Interfacial effects on sensitization of chemically amplified extreme ultraviolet resists

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The suppression of stochastically generated bridges is an important issue in the chemically amplified resist process for extreme ultraviolet (EUV) lithography. The additional supply of secondary electrons from an underlayer may be required for the suppression of bridging. In this study, the secondary electron dynamics in a resist-underlayer system was calculated assuming line-and-space resist patterns to assess the effects of the underlayer absorption coefficient α u on the bridging risk R b. The bridging risk decreased with increasing underlayer absorption coefficient. In particular, the effect of the underlayer absorption coefficient on the bridging risk dlnR b/dα u for α u>6 μm-1 was larger than that for α u<6 μm-1. However, the vertical profile of the protected unit distribution was significantly degraded owing to the excessive supply of secondary electrons for α u>8 μm-1. α u of 6-8 μm-1 is considered to be the target value for suppressing the bridging risk when the resist absorption coefficient was 4 μm-1.

Section: Simulation Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Effects of underlayer absorption coefficient on bridging risk in chemically amplified resist process for extreme ultraviolet lithography

Kozawa

2023

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“…21) From these viewpoints, the suppression of stochastic defects at the interfaces has been investigated. However, the short-range backexposure effects of low-energy secondary electrons [22][23][24][25] should be taken into account to control the vertical profiles of resist patterns in addition to the factors described previously. In this study, the sensitization and reaction processes induced in chemically amplified EUV resists were calculated for eight combinations of boundary conditions using a Monte Carlo method to estimate the dependence of defect risks 26) on the conditions of resist interfaces.…”

Section: Introductionmentioning

confidence: 99%

“…Figure 1 shows schematics of the assumed boundary conditions for low-energy secondary electrons. 23) BC VR and BC RU represent the boundary conditions at the resist interfaces with vacuum and an underlayer, respectively. A long arrow and a pair of short arrows indicate the total transmission and the total reflection of low-energy secondary electrons at the interface, respectively.…”

Section: Introductionmentioning

confidence: 99%

Defect risks at interfaces of chemically amplified resists in extreme ultraviolet lithography process

Kozawa

2023

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In extreme ultraviolet (EUV) lithography, stochastically generated defects (stochastic defects) are a significant issue. In this study, the formation of the latent images of line-and-space resist patterns was simulated to assess the dependence of defect risks on the conditions of resist interfaces. The protected unit distribution was calculated on the basis of the sensitization and reaction mechanisms of chemically amplified EUV resists using a Monte Carlo method. The pinching and bridging risks were calculated to be 7.4×10-3-2.0×10-2 and 1.5×10-3-2.6×10-1, respectively, depending on the boundary conditions of low-energy secondary electrons at the interfaces. Using the obtained defect risks, we roughly estimated that the impacts of interfacial effects on pinching and bridging probabilities for low-energy secondary electrons were more than one order of magnitude and more than six orders of magnitude, respectively. Controlling the low-energy electrons at the interfaces is important for the suppression of stochastic defects.

“…5,6) In the EUV resist process, we do not generally consider the reflection of EUV photons at the substrate, because the refractive index of typical substrates such as Si is close to 1.0 and similar to the refractive index of the resist unlike in the case of deep UV and vacuum UV. In the EUV resist process, we should be concerned about the secondary electrons generated in the substrate, 7,8) similarly to the electron beam (EB) resist process, [9][10][11][12] although not only secondary electrons but also primary electrons are included in the EB resist process. The span of the effect of electrons generated in the substrate is different by four orders of magnitude between EB and EUV because of their energy difference.…”

Section: Introductionmentioning

confidence: 99%

Shielding effect of underlayer against secondary electrons generated in substrate in extreme ultraviolet lithography

Kozawa

2023

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The wavelength of a radiation exposure source has been reduced to improve the resolution of lithography in the semiconductor industry. The energy of photons reached the ionizing radiation region when using EUV radiation. Because the energy of EUV photons for lithography is 92.5 eV, the EUV photons can ionize all kinds of atom. In this study, the shielding effect of the underlayer against the secondary electrons generated in the substrates was investigated using the bridging risk as an indicator. Secondary electron dynamics was calculated by a Monte Carlo method assuming the resist-underlayer-substrate system. The physical properties of the underlayer were assumed to be the same as those of the resist layer. The secondary electrons generated in the substrate significantly affected the bridging risk when the underlayer thickness was smaller than approximately 5 nm. The resist process should be designed by considering the secondary electrons generated in the substrate.