EUV-induced hydrogen plasma: pulsed mode operation and confinement in scanner

Kerkhof, Mark van de; Yakunin, A. M.; Astakhov, Dmitry; Kampen, M. van; Horst, Ruud van der; Banine, VY Vadim

doi:10.1117/1.jmm.20.3.033801

Cited by 16 publications

(18 citation statements)

References 57 publications

(113 reference statements)

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“…For the CNT pellicle the concept of film thickness is less meaningful and it becomes more appropriate to specify the film in terms of carbon density (expressed in 'TFU' (Thin Film Unit, or 10 15 C-atoms per cm 2 ). The pellicle is irradiated by EUV and around the pellicle an EUV-induced hydrogen plasma is formed; so mechanical, thermal, chemical and radiation stability need to be evaluated under these conditions 16 . These considerations favor metal silicides for today's source powers of up to 400 W, and this is the baseline pellicle material used today 17 .…”

Section: Other Considerationsmentioning

confidence: 99%

EUV pellicle scanner integration for N2 nodes and beyond

Kerkhof¹,

Klein

Seoane

et al. 2023

Optical and EUV Nanolithography XXXVI

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EUV lithography has been adopted worldwide for High-Volume Manufacturing (HVM) of sub-10nm node semiconductors. To support HVM, EUV pellicles were introduced by ASML in 2016. More recently, several novel pellicle materials have been developed to offer higher transmission and support higher source powers. The current focus is on two classes of pellicles to support the upcoming NXE:3800 and the associated N2 node, and beyond: Si-based composites and CNT-based pellicles. In this paper, we will give an overview of scanner integration results of current EUV pellicles, both Si-based composites and CNT-based pellicles. This overview will cover high-level aspects of transmission, imaging, robustness and lifetime; as well as underlying contributors such as EUV-uniformity, EUV-reflectivity, flare and DUV-reflectivity. Reviewing achieved performance will illustrate the suitability of these materials to support advanced nodes in production. Additionally, the anticipated future performance of EUV pellicles when used with increasing EUV source powers and high-NA scanners will be provided.

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Section: Other Considerationsmentioning

confidence: 99%

EUV pellicle scanner integration for N2 nodes and beyond

Kerkhof¹,

Klein

Seoane

et al. 2023

Optical and EUV Nanolithography XXXVI

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“…An additional pristine sample was kept aside to be used as a reference. In a EUV scanner operation, the mask is exposed in a hydrogen environment to maintain self-cleaning conditions for the sensitive EUV mirrors [13]. To test its stability, Ta-Co alloy samples were exposed to hydrogen radicals for 24 hours.…”

Section: Figure 2 Predicted Stable Ta-co Alloys Using Phase Diagram A...mentioning

confidence: 99%

Evaluation of Ta-Co alloys as novel high-k EUV mask absorber

Thakare¹,

Wu²,

Opsomer

et al. 2022

Optical and EUV Nanolithography XXXV

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An alternate mask absorber is a generally applicable approach as a mitigation strategy for Mask 3-D effects (M3D) observed in EUV lithography. It is also an efficient solution in a production-worthy environment compared to multilayer modification or Source Mask Optimization (SMO) techniques. Absorbers with a high EUV extinction coefficient k allow for lower Best Focus Variation (BFV) through pitch and reduced Telecentricity Errors (TCE). This study evaluates Ta-Co alloys as potential high-k mask absorbers. It includes an experimental study of film morphology, surface composition, and stability of Ta-Co alloys as well as a theoretical investigation of the imaging performance. The optical constants were determined from EUV angle-dependent reflectivity measurements for three selected compositions, viz. TaCo, Ta2Co, and TaCo3. The Ta-Co alloys exhibit a higher EUV extinction coefficient k compared to the currently used TaBN absorber. TaCo and Ta2Co demonstrated smooth surfaces, were stable in a hydrogen environment, and in mask cleaning solutions. These qualified compositions of Ta-Co alloys were selected for aerial image simulations and compared with a TaBN absorber. The optimized absorber thickness for Ta-Co alloy absorbers is based upon NILS enhancement, Threshold to Size (TtS) and balancing of diffraction order amplitudes. A 10 nm alternate line-space pattern with a pitch of 20 nm and 14 nm square contact holes with a pitch of 28 nm were considered for the simulation study using High NA 0.55 EUV lithography process settings. The through pitch imaging performance was evaluated using NILS, TCE and BFV as metrics. Ta-Co alloys allow for a reduction in M3D effects at smaller absorber thickness compared to a 60 nm TaBN absorber.

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“…The interactions between the charges and neutral atoms determine the dynamics of the plasma, including its temperature, density, and spectra [8][9][10][11][12][13]. In the commercial EUV lithography scanner [14][15][16][17], the EUV-induced hydrogen plasma needs to be investigated to understand its effect on the reliability and yield of the Si chips [18,19].…”

Section: Introductionmentioning

confidence: 99%

A study of hydrogen plasma-induced charging effect in EUV lithography systems

2023

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In the extreme ultraviolet lithography system, EUV-induced hydrogen plasma charging effect is observed by in situ embedded micro-detector array. The 4k-pixel on-wafer array can detect and store the distributions of H2 plasma in each in-pixel floating gate for non-destructive off-line read. The local uniformity of H2 plasma intensity extracted by the threshold voltages on an array and its distributions across a wafer by the average bit cell current of MDAs provide insights into the detailed conditions inside advanced EUV lithography chambers.

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EUV-induced hydrogen plasma: pulsed mode operation and confinement in scanner

Cited by 16 publications

References 57 publications

EUV pellicle scanner integration for N2 nodes and beyond

EUV pellicle scanner integration for N2 nodes and beyond

Evaluation of Ta-Co alloys as novel high-k EUV mask absorber

A study of hydrogen plasma-induced charging effect in EUV lithography systems

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