DEPOSITION AND COMPOSITION OF POLYMER FILMS IN FLUOROCARBON PLASMAS*

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DEPOSITION AND COMPOSITION OF POLYMER FILMS IN FLUOROCARBON PLASMAS* Kapil Rajaraman and Mark J. Kushner 1406 W. Green St. Urbana, IL 61801 rajaramn@uiuc.edu mjk@uiuc.edu http://uigelz.ece.uiuc.edu November 2004 *Work supported by Semiconductor Research Corporation

AGENDA Fluorocarbon etching resolution of polymer composition. Reaction mechanism. Global simulation of base case (pure C 4 F 8 ). Parameterizations Power Self-Bias M/Ar/O 2 plasmas. (M = C 4 F 8, C 2 F 6 ) Pulsed operation. AVS_02

FLUOROCARBON PLASMA ETCHING The use of low-k dielectric materials for interconnect wiring presents new challenges to the semiconductor industry. Fluorocarbon plasma etching is still the foremost process for obtaining selectivity between dielectrics. Optimization of this process is critical as dielectrics thin and selectivity requirements become extreme. This selectivity is due to the deposition of a polymer layer, which is then consumed by oxidants in the underlying dielectric, leading to an etch. The thickness of this polymer also controls the ion energy hitting the dielectric surface. AVS_03

RESOLUTION OF POLYMER COVERAGE To first order, etch rates are affected by ion energies only by the polymer thickness, and not by the composition of the film. The polymer deposition/sputtering rate, and the rate of reaction of the polymer with the dielectric depend on the composition of the polymer. To this end, a surface model has been developed to resolve the polymer on a mesoscale level. -C-, -CF-, -CF 2 -, and CF 3 - sites are differentiated, and the thickness of the polymer is the sum of the thicknesses of all of the above. AVS_04 Li et al, JVSTA 20 (2002)

SURFACE REACTION MECHANISM: I CF x and C x F y radicals are the precursors to the passivation layer which regulates delivery of precursors and activation energy. Chemisorption of CF x produces a complex at the oxide-polymer interface. Plasma CF x Ion + I*, CF 2 C x F y Ion + CO2 Ion + CO2 Ion +,F SiF3 Low energy ion activation of the complex produces polymer. C x F y Passivation Layer Polymer k E 1 E = k0 c SiO 2 Plasma F CF x SiO 2 C x F y Ion +,F SiF 3 SiOCFy SiF 3 E c = maximum allowable energy k 0 = probability at E c. C x F y Passivation Layer Polymer C x F y radicals adds onto polymer to produce thicker polymer. AVS_05 Si SiF SiF2 SiF3

SURFACE REACTION MECHANISM: II The polymer layer is sputtered by energetic ions Plasma I*, CF 2 CF Ion + Ion + x C x F y CO2 Ion + CO2 Ion +,F SiF3 p(e) = p 0 E E n n r - E - E n th n th C x F y Passivation Layer SiO 2 Polymer SiO 2 C x F y SiOCFy SiF 3 E th = threshold energy E r = reference energy p 0 = probability of sputtering at the reference energy. Plasma C x F y Passivation Layer Si Ion +,F F CF x Polymer SiF SiF2 SiF3 SiF 3 The complex formed at the oxide-polymer interface undergoes ion activated dissociation to form volatile etch products (SiF 3, CO 2 ). AVS_06

SURFACE REACTIONS The fluorination state of C- is resolved (e.g. C-, -C-F, etc.) AVS_07

GLOBAL PLASMA MODEL GLOBAL_KIN is a spatially homogeneous solver which periodically updates the gas and surface species. A preprocessor reads in a 2-D mesh to calculate an effective length scale, and fractional surface areas. AVS_08

REACTOR GEOMETRY The global model is used to efficiently develop surface chemistry reaction mechanisms. (2-D model 5-6 hours, 0-D 20 min) Geometry is based on the ICP reactor used by Oehrlein. 15 Coils Base operating conditions are Pure C 4 F 8 10 mtorr 50 sccm 1400 W ICP power 13.56 MHz Height (cm) 10 5 0 Feed ring 10 5 Substrate Wafer Pump port 0 5 10 Radius (cm) AVS_09

POLYMER THICKNESS AND SiO 2 ETCH RATE The trends followed in etch rates are similar to those found by Oehrlein.* Below a critical thickness (~ 1.5 nm), the ions directly etch the substrate. In these regimes, the thickness of the film is not the main parameter controlling etch rates. * Standaert et al, JVSTA 22 (2004) 100% C 4 F 8, 50 sccm, 1400 W AVS_11

ION-INDUCED DEFLUORINATION Ion-induced defluorination reactions have been proposed to explain etching through thicker (> 3 nm) films.* As a result, the C-C contribution to the film increases with selfbias, due to C-F 2 being defluorinated. 100% C 4 F 8, 50 sccm, 1400 W AVS_12 * Standaert et al, JVSTA 22 (2004)

EFFECT OF POWER: FILM THICKNESS A. The thickness of the film increases with increase in depositing radicals. B. The rate of deposition is then balanced out with ion sputtering C. Formation of volatile CF 4 due to increase in fluorine. AVS_14 100% C 4 F 8, 50 sccm, 10 mtorr

ADDITION OF ARGON: FILM THICKNESS As Ar is added, thinner films are observed due to the reduction in density of depositing radicals and sputtering. At lower self-bias, the Ar + does not affect the sputtering, and the rate of reduction of film thickness is lower. AVS_15 Gas Phase Densities 50 sccm, 1400 W, 10 mtorr

ADDITION OF ARGON: FILM COMPOSITION As Ar is added, the percentage contribution of C-F 3 is reduced, because of increased sputtering by Ar ions. 50 sccm, 1400 W, 10 mtorr AVS_15

ADDITION OF OXYGEN: FILM THICKNESS With an increase in O 2, the depositing radical density falls. O radicals reactively etch the polymer film, reducing thickness. Gas Phase Densities AVS_16 50 sccm, 10 mtorr

ADDITION OF OXYGEN: FILM COMPOSITION Increased functionalization of surface sites is observed, while the contributions of C-Fx are reduced. 50 sccm, 10 mtorr, 200 ev ions AVS_16

COMPARISON WITH C 2 F 6 PLASMA: GAS PHASE In a C 2 F 6 plasma, the branching ratio for CF 3 increases. As a result, the CF 3 content in the film is significantly increased. 100% C 2 F 6, 50 sccm, 10 mtorr 100% C 4 F 8, 50 sccm, 10 mtorr AVS_16

COMPARISON WITH C 2 F 6 PLASMA: FILM PROPERTIES At high ion energies, the -CF 3 is easily sputtered away, causing a sharp reduction in thickness. At lower ion energies, the high density of CF 3 leads to a balance of deposition of CFx and formation of volatile CF 4. 100% C 2 F 6, 50 sccm, 10 mtorr AVS_17

INFLUENCE OF SUBSTRATE TEMPERATURE Surface temperature changes the diffusion rate of surface sites. At low ion energies, most of the sites are activated, and the process can be modeled by each activated site having a lifetime dependent on substrate temperature. AVS_16

MODULATED DISCHARGES PTFE-like ([CF 2 ]n) films have been shown to possess hydrophobic qualities. This makes these films attractive for applications like stain resistant clothes, nonfouling substrates, etc. In the past, CW discharges of tetrafluoroethylene (TFE) have been used to obtain cross-linked amorphous fluorocarbon films. Recently, modulated TFE discharges have been investigated for the formation of super-hydrophobic films which are ribbon-like in structure.* The reaction model developed in the previous study was applied to such discharges. * Cicala et al, Macromolecules (2002) AVS_21

REACTOR GEOMETRY The reactor is the same geometry as in the previous studies. The operating conditions are Pure C 2 F 4 6 sccm 300 mtorr 30 W The period of the pulse is 100 ms, and the duty cycle is varied from 10 to 100%. AVS_22

GAS PHASE DENSITIES DUTY CYCLE As duty cycle (DC) is increased, there is significant modulation of the CF 2 radicals. [F] tracks the pulse, leading to less removal of CF x from the film via volatile products for lower DC. 10% DC 70% DC 100% DC (CW) 6 sccm, 300 mtorr, C 2 F 4 AVS_23

POLYMER THICKNESS AND COMPOSITION For lower DC, the films are thicker, and have a high percentage of C-F 3 compared to experiment.* As DC goes up, the percentage of C-F 2 rises due to the increase in CF 2 density, while the C-F 3 percentage is reduced due to the increase in [F] etching. AVS_24 * Cicala et al, Macromolecules (2002)

INFLUENCE OF SUBSTRATE TEMPERATURE The rate of activation K p increases with duty cycle. At low K p, the sites are de-activated before the radicals can attach. At higher K p, the rates K p and K 2 are the determining factors for polymer thickness. AVS_16

CONCLUDING REMARKS A surface reaction mechanism has been developed to resolve the composition of the fluorocarbon layer deposition. Ion-induced defluorination is important for etching processes for fluorocarbon thicknesses > 3 nm. With addition of Ar, there is a significant reduction in thickness. In a C 2 F 6 /Ar plasma, due to the increased CF 3 radicals, the surface composition is altered to more CF 3. For modulated C 2 F 4 discharges, the surface composition and thickness is a function of the duty cycle. Substrate temperature plays an important part in surface kinetics by affecting the lifetime of activated polymer sites. AVS_25

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