Selective Etching of High-kDielectric HfO2Films over Si in BCl3-Containing Plasmas without rf Biasing

Nakamura, Katsumi; Hamada, Daisuke; Ueda, Yoshikatsu; Eriguchi, Koji; Ono, Ken

doi:10.1143/apex.2.016503

Cited by 12 publications

(9 citation statements)

References 20 publications

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“…The selectivity is as large as 12 at a bias of 32 V, decreasing monotonically to 2 for a bias of 200 V. The decrease in selectivity is largely a consequence of the removal of polymer on the Si by sputtering. 4,12,13 The increase in bias voltage also produces undercutting of the TiN. 4,13 The predicted decrease in selectivity as a function of increasing bias is also in general agreement with experiment, although our decrease in selectivity is more gradual.…”

Section: A Hfo 2 Etch Rate Versus Bias Voltagesupporting

confidence: 84%

Mechanisms for plasma etching of HfO2 gate stacks with Si selectivity and photoresist trimming

Shoeb

Kushner

2009

Journal of Vacuum Science &Amp; Technology A: Vacuum, Surfaces, and Films

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Articles you may be interested inComparison of the effects of downstream H2-and O2-based plasmas on the removal of photoresist, silicon, and silicon nitride Effect of high-frequency variation on the etch characteristics of ArF photoresist and silicon nitride layers in dual frequency superimposed capacitively coupled plasmaa) Plasma enhanced chemical vapor deposition Si-rich silicon oxynitride films for advanced self-aligned contact oxide etching in sub-0.25 μm ultralarge scale integration technology and beyondTo minimize leakage currents resulting from the thinning of the insulator in the gate stack of field effect transistors, high-dielectric constant ͑high-k͒ metal oxides, and HfO 2 in particular, are being implemented as a replacement for SiO 2 . To speed the rate of processing, it is desirable to etch the gate stack ͑e.g., metal gate, antireflection layers, and dielectric͒ in a single process while having selectivity to the underlying Si. Plasma etching using Ar/ BCl 3 / Cl 2 mixtures effectively etches HfO 2 while having good selectivity to Si. In this article, results from integrated reactor and feature scale modeling of gate-stack etching in Ar/ BCl 3 / Cl 2 plasmas, preceded by photoresist trimming in Ar/ O 2 plasmas, are discussed. It was found that BCl n species react with HfO 2 , which under ion impact, form volatile etch products such as B m OCl n and HfCl n . Selectivity to Si is achieved by creating Si-B bonding as a precursor to the deposition of a BCl n polymer which slows the etch rate relative to HfO 2 . The low ion energies required to achieve this selectivity then challenge one to obtain highly anisotropic profiles in the metal gate portion of the stack. Validation was performed with data from literature. The effect of bias voltage and key reactant probabilities on etch rate, selectivity, and profile are discussed.

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Section: A Hfo 2 Etch Rate Versus Bias Voltagesupporting

confidence: 84%

Mechanisms for plasma etching of HfO2 gate stacks with Si selectivity and photoresist trimming

Shoeb

Kushner

2009

Journal of Vacuum Science &Amp; Technology A: Vacuum, Surfaces, and Films

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“…5 shows the discovered gas combination and the resultant etching rates of HfO 2 . As shown in the figure, the etching rates achieved by discovered gas combinations were 100 times higher than that of the traditional gas combination obtained from the literature [16]. We emphasize that only 55 experiments (equivalent to <0.00001% of all possible process/material candidates) were needed to discover the new conditions.…”

Section: With Parameters Listed In Tablementioning

confidence: 84%

“…To evaluate the found materials and processes through our co-optimization procedure, we compared with the results obtained by a traditional gas combination and its process provided by Nakamura et al [16]. They etched a thin film of HfO 2 at 75 deg C using gasses of BCl 3 , Cl 2 , and O 2 (37.5:62.5:5) with a total flow rate of 40 sccm at 5 mTorr and achieved a relatively high etching rate of ∼150 nm/min.…”

Section: B Validation Of Our Methodologymentioning

confidence: 99%

“…To quantitatively compare with the conventional methodology, we estimated the necessary number of experiments, which ) is a traditional one obtained from literature [16], although the process is a little bit different, because high vacuum was not available.…”

Section: With Parameters Listed In Tablementioning

confidence: 99%

“…5. Discovered gas combination and resultant etching rates of HfO 2 using discovered processes at 500 deg C. The condition on the left (BCl 3 + Cl 2 + O 2) is a traditional one obtained from literature[16], although the process is a little bit different, because high vacuum was not available.…”

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confidence: 99%

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Materials Informatics for Process and Material Co-Optimization

Tomita

Sato

Yoshii

et al. 2019

IEEE Trans. Semicond. Manufact.

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In semiconductor manufacturing, fabrication processes and their materials should be properly co-optimized to achieve required processing results within reasonable development duration and acceptable cost. Unfortunately, it is a very time-consuming procedure, because the number of possible combinations of process/material candidates is very large. Here, we develop a methodology for co-optimization of processes and their materials. We successfully constructed a prediction model for dry-etching of high-k materials (R 2 = 0.65). Also, it was proven that considering both the materials and processes is needed for accurate prediction of etching rates. By trying only <0.00001% of all possible process/material candidates with this model and Bayesian optimization, we can find new combinations of gasses and their processes for more than 100 times higher etching rates than that with a traditional gas/process condition. Furthermore, we discussed that accurate prediction can be made by using a combination of the Bayesian optimization with LASSO and materials knowledge from related scientific papers. Future work will focus on validating the versatility of our methodology by applying it to other development items.

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Epitaxial multi-component rare-earth oxide: A high-k material with ultralow mismatch to Si

et al. 2010

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Selective Etching of High-kDielectric HfO₂Films over Si in BCl₃-Containing Plasmas without rf Biasing

Cited by 12 publications

References 20 publications

Mechanisms for plasma etching of HfO2 gate stacks with Si selectivity and photoresist trimming

Mechanisms for plasma etching of HfO2 gate stacks with Si selectivity and photoresist trimming

Materials Informatics for Process and Material Co-Optimization

Epitaxial multi-component rare-earth oxide: A high-k material with ultralow mismatch to Si

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