIGIN OF PHOTO- AND ELECTROLUMINESCENE OF POROUS SILICON • Origin of luminescence key point- as bulk Si is indirect band gap semiconductor with very weak light emission • Competing models for light emission include quantum-spatial confinement, siloxenes and SiOH • Luminescent nc-Si structure requires SiO, SiH surface bonds - caps dangling bonds -removes killer traps in band gap • Size dependence of k, m selection rules, scaling laws determine light emission properties • Mechanical, photochemical, chemical stability of pSi are key factors for devices – safety too - care with humidity control and toxic silane evolved Si[H]surface + H2O  SiH4 favored for high surface area material like pSi • Efficient e-h charge-injection required for practical LED

29. *(SiH) CB CB capping Si cluster dangling bond with H, F, O forms bonding-antibonding SiH -orbitals, moves killer trap states out of the gap facilitates radiative over non-radiative relaxation VB VB (SiH) Sin HxSin MAKING NANOCRYSTALLINE SILICON LUMINESCENT: SURFACE CAPPING

30. e h POROUS SILICON LED ITO e-h recombination emission pSi Au

31. LIGHT WORK BY THE SILICON SAMURAIWHERE IT ALL BEGAN AND WHERE IT IS ALL GOING??? FROM CANHAM’S 1990 DISCOVERY OF PL AND EL ANODICALLY OXIDIZED p+-DOPED Si WAFERS, TO NEW LIGHT EMITTING SILICON NANOSTRUCTURES, AND DREAM OF SILICON OPTOELECTRONICS AND PHOTONICS COMPUTING – ACTUALLY BIOSENSORS EVENTUALLY MADE IT TO THE REAL WORLD !!!

32. CHEMICAL VAPOUR DEPOSITION • Pyrolysis, photolysis, chemical reaction, discharges - RF, microwave facilitated deposition processes • Epitaxial films, correct matching to substrate lattice • CH4 + H2 (RadioF, MicroW)  C, diamond films (perfect non-stick frying pan – inert, hard, transparent, non-stick, high thermal conductivity) • Et4Si (thermal, air)  SiO2 • SiCl4 or SiH4 (thermal T, H2) a-H:Si or nc-H:Si • SiH4 + PH3 (RF)  n-Si (ppm P)

33. CHEMICAL VAPOUR DEPOSITION • Si2H6 + B2H6 (RF)  p-Si (ppm B) • Single source precursor xSiH3SiH2SiH2PH2 + (1-x)SiH4 (RF) n-Si precise control of doping level • Me3Ga (laser photolysis, heating)  Ga • Me3Ga + AsH3 + H2 (T,P) GaAs + CH4 • Si (laser evaporation, molecular beam, high to low P supersonic jet, ionization) Sin+ (size selected MS - cluster deposition)  Si

34. H H H H H H H H H H H H H H H H H H H H H H H H H H H H H H H H H H H Amorphous hydrogenated silicon a-H:Si, easy to form thin film by CVD Hydrogen capping of dangling surface sp3 bonds Reduces surface electron killer traps Enhances electrical conductivity compared to a-Si but less than bulk c-Si Poly-domain texture Can be crystallizes thermally or with hydrogen plasma treatment Useful for pn and pin junction large area solar cell devices

35. *(SiH) CB CB capping Si cluster dangling bond with H forms bonding-antibonding SiH -orbitals, moves killer trap states out of the gap facilitates charge transport and radiative relaxation VB VB (SiH) Sin HxSin REMOVING DANGLING BONDS BY Si-H CAPPING

36. METAL ORGANIC CHEMICAL VAPOR DEPOSITIONMOCVD • Invented by Mansevit in 1968 • Recognized high volatility and chemical reactivity of metal organic compounds as sources for semiconductor thin film preparations • Enabling chemistry: electronic, optical quantum devices • Quantum wells and superlattices • Occurs for 5-500 Ångstrom layers • Known as artificial superlattices

37. Schematic energy band diagram of a quantum well structure showing confined electron and hole states produced by large Eg GaAlAs layers sandwiching small Eg GaAs depicting quantum size effects and some possible optical transitions CB edge GaAlAs CB/VB edges GaAs L VB edge GaAlAs En = n2p2h2/2m*L2

38. METAL ORGANIC CHEMICAL VAPOR DEPOSITION, MOCVD • Quantum confined electrons and holes when thickness of quantum well L is comparable to the wavelength of an electron or hole at the Fermi level of the material, band diagram shows confined particle states and quantization effects for electrical and optical properties • Discrete electronic energy states rather than continuous bands, given by solution to the simple particle in a box equation, assuming infinite barriers for the wells, m* is the effective mass of electrons and holes • En = n2p2h2/2m*L2 • Tunable thickness, tailored composition materials, do it yourself quantum mechanics materials for the semiconductor industry

39. METAL ORGANIC CHEMICAL VAPOR DEPOSITION, MOCVD • Quantum well structure synthesized by depositing a controlled thickness superlattice of a narrow band gap GaAs layer sandwiched by two wide band gap GaxAl1-xAs layers using MOCVD • Ga(Al)Me3 + AsH3 (H2, T)  Ga(Al)As + CH4 • Artificial superlattices, designer periodicity of layers, quantum confined lattices, thin layers, epitaxially grown, x determines electronic band gap • Example: GaxAl1-xAs|GaAs|GaxAl1-xAs

40. MOCVD • Example: GaxAl1-xAs|GaAs|GaxAl1-xAs • n- and p-doping achievable by having excess As or Ga respectively in a GaAs layer • Composition and carrier concentration controls refractive index (lower RI cladding, TIR optical confinement) and electrical conductivity (p-n and p-n-p junction devices), in a semiconducting superlattice • Enables electron (quantum) and photon (RI) confinement for electronic, optoelectronic, optical and photonic devices

41. MOCVD • Examples include: • (i) multiple quantum well laser • (ii) quantum cascade laser • (iii) distributed feedback laser • (iv) resonant tunneling transistor • (v) high electron mobility transistor (HEMT) • (vi) laser diode

42. Resonant tunneling transistor

43. BAND GAP ENGINEERING OF SEMICONDUCTORS • MOCVD, LPE, CVD, CVT, MBE all deposition techniques that provide angstrom precise control of film thickness • Together with composition control one has a beautiful synthetic method for fine tuning the electronic band gap and hence most of the important properties of a semiconductor quantized film

44. BAND GAP ENGINEERING OF SEMICONDUCTORS • Key is to achieve epitaxial lattice matching of film with underlying substrate • Avoids interfacial lattice strain, elastic deformation, misfit dislocations, defects • All of these problems serve to increase carrier scattering, decrease charge-transport, increased quenching of e-h recombination luminescence (killer traps), thereby reducing the efficacy of the material for advanced device applications

45. MOCVD SINGLE SOURCE PRECURSORS • Me3Ga, Me3Al, Et3In (synthesis GaCl3 + MeLi/R2Mg/RMgI) • NH3, PH3, AsH3 (synthesis Mg3As2/HCl), Bu3PS, Bu3PSe • H2S, H2Se, (Me3Si)2S, (Me3Si)2Se • Me2Te, Me2Hg, Me2Zn, Me4Pb, Et2Cd

46. MOCVD SINGLE SOURCE PRECURSORS • E.g. synthesize an IR detector based on p-n photodiode • Me2Cd + Me2Hg + Me2Te (H2, 500oC)  HgxCd1-xTe • p-HgxCd1-xTe/n-HgxCd1-xTe • p- and n-doping requires precise control of Hg/Cd and Te stoichiometry • x determines the electronic bandgap – tuned to IR wavelength range for detector • Toxic materials – safe handling and disposal of toxic waste!!!

47. Schematic of cold wall MOCVD system Single crystal substrate on inductively heated or resistively heated susceptor – mass flow control of precursors MOCVD deposited film H2/AsH3/PH3 Water cooling H2/InMe3/GaMe3 Thermocouple H2/PEt3 H2/n-dope H2S/p-dope ZnMe2 Waste gases

48. MOCVD surface chemistry of precursors, nucleation and growth of product film on substrate Me Me Me CH4 Ga Me Me Me Me Me H H H Ga Al As Me H As Al As Al As Al As Al As Al As Al As Al As Al As Al As Precursor adsorption on single crystal oriented substrate - lattice matching epitaxy criteria - surface physisorption - chemisorption - surface diffusion - dissociative chemisorption - reaction - desorption Different models for film nucleation and growth - depends whether surface diffusion involved - fixed vs mobile crystal nuclei

49. MOCVD SINGLE SOURCE PRECURSORS • Specially designed MOCVD reactors, hot and cold wall designs, controlled flow of precursors using digital mass flow meters directing precursors to heated single crystal substrate, induction or resistive heater, silicon carbide coated graphite susceptor for mounting substrate • This chemistry creates problems for semiconductor manufacturers wrt safe handling and disposal of toxic waste • Most reactions occur in range 400-1300oC, complications of diffusion at interfaces, disruption of atomically flat epitaxial surfaces/interfaces may occur during deposition • Photolytic processes (photoepitaxy) help to bring the deposition temperatures to more reasonable temperatures

50. Bottom graphite, middle substrate, top HgTe film H2 gas window Hg pool H2/Et2Te Exhaust gases UV illumination PHOTOEPITAXYMaking atomically perfect thin films under milder and more controlled conditionsEt2Te + Hg + H2 (h, 200oC)  HgTe + 2C2H6