Dopant loss of ultrashallow junction by wet chemical cleaning

Buh, G. H.; Park, T.; Yon, G. H.; Kim, S. B.; Jee, Young A.; Hong, Seoung‐Jin; Ryoo, C.W.; Yoo, J.; Lee, J. W.; Jun, C. S.; Shin, Youngsoo; Chung, U‐In; Moon, Jung-Hyung

doi:10.1116/1.2132323

Cited by 5 publications

(3 citation statements)

References 8 publications

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“…This makes PPS not a blanket solution for all PR stripping applications. Its reduced plasma exposure suggests application of PPS for PR stripping after sensitive implants like ultra shallow junctions [5].…”

Section: Discussionmentioning

confidence: 99%

Shortening of Plasma Strip Process Resulting in Better Removal of Photo Resist after High Dose Implantation

Захаров

Lenski

Metzger

et al. 2009

SSP

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A layer of hardened material (crust) forms on the surface of photo resist (PR) during the implantation. This crust can be described as highly cross-linked polymer [1, 2]. Its thickness and composition depends on the type of PR, implant species, energy, dose, temperature during implantation and other factors. The crust is very resistant against chemical attack. Its chemical resistance tends to increase with the continuous shrink of technology nodes as implant doses increase. Moreover, even small residues of PR, left after cleaning, become more critical with shrinking device geometry. The usual process sequence for stripping a PR after high dose implantation (HDI) is a plasma strip (PS) followed by a wet clean. The drawback of plasma ashing is increased substrate loss and dopant bleach [3]. Plasma strip or plasma ash stand in this paper for the approach of complete PR consumption in the plasma process. Wet stripping alone often is not sufficient for stripping PR after implant doses of ≥ 1x1015 ions/cm2.

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Section: Discussionmentioning

confidence: 99%

Shortening of Plasma Strip Process Resulting in Better Removal of Photo Resist after High Dose Implantation

Захаров

Lenski

Metzger

et al. 2009

SSP

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“…Although there is some interest in wet-only processing, the challenges related to resist and residue removal prevent this approach in the main stream and dry-only or dry-wet combinations are typically employed. Limitations are placed on plasma chemistries, driven by the need for near-zero substrate and dopant loss [1]. Continuing high-dose (>2E15), but shallow implants of multiple species, combine to make dry photoresist strip a significant challenge [2].…”

Section: Introductionmentioning

confidence: 99%

Characterization of Oxidation Induced Substrate Loss

Cunnane¹,

Moore²,

Waldfried

et al. 2010

ECS Trans.

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Post implant resist strip for 45 nm and below poses challenges with regard to Si substrate loss due to oxidation and surface modification. In particular, the process to form Ultra Shallow Junctions (USJ) with high-dose implant (HDI) creates a carbonized, cross-linked crust on the surface of the resist. Removal of the implanted resist typically requires temperature-controlled and chemically aggressive approaches which can lead to excessive substrate damage. In order to ensure the desired device characteristics, this damage must be kept to a minimum, and the required optimization is dependent on highly sensitive metrology techniques. This paper reports on wafer mass loss as a direct linear measurement technique to quantify substrate loss.

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“…There are several reports on dopant loss affected by the cleaning. Previous studies showed that dopant loss is occurred by wet etching in the case of ultrashallow junction (1,2,3). Using of SC1 multiple times etches the polysilicon containing dopant.…”

Section: Introductionmentioning

confidence: 99%

Effect of Ashing, Strip and Annealing Process on the Dopant Concentration of Silicon

Lee

Park²,

Kang³

et al. 2007

ECS Trans.

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In this study, we investigated the change of dopant concentration during ashing, strip and annealing process. Combined HF-based strip and annealing process causes the loss of dopants, phosphorous and arsenic, while the ashing process does not affect the dopant loss. This is because HF cleaning removes the silicon oxide acting as the capping layer of dopant evaporation and out-diffusion in annealing process.

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Dopant loss of ultrashallow junction by wet chemical cleaning

Cited by 5 publications

References 8 publications

Shortening of Plasma Strip Process Resulting in Better Removal of Photo Resist after High Dose Implantation

Shortening of Plasma Strip Process Resulting in Better Removal of Photo Resist after High Dose Implantation

Characterization of Oxidation Induced Substrate Loss

Effect of Ashing, Strip and Annealing Process on the Dopant Concentration of Silicon

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