The effects of etch chemistry on the etch rates of ArF BARC products

Zhuang, Hong; Abdallah, Dave; Xiang, Zhong; Wu, Huixiang; Shan, Jianhui; Lu, Peng-Han; Neisser, Mark; Karwacki, Eugene J.; Jia, Bing; Badowski, Peter R.

doi:10.1117/12.657128

Cited by 3 publications

(2 citation statements)

References 6 publications

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“…High etch rate organic BARCs were determined to etch 51% to 74% slower in patterned wafers using CF4/O2 gas mixtures. 8 On the other hand, under O2 etch conditions carbon underlayers beneath patterned Si-BARCs are found to etch significantly faster on patterned wafers than on blanket coatings of underlayers. The availability of oxygen radicals is presumably higher since only a portion of the underlayer is exposed to the oxygen radicals and the Si-BARC surface becomes inert once oxide formation is established.…”

Section: Etch Rate Selectivity Comparison Between Patterned and Blankmentioning

confidence: 98%

Etching spin-on trilayer masks

Abdallah

Miyazaki

Hishida

et al. 2008

Advances in Resist Materials and Processing Technology XXV

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Spin-on trilayer materials are increasingly being integrated in high density microfabrication that use high NA ArF lithography due to dwindling photoresist film thicknesses, lower integration cost and reduced complexity compared to analogous CVD stacks. To guide our development in spin-on trilayer materials we have established etch conditions on an ISM etcher for pattern transfer through trilayer hard masks. We report here a range of etch process variables and their impact on after-etch profiles and etch selectivity with AZ trilayer hard mask materials. Trilayer pattern transfer is demonstrated using 1 st and 2 nd minimum stacks with various pattern types. Etch recipes are then applied to blanket coated wafers to make comparisons between etch selectivities derived from patterned and blanket coated wafers.

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Section: Etch Rate Selectivity Comparison Between Patterned and Blankmentioning

confidence: 98%

Etching spin-on trilayer masks

Abdallah

Miyazaki

Hishida

et al. 2008

Advances in Resist Materials and Processing Technology XXV

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“…The very fundamental requirement in plasma etching method adopted in fabricating of an IC pattern is the photoresist remaining margin. The pre-defined photoresist pattern on the metal substrate during photolithography process comes together with the organic backside antirefractive coating film to improve reflection control and light absorption during photolithography (Boumerzoug, 2014;Huang & Weigand, 2008;Zhuang et al, 2006). BARC layer minimizes thin film interference effects by reducing reflected light.…”

Section: Introductionmentioning

confidence: 99%

Assessment Of Cl 2 /CHF 3 Mixture For Plasma Etching Process On Barc And Tin Layer For 0.21 µm Metal Line: Silterra Case Study

al.¹

2021

TURCOMAT

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In wafer fabrication manufacturing, aluminum etching process is a dry plasma etching process used as main process for construction of aluminum (Al) interconnects structures. As customer requirement changed for faster, more reliable and lower cost chips, chip manufacturers have learned to reduce the size of component on a chip in order to achieve those requirements(Ibrahim, Chik, & Hashim, 2016). As the geometry of the chip getting smaller, the width of Al line wiring specification also shrinking. To print the smaller geometry pattern requirement, the thickness in masking process also has to be reduced for better resolution. Such a thinner resist will create a challenge during plasma etching to ensure a minimal resist loss process which required new type of equipment but this research insist to sustain similar equipment. The use of oxide film as a hard mask has been evaluated by other researchers but alternative approach still needed to suit specific requirement of semiconductor factory installation base. This approach does require a process integration change and require a full technology qualification and easily take a lengthy qualification procedures especially when to qualify the existing products. It is worth trying at the situation of no other solution available. The challenge of insufficient margin for the metal line etching process for 0.2 µm width has caused the deformed metal pattern formation. This chemistry study of Cl2/CHF3 as a replacement gas to existing Cl2/O2 to address Organic backside anti refractive coating (OBARC) was evaluated and proven novelty where detail discussed in the following content.

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Novel Fast Etch Rate BARC for ArF Immersion Lithography

Lee

Ahn

Jang

et al. 2018

J. Photopol. Sci. Technol.

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Thickness of 193 immersion photoresist (PR) has been continuously reduced to achieve smaller critical dimension (CD) beyond 1x nm nodes. As a result, faster etch rate (E/R) bottom antireflective coating (BARC) is required to maintain appropriate PR thickness as a mask for pattern transfer and small CD bias after dry etch process of BARC. The etch rate of BARC can be theoretically predicted by Ohnishi Parameter (O.P.); faster etch rate can be obtained by high O.P. with increase in number of hydrophilic heteroatoms, such as nitrogen (N) or oxygen (O). However, poor solubility of high polar resin is the major technical barrier in development of faster E/R BARC. We have designed novel polarity-switchable BARC (PS-BARC) with enhanced solubility via hydrophobic protecting groups while maintaining fast etch rate. In this paper, details of BARC new fast E/R immersion BARC for 193 nm lithography will be discussed.

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The effects of etch chemistry on the etch rates of ArF BARC products

Cited by 3 publications

References 6 publications

Etching spin-on trilayer masks

Etching spin-on trilayer masks

Assessment Of Cl 2 /CHF 3 Mixture For Plasma Etching Process On Barc And Tin Layer For 0.21 µm Metal Line: Silterra Case Study

Novel Fast Etch Rate BARC for ArF Immersion Lithography

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