Fys4310 doping

FYS4310 DOPING Fys4310 doping DIFFUSION

phenomenological Ficks laws Intrinsic diffusion - extrinsic diffusion Solutions of Fick’s laws ’predeposition’, ’drive-in’ electrical field enhancement Concentration dependant diffusion ( As) Diffusion program I atomistic Si-Self diffusion Vacancy diffusion Charged vacancy model Impurity diffusion Vacancy -dopant interactions

Math & practical Numerical solutions of Ficks laws Computer packages Materials science Diffusion program II High concentration effects Pairs, quartets, defects experimental./ref.reading Measurements of diffusion SIMS, Radio tracer, RBS Differential Hall, SRM, CV, stain etch Bolzman Matano method Diffusion equipment, furnaces, boilers, sources

Examples B in Si As in Si P in Si, high concentration Emitter push Zn in GaAs Diffusion program III etc. These points/topics are woven into other headings High doping effects Solubility, Metastable doping Dopant interactions Defects introduced in diffusion doping, Stresses Defining doping areas, masking, Diffusion in SiO2 vs Si Diffusion of metallic impurities

Ficks laws Defines D phonomenologic Ficks 1st lov Diffusion phenomenological J: flux Continuity equation Ficks 2nd law

x x+dx Jin Jout qed J: flux C: concentration t : time Continuity equation should be well known One dimentional Derivation

Random walk Brownian motion Microscopic lattice modelling Diffusion in general microscopically Phenomenologically Ficks 1. og 2. Comparison gives D a: jump distance v:trial rate Z: geometry Ea= Em+Ev :migr.+vac 6: std for cubic

Boundary cond. - ”predeposition” from gas or solid source Analytic solution diffusion equation 1 C(z,0) =0 C(0,t)=Cs C(∞,t)=0 Solution Total amount

Boundary cond. - ”drive - in” Analytic solution diffusion equation 2 don surface predep no flux Dtpre<<Dtinndr Drive in Solution

INTRINSIC Diffusion Pre deposition Drive in Curve shape for idealized case Fig. 3-7 a b, Cambell

Elec field Electric field assisted diffusion - doping Flux

exhange 2 1 2 1 Atomic diffusion -self diffusion vacancy- diffusion V V Interstitial diffusion Usually requires little energy Interstitials can knock out regular atoms - interstitialcy

Si Int O, Fe, Cu, Ni, Zn Sub P, B, As, Al, Ga, Sb, Ge Atomic diffusion Interstitials can move from on interstitial position to the next- Interstitial diff. Usually requires little energy interstitial substitutional Substitutionals may move in various ways exchange 2 1 2 1 V V vacancy- diffusion

Various diffusion mechanisms for doping atoms ’Interstitialcy’ Fig 3.5 Atomic diffusion B and P may diffuse this way -also depends whether have Si(I) or V ’kick out’ Fig 3.6 Frank-Turnbull

Si self diffusion - guess vacancy diffusion Can be measured by labeling the Si atoms by radioactive Si* Atomic diffusion Assume DSi can be measured Finds: P conc.. DSi dependant on the doping density Why?

Schematic Atomic diffusion Vacancy diffusion Vacancy concentration depends on doping concentration Probability for jump via vacancy depends on vacancy concentration i.e. Diffusivity D depends on doping concentration Diy :diffusivity of Si by vac. w. charge y in intrinsic case

For dopant atoms n=n(C) n: electron concentration p=p(C) C:doping concentration i.e. atomistic diffusion consequences D=D(C) and C=C(x) ie EXTRINSIC DIFFUSJON Diffusion equation Must be solved numerically

How? Assume D can be measured, From Diffusion, atomistic model consequences With measurements of D vs. n you can determine D*, D-, D= Fit to y: charge state *,-,+,= Measured cm2/s eV

Fig 3.8 B high conc. Fig 3.9 As high conc. Diffusion, typical profiles B acceptor B- V- As donor, As+ As+ V- , As+ V+ n>>ni : h=2,

Dislocations Band gap shrinkage Diffusion, High doping effects Cluster formation Segregation

Dislocations f.example B doping Stress-no disloc. Diffusion, High doping effects Disadvantage for stress in membranes for MEMS, ie for pressure sensors Elastic energy released by creating a dislocation Stress in heavy B doping of Si tried compensated by adding Ge

Band-gap narrowing Diffusion, High doping effects Ed e-e int.act.. Donor donor interaction. High doping conc. Very low doping conc. Eg varies ni varies [V] varies.

Band-gap narrowing, qualitatively? Diffusion, High doping effects For 1017 ≤ N ≤ 3·1017 cm-3 .∆Egel ~ 3.5·10-8·Nd1/3 (eV) (Nd in cm-3) Van Overstraeten, R. J. and R. P. Mertens, Solid State Electron. 30, 11 (1987) 1077- 1087.

Cluster formation solubility ln(n) Diffusion, High doping effects Complexes/clusters Maybe precursor to segregation ln(C) Si VAs2-complex V=+2As+=VAs2 Various reactions As One model V kVl+mAs++ye=(VKAsm)(m+lk-y) As Si Complex neutral, el.neg, [V]>>[2V] Gives k=1 and m=1,2,4

Cluster formation solubility ln(n) Diffusion, High doping effects ln(C) V2As2-complex kVl+mAs++ye=(VKAsm)(m+lk-y) V How to find out about cluster models.? 2V-+2As+=V2As2 Én model As Si As V

Segregation Requires nucleation of new phase, i.e. the concentration must correspond to super saturation before precipitation occurs, The density of precipitates depends upon nucleation rate and upon diffusion. It means measurements of solubility can require patience particularly at low temperatures. Diffusion, High doping effects surface ∆G* ∆G r* r volume bulk

Solving the diffusion equations (by simulations) General methods Finite differencing Finite element Diffusion, Numerical calculation considerations Monte Carlo Spectral Variational

Representations of time and space differentials Forward Euler differentiation, Accuracy to 1ste order ∆t a Diffusion, numeric ’finite difference’ b Combining a and b giver representation FTCS Forward Time Centered Space example. diff.eq. NB Unstable* FTCS FTCS explicit so Ujn+1 can be calculated for each j from known points Stability achieved by Stability just as much art as science

F: Flux C: Flux Leapfrog Here accuracy 2nd order in ∆t Diffusion, numeric ’finite difference’ Diffusion equation in simple case FTCS: (explicitly) Stab. criteria: Often stability means many time steps

(explicit) FTCS: Diffusion, numeric ’finite difference’ (implicit) Backward time Combining the two =Crank-Nicholson method Allows large time-steps (explicit) (implicit) Crank-Nicholson

Diffusion equation w. Crank -Nicholsen collect left and right ie

A and B tridiagonal i.e. Diffusion equation w Crank -Nicholsen Boundary cond , j=1 i.e. surface R=1 reflection R=0 trapping R=0.5 segregation coeff ie. j=2 ie.

known unknown Diffusion equation w Crank -Nicholsen = Can readily be solved when D only a function of x and t but not of C. If D=D(C) i.e. we have a nonlinear set of equations

schematic Diffusion, numeric examples Implanted profile Vacancy creation on surface Vacancy annihilation in ion-damaged region Surface segregation As i Si Implanted profile Vacancy creation on surface Vacancy annihilation in ion-damaged region Ge i Si

If D=D(C) ie we have a nonlinear system of equations known unknown But assume as 1st approx. then calculate Cn+1, and put in A for next it. Diffusion, numeric general vector matrix Initial conditions This equation is solved for example by Newton’s method in the general case

’curve-fitting' models / physical models All processing stages/ all thermal/ just diffusion Integrated, -masks, device, system-simulation (icecream silvaco) Diffusion, numeric SOFTWARE PACKAGES 1D, 2D, 3D Required for ULSI SUPREM III (1D), SUPREM IV(2D) [Stanford] TSUPREM4, SSUPREM4[Silvaco], ATHENA[Silvaco] ICECREAM, DIOS, STORM Floops, Foods, ACES,

In many situations we have C=C(x), We can find D(C) by measuring C(x) at different T Can find D*, D+, D-, D= from the dependency D(n) Diffusion, Measurements of diffusion profiles, D(C) So measurement of C, and n el. P is needed Example P in simple case Methods for C Methods for n SIMS, TOFSIMS Neutron activation RBS, ESCA, EDAX IR abs. Spreading Resistance Differential Hall i.e.. +strip Capacitance, C-V + strip SCM, SRM

Diffusion, Measurement of diffusion, process surveillance Top view sphere sphere

’Four-point probe’ Diffusion, Measurement of diffusion, process surveillance Measures so-called sheet resistance Can find resistivity if the depth distribution of n and µ is found Mostly for process surveillance-reproducibility tests

3 2 More common geometry Diffusion, Measurements of diffusion profiles 4 4 3 1 1 2 van der Peuw method

Hall measurements Diffusion, Measurement of electric profile Measurement-procedure Measure rs, RHS gives µH Strip a layer Repeat to d Calc individual n and µ

Diffusjon, Measurement of electric profile Schottky p-n junction electrolyte

Scanning Probe Microscopy SSRM SCM Diffusion, Measurement of diffusion profile

Diffusion, Measurement of diffusion profile

Spreading resistance measurements Diffusion, Measurement of diffusion profile needle beveling

Scanning capacitance microscopy Diffusion, Measurement of diffusion profile Electric

Scanning capacitance microscopy Diffusion, Measurement of diffusion profile Elektriske

SIMS, Diffusion, Measurement of diffusion profile

Fys4310 doping

Fys4310 doping

Presentation Transcript

Sports Doping

Doping

DOPING

DOPING

Blood Doping

DOPING

doping stopped

Nanowire Doping via Monolayer Doping

 (doping density)