Mechanistic Advantages of Organotin Molecular EUV Photoresists

Heidkamp, Jonathan; Needham, Craig D.; Wang, H.; Neureuther, Andrew R.; Naulleau, Patrick

doi:10.1021/acsami.1c12411

Cited by 16 publications

(16 citation statements)

References 49 publications

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“…But the affections from counterions could be negligible for the carbon–tin bond energy. Our conclusion is consistent with former reports, 19,22,23 which certify that our calculation is reasonable at this functional and basis set level.…”

Section: Resultssupporting

confidence: 94%

“…The photochemical character and property of the cage have been investigated in many studies. 2,[19][20][21][22][23][24] It is commonly accepted that the cleavage of the carbon-tin bond to generate a tin free radical is the first step in the reaction for solubility switching, and the radical species can be confirmed using mass spectrometry. 19,20 Moreover, the carbon-tin bond in the side and belt region presents different chemical properties.…”

Section: Introductionmentioning

confidence: 99%

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Insight into the evolution upon ionization from tin-oxo cage photoresist and counterions by DFT calculation

Yang,

Ye,

Chen

et al. 2023

New J. Chem.

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Section: Resultssupporting

confidence: 94%

Section: Introductionmentioning

confidence: 99%

Insight into the evolution upon ionization from tin-oxo cage photoresist and counterions by DFT calculation

Yang,

Ye,

Chen

et al. 2023

New J. Chem.

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“…Recent chip fabrication technology is progressing toward the fabrication of 5 nm node or below with the help of extreme ultraviolet lithography (EUVL) . Hence, the era demands single-nanometer technological nodes which further require suitable resist materials that can print features at sub-10 nm regime through a single exposure, although their development is truly challenging. − In recent times, resist compositions comprising inorganic or organometallic species with resolution potential at the single-nanometer regime and high etch resistance capabilities even with thickness below 20 nm have drawn special attention. − For sub-10 nm patterning applications, it is desirable that the film thickness should be less than 20 nm to avoid pattern collapse. , Also, developing an understanding of the mechanistic aspect of polarity switching of inorganic resist during exposure is an important area as it helps in designing new resist platforms with better performance at a single nanometer regime. − Among various types of inorganic resists, some tin-based compositions are being considered to have the potential to meet the current demand. ,,− In reality, some spin-on type tin-based inorganic resist formulations have been proven to have potential for advanced node applications. , Moreover, as per the recent developments, a few inorganic resists have been shown to have true potential for patterning at a single nanometer regime with a very good pattern profile. − However, the number of such materials is truly limited. Herein, we demonstrate the potential of an organotin-based cage-like network (Sn–CT) as an inorganic resist system for sub-10 nm patterning (Figure ).…”

Section: Introductionmentioning

confidence: 99%

“…Herein, we demonstrate the potential of an organotin-based cage-like network (Sn–CT) as an inorganic resist system for sub-10 nm patterning (Figure ). In general, at the developmental phase, the resists for EUVL are often screened initially with electron beam lithography (EBL) and helium ion beam lithography (HIBL) to evaluate the patterning potential. − ,− …”

Section: Introductionmentioning

confidence: 99%

Induced Chemical Networking of Organometallic Tin in a Cyclic Framework for Sub-10 nm Patterning and Interconnect Application

Nandi

Khillare

Kumar

et al. 2023

ACS Appl. Nano Mater.

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Given the need for advanced resist materials in view of fast shrinkage of semiconductor node scaling, this work demonstrates the lithography application of an organotin-based cyclotrimeric species (Sn−CT) as a molecular resist for sub-10 nm patterning using electron beam lithography (EBL) and helium ion beam lithography (HIBL) techniques. While the resist has been successfully used for patterning ∼15 nm line/space features and ∼9 nm discrete line features at a dose of 2.5 mC/cm 2 using EBL, ∼15 nm line/space features were printed on silicon at a dose of 16 μC/cm 2 using HIBL. Moreover, Sn−CT has also been used for patterning complex features at a single nanometer regime such as real-scale device designs at ∼7 nm structure on silicon. A mechanistic study using X-ray photoelectron spectroscopy (XPS) revealed the formation of Sn−O−Sn and Sn−OH networks along with the loss of carbon-based group(s) upon radiation exposure, resulting in the generation of insoluble products in the exposed region, which becomes the basis of polarity switching and hence pattern development. The resist was found to have good etch resistance with respect to silicon. Moreover, Sn−CT has been explored as a good gap-filling material for silicon (Si) front-end devices and interconnects due to its low-κ dielectric (∼1.9) and high diffusion barrier properties.

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“…While organic polymeric chemically amplified resists have been the workhorses for the semiconductor industries over the past several decades, it seems that these resists have reached their resolution limit and may not be suitable for patterning desirable low size nodes to meet the current demand of semiconductor industries. , Also, for patterning well-resolved sub-12 nm features, the resist film thickness is desirable to be less than 20 nm. , This is the point where organic resists suffer as they have weak tolerance to etch conditions at this low thickness. , To address these issues, efforts are being directed to develop interesting resist platforms for low node patterning. Among different types of resists, in recent times, inorganic resists have been reported to be the most promising candidates as they offer sub-12 nm patterns with low film thickness and show good etch resistance under common etch conditions. ,− In this context, tin-based inorganic resists among the several other types have gained considerable attention. ,− However, shrinkage of resist films during exposure and baking conditions has been a serious problem for inorganic resists, and therefore, it is a challenge to address the concerning shrinkage issue. Hence, approaches to mitigate this issue are highly desirable, although quite challenging.…”

Section: Introductionmentioning

confidence: 99%

Macrocycle Network-Aided Nanopatterning of Inorganic Resists on Silicon

Nandi

Khillare

Moinuddin

et al. 2022

ACS Appl. Nano Mater.

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Inorganic resists have emerged as promising candidates in semiconductor industries to realize sub-10 nm node technology. However, controlling vertical shrinkage of resist films during the pattern development process, particularly for ultralow thin film applications, is among the highly pressing limitations of inorganic resists along with pattern roughness and poor resist shelf-life characteristics. Tin-based clusters and small molecules have been recently introduced as resist materials. They possess a high absorption coefficient and fast solubility transitions under irradiation exposure. As we investigated, n-butylstannoic acid (BTA) showed ∼38% vertical shrinkage when its film was exposed with deep ultraviolet photons (DUV, ∼254 nm) and could pattern features of ∼120 nm. We hypothesized and experimentally validated an approach that provided control on shrinkage issues, along with improving its patterning potential to sub-15 nm regime. In our approach, BTA was embedded into a polyhydroxy organic host matrix composed of noria (water-wheel-like macrocycle) derivatives. The rigid molecular cage structure and photo-inert nature of noria (N-Me) were utilized as the host matrix that apprehended the inorganic resist material within its intermolecular space. Ultrathin films (∼20 nm) were coated on silicon, and various nanofeatures including 10 nm lines, meshlike grids with 10 nm width, complex patterns, and so forth were patterned using electron beam and helium ion beam lithography. Most importantly, we were able to drastically reduce the vertical shrinkage to ∼13% with respect to initial thickness, which substantiates the potential of our hypothesis. We also noticed good shelf-life (6 months), good etch resistance, and low line edge roughness (LER)/line width roughness (LWR) for the developed resist composition.

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Mechanistic Advantages of Organotin Molecular EUV Photoresists

Cited by 16 publications

References 49 publications

Insight into the evolution upon ionization from tin-oxo cage photoresist and counterions by DFT calculation

Insight into the evolution upon ionization from tin-oxo cage photoresist and counterions by DFT calculation

Induced Chemical Networking of Organometallic Tin in a Cyclic Framework for Sub-10 nm Patterning and Interconnect Application

Macrocycle Network-Aided Nanopatterning of Inorganic Resists on Silicon

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