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Plasma-only etching strategy for PS-b-PMMA nanostructures
P.Bézard, G. Cunge, O. Joubert, E. Latu-Romain – LTM, CNRS X. Chevalier – Arkema R. Tiron, A. Gharbi, M. Argoud – CEA LETI Philippe Bézard- PS-b-PMMA dry etching
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Block copolymer (BCP) as an alternative lithography
Courtesy X. Chevalier & A. Gharbi PS-b-PMMA self assembly in vertical PMMA cylinders configuration (1) Surface neutralization with brush (PS-r-PMMA) Spin coating of brush Bake of Brush layer Washing of brush layer (2) Self assembly of BCP (PS-b-PMMA) of BCP Bake for Self assembly Acetic acid bath Application: Contact shrink Main issue: CD control X.Chevalier et al., Proc of SPIE 2011, 7970 Philippe Bézard- PS-b-PMMA dry etching 2 M. Darnon - SPIE San Francisco M. Darnon - SPIE San Francisco 2
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Philippe Bézard- PS-b-PMMA dry etching
Pattern transfer PMMA residues etching Brush etching acetic acid treatment Si (100) Hard mask PS-r-PMMA Si (100) Hard mask PS-r-PMMA Si (100) Hard mask PS-r-PMMA Si (100) Hard mask Plasma-only etching Si (100) Si etching Hard mask etching Specific plasma etching steps must be developped to ensure nano-holes etching with a good CD control. Philippe Bézard- PS-b-PMMA dry etching 3
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Philippe Bézard- PS-b-PMMA dry etching
Equipment/ Experiment description Mass Spectrometer / Ion flux probe LED for UVAS (Cl2) D2 lamp for VUVAS (HBr, Br2) Quasi in-situ XPS We are using an industrial ICP reactor from AMAT designed to etch 300 mm wafers but modified to host plasma and surface diagnostics. System equipped with pulsed RF generators / Operation at constant peak power. Typical pulsing frequency: 1-10 kHz Philippe Bézard- PS-b-PMMA dry etching
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Philippe Bézard- PS-b-PMMA dry etching
PMMA removal Why developing an « all-dry » strategy? Philippe Bézard- PS-b-PMMA dry etching
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Philippe Bézard- PS-b-PMMA dry etching
PS mask fabrication: acid acetic treatment AFM Before acetic ac. After acetic ac. phase Covered by thin PS films or still partly filled with PMMA, many holes are not entirely opened. SEM top-view of PS-b-PMMA after acetic acid Si Acid acetic rinsing PMMA PS brush The acetic acid treatment does not eliminate the PMMA but rather pushes it to the surface can plasma etching be used to open the holes? Philippe Bézard- PS-b-PMMA dry etching
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Philippe Bézard- PS-b-PMMA dry etching
Impact of N2/H2 plasma on PMMA H2 based plasmas are widely used to etch PMMA good initial chemistry MIR of C=O bond XPS C1s H-C-O C=O PMMA H2 plasmas reduce C=O and C-O bonds and hydrogenate carbone dangling bonds PMMA etching rate is driven by the flux of H atoms Philippe Bézard- PS-b-PMMA dry etching
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Philippe Bézard- PS-b-PMMA dry etching
Impact of N2/H2 plasma on PS MIR of C-H bonds PS is etched slowly compared to PMMA (typical selectivity 5-8). However, PS aromatic cycles are destroyed by the H2 plasmas PS etching resistance is lowered after the plasma etching of PMMA residues. Example of highly damaged PS after transfer High PMMA/PS selectivity is expected at low energy / high H atom flux N2/H2 plasma at high ICP power, low bias power, high pressure Philippe Bézard- PS-b-PMMA dry etching
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PMMA removal: optimizing H2 plasma after acetic acid
Plasma conditions adjusted to etch PMMA selectively towards PS low ion energy After low ion energy plasma CD dispersion > 3 nm ! CDbias = +2 nm (PS hole diameter increase) Philippe Bézard- PS-b-PMMA dry etching
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Philippe Bézard- PS-b-PMMA dry etching
PMMA removal: acetic acid - microloading Amount of PMMA residues is fluctuating from hole to hole The lateral etch rate of a PS hole filled by PMMA is delayed / hole without PMMA loss of CD control (CD microloading) H Acetic acid + plasma do not allow a satisfying CD control what about plasma alone ? Philippe Bézard- PS-b-PMMA dry etching
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Philippe Bézard- PS-b-PMMA dry etching
PMMA removal: “All-dry” strategy – conditions PS vertical etch rate must be minimized: Low ion energy Low ion energy High ion energy H atoms are responsible for PMMA etching High source power (ICP) High pressure N2 addition Low radical flux High radical flux An « all-dry » process needs low energy ions with high atomic hydrogen flux. Philippe Bézard- PS-b-PMMA dry etching
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Philippe Bézard- PS-b-PMMA dry etching
PMMA removal: “All-dry” strategy – Results SEM cross section of PS-b-PMMA after « all-dry » removal SEM top view of PS-b-PMMA after « all-dry » removal ~35 nm remaining of initial ~40nm-thick PS mask (selectivity > 8) CD dispersion ~2.5nm (1σ): already too high Philippe Bézard- PS-b-PMMA dry etching
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Philippe Bézard- PS-b-PMMA dry etching
PMMA removal: “All-dry” strategy – Defects and CD dispersion SEM top view of PS-b-PMMA after « all-dry » removal CD dispersion due to defects in the BCP organisation + initial CD dispersion is enhanced by plasma The «all-dry » opening of the PS mask is promising if lower defect density in BCP can be achieved Philippe Bézard- PS-b-PMMA dry etching
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Brush opening after « all-dry » Philippe Bézard- PS-b-PMMA dry etching
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Philippe Bézard- PS-b-PMMA dry etching
Brush opening : the issue of charging effects Ion + e - + Due to differential charging of the features, the ion energy and flux are reduced etch stop issues This effect becomes stronger when Aspect Ratio increases Solution: increase ion energy and/or prevent charging by pulsing the plasma Philippe Bézard- PS-b-PMMA dry etching
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Philippe Bézard- PS-b-PMMA dry etching
Example: brush opening after acetic acid CW plasma with bias (100 eV ions energy) Synchonized pulsed plasma: Ion energy > 100 eV and no charging effects CW plasma without bias (15 eV ions energy) Energetic ion bombardment is mandatory to open the ultrathin brush layer in H2 plasmas Can we use same synchronized pulsed plasma to open brush after the « all dry » strategy ? Philippe Bézard- PS-b-PMMA dry etching
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Philippe Bézard- PS-b-PMMA dry etching
Brush opening after “all-dry” development SEM cross section after « all-dry » development and a H2/N2 synchronously pulsed with high bias power - optimised Brush is not opened and PS mask is considerably damaged !!! need for an alternative plasma chemistry to open the brush with fragile PS mask Philippe Bézard- PS-b-PMMA dry etching
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Philippe Bézard- PS-b-PMMA dry etching
Brush opening after “all-dry” development– CF4? CF4 creates a thin fluorocarbon layer on top of PS: XPS doesn’t detect any C-O (due to PMMA) after brush opening step XPS study of PS after brush opening step SEM cross section after brush opening step SEM top view of PS after brush opening step Etching is controlled by ions -> operations at high source power low pressure (1000Ws 5mT) to maximize the ion flux. CF4 does etch brush layer but leads to striations Philippe Bézard- PS-b-PMMA dry etching
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Philippe Bézard- PS-b-PMMA dry etching
Brush opening after “all-dry” development – Avoid striations Reducing Ion energy SEM observations after brush opening step SEM observations after brush opening step Brush layer can be opened with CF4 CW ICP plasma with lower bias power Philippe Bézard- PS-b-PMMA dry etching
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Philippe Bézard- PS-b-PMMA dry etching
Brush opening after “all-dry” PMMA removal – Results SEM cross section of PS-b-PMMA after brush opening step SEM top view of marked Silicon after brush opening Silicon is marked as proof of efficient brush opening for each hole (PS is stripped with O2 plasma before observation). >30nm copolymer mask remaining (due to CFx deposition) Striations are not transfered into Silicon Delayed etching for some holes/ loss of CD control. Philippe Bézard- PS-b-PMMA dry etching
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Philippe Bézard- PS-b-PMMA dry etching
PS in PMMA cylinders? After plasma treatment, PS has been thinned down to <10nm thickness PS instead of PMMA. PMMA cylinder didn’t organise well here Some « PMMA cylinders » are in fact mostly PS! Since H2/N2 plasma etches PS very slowly, there is a delay in the etching of those defects, leading to partial transfer in the underlayer and CD control loss. Philippe Bézard- PS-b-PMMA dry etching
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Philippe Bézard- PS-b-PMMA dry etching
Conclusions (1/2) Low ion energy High pressure High source power H2 N2 chemistry 200 sccm H2 10 sccm N2 40mTorr 1200Ws 0Wb CW 20sec PROCESS WORKS WELL BUT ENHANCES BCP DEFECTS! Philippe Bézard- PS-b-PMMA dry etching
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DEFECTS HAVE TO BE CONTROLLED FOR AN ALL DRY DEVELOPMENT
Conclusions (2/2) Low/moderate ion energy Low pressure (5-10mT) High source power CF4 chemistry 70 sccm CF4 5mTorr 1000Ws 50Wb CW 10sec BUT: partial transfer due to PS in PMMA cylinders. BRUSH OPENED WITH NO STRIATION IN UNDERLAYER DEFECTS HAVE TO BE CONTROLLED FOR AN ALL DRY DEVELOPMENT Philippe Bézard- PS-b-PMMA dry etching
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Philippe Bézard- PS-b-PMMA dry etching
Thank you for your attention! This work has been partially supported by the LabEx Minos ANR-10-LABX-55-01 Philippe Bézard- PS-b-PMMA dry etching
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