A compound Kinoform/Fresnel zone plate lens with 15 nm resolution and high efficiency in soft x-ray

Tong, Xujie; Chen, Yifang; Mu, Chengyang; Chen, Qiucheng; Zhang, Xiangzhi; Zeng, Guang; Li, Yuchun; Xu, Zijian; Zhao, Jun; Zhen, Xiangjun; Mao, Chengwen; Lu, Hong‐Liang; Tai, Renzhong

doi:10.1088/1361-6528/acb946

“…The use of the above types of mirrors can help increase the spectral range to the level of ~10% dE E , which, together with the use of the effect of total external reflection instead of diffraction from periodical multilayers, will make it possible to collect the radiation dose required for exposure of X-ray resists several times faster. Combining composite lenses and Fresnel zone plates with a relatively small effective aperture (up to 10 -20 μm ) into a single system opens up the possibility of effectively controlling not only the focusing characteristics of X-ray optics, but also its contrast and resolution [21]. In this case, instead of struggling with aberrations and distortions over a sufficiently large image field, it becomes possible to form the final image projected on a substrate covered with a resist from small fragments with controlled optical characteristics.…”

Section: De Ementioning

confidence: 99%

“…Let us assume that a wave 1 ( ) f x whose spectrum is equal to the Fourier image 1 ( ) F u is incident on the lens, and then find the field distribution ( ) g x in the focal plane of the lens. If we use the frequency response ( ) H u in the Fresnel approximation (21) for the space behind the lens, we can obtain the following formula for the field in the focal plane:…”

Section: Transmission Function Of Lens With Diaphragmmentioning

confidence: 99%

Refractive X-ray optics: towards wavelengths of 13.5 nm and beyond

Demin,

Korneev,

Glagolev

et al. 2023

Preprint

0

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In this work we analyze the possibility of using refractive lenses for X-ray lithography in the wavelength range λ=2-20 nm, where the absorption of radiation in the lens material has a significant impact on the image quality. The general scheme of image formation in projection refractive X-ray optics using a composite objective lens consisting of biconcave elementary lenses is considered. By means of the analytical solution and finite-element simulation model, possible ways to obtain the lens transmission function taking into account the absorption of X-rays were investigated. A lens based on a beryllium (Be) thin film with a complex refractive index n=0.989+0.0015i was chosen to estimate its optical properties at a wavelength of 13.5 nm. Two mechanisms of blurring of the X-ray beam at the lens focus were studied: a mechanism associated with X-ray diffraction and a mechanism based on the absorption of X-ray radiation in the lens material. The possibility of reducing X-ray absorption by switching to diffractive and kinoform lenses is being explored. A method for constructing an image in a diffraction lens with a 4-fold reduction taking into account X-ray absorption is presented. It was shown that to obtain image resolution in the range of 20-40 nm, composite kinoform lenses consisting of a small number (N=3-6) of elementary lenses can be used.

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“…The use of the above types of mirrors can help increase the spectral range to the level of ~10% dE E , which, together with the use of the effect of total external reflection instead of diffraction from periodical multilayers, will make it possible to collect the radiation dose required for exposure of X-ray resists several times faster. Combining composite lenses and Fresnel zone plates with a relatively small effective aperture (up to 10 -20 μm ) into a single system opens up the possibility of effectively controlling not only the focusing characteristics of X-ray optics, but also its contrast and resolution [21]. In this case, instead of struggling with aberrations and distortions over a sufficiently large image field, it becomes possible to form the final image projected on a substrate covered with a resist from small fragments with controlled optical characteristics.…”

Section: De Ementioning

confidence: 99%

“…Let us assume that a wave 1 ( ) f x whose spectrum is equal to the Fourier image 1 ( ) F u is incident on the lens, and then find the field distribution ( ) g x in the focal plane of the lens. If we use the frequency response ( ) H u in the Fresnel approximation (21) for the space behind the lens, we can obtain the following formula for the field in the focal plane:…”

Section: Transmission Function Of Lens With Diaphragmmentioning

confidence: 99%

Refractive X-ray optics: towards wavelengths of 13.5 nm and beyond

Demin,

Korneev,

Glagolev

et al. 2023

Preprint

0

View full text Add to dashboard Cite

In this work we analyze the possibility of using refractive lenses for X-ray lithography in the wavelength range λ=2-20 nm, where the absorption of radiation in the lens material has a significant impact on the image quality. The general scheme of image formation in projection refractive X-ray optics using a composite objective lens consisting of biconcave elementary lenses is considered. By means of the analytical solution and finite-element simulation model, possible ways to obtain the lens transmission function taking into account the absorption of X-rays were investigated. A lens based on a beryllium (Be) thin film with a complex refractive index n=0.989+0.0015i was chosen to estimate its optical properties at a wavelength of 13.5 nm. Two mechanisms of blurring of the X-ray beam at the lens focus were studied: a mechanism associated with X-ray diffraction and a mechanism based on the absorption of X-ray radiation in the lens material. The possibility of reducing X-ray absorption by switching to diffractive and kinoform lenses is being explored. A method for constructing an image in a diffraction lens with a 4-fold reduction taking into account X-ray absorption is presented. It was shown that to obtain image resolution in the range of 20-40 nm, composite kinoform lenses consisting of a small number (N=3-6) of elementary lenses can be used.

show abstract