X-Ray Lithography for Nanofabrication: Is There a Future?

Bharti, Amardeep; Turchet, A.; Marmiroli, Benedetta

doi:10.3389/fnano.2022.835701

Cited by 15 publications

(6 citation statements)

References 76 publications

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“…However, XRL may not be suitable for the mass production of biomedical systems. The high cost associated with investing in a synchrotron source and producing complex x-ray masks, coupled with the relatively low throughput, restricts its widespread use in the biomedical industry [ 41 , 45 ].…”

Section: Conventional Lithographic Techniquesmentioning

confidence: 99%

“…Wavelength reduced to 193 nm or 248 nm [ 32 ] 65–130 nm [ 32 ] Improved resolution in comparison to traditional UV lithography [ 32 ] Shorter wavelengths are more easily reflected [ 33 ] Interference effects [ 32 ] Maximum total thickness variation is 0.5 µm [ 34 ] Low depth of focus [ 34 ] Extreme UV lithography Use UV light and mask to pattern a photoresist. Wavelength reduced to 13.5 nm [ 35 ] < 10 nm [ 36 ] Improved resolution in comparison to traditional UV lithography [ 36 ] Shorter wavelengths are more easily reflected [ 33 ] Low photon transmission efficiency [ 37 ] Defects in the photomask warp pattern [ 38 ] Secondary electrons cause blur [ 39 ] Increased stochastic pattern variations [ 40 ] X-ray lithography Use x-rays and mask to pattern a photoresist [ 41 ] 15 nm [ 42 ] Improved resolution in comparison to traditional UV lithography [ 42 ] Large substrate-mask distances do not cause diffraction/proximity effects until the feature width approaches 100 nm [ 43 ] Shorter wavelengths are more easily reflected [ 33 ] Masks are thin, fragile, and expensive [ 44 ] Secondary electrons cause blur [ 45 ] Electron beam lithography Use electrons to pattern a resist [ 46 ] > 10 nm [ 47 ] Precise control [ 48 ] Can pattern complex geometries [ 48 ] Beam can damage the substrate [ …”

Section: Introductionmentioning

confidence: 99%

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Advances in lithographic techniques for precision nanostructure fabrication in biomedical applications

Stokes,

Clark,

Odetade

et al. 2023

Discover Nano

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Nano-fabrication techniques have demonstrated their vital importance in technological innovation. However, low-throughput, high-cost and intrinsic resolution limits pose significant restrictions, it is, therefore, paramount to continue improving existing methods as well as developing new techniques to overcome these challenges. This is particularly applicable within the area of biomedical research, which focuses on sensing, increasingly at the point-of-care, as a way to improve patient outcomes. Within this context, this review focuses on the latest advances in the main emerging patterning methods including the two-photon, stereo, electrohydrodynamic, near-field electrospinning-assisted, magneto, magnetorheological drawing, nanoimprint, capillary force, nanosphere, edge, nano transfer printing and block copolymer lithographic technologies for micro- and nanofabrication. Emerging methods enabling structural and chemical nano fabrication are categorised along with prospective chemical and physical patterning techniques. Established lithographic techniques are briefly outlined and the novel lithographic technologies are compared to these, summarising the specific advantages and shortfalls alongside the current lateral resolution limits and the amenability to mass production, evaluated in terms of process scalability and cost. Particular attention is drawn to the potential breakthrough application areas, predominantly within biomedical studies, laying the platform for the tangible paths towards the adoption of alternative developing lithographic technologies or their combination with the established patterning techniques, which depends on the needs of the end-user including, for instance, tolerance of inherent limits, fidelity and reproducibility.

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Section: Conventional Lithographic Techniquesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Advances in lithographic techniques for precision nanostructure fabrication in biomedical applications

Stokes,

Clark,

Odetade

et al. 2023

Discover Nano

View full text Add to dashboard Cite

show abstract

“… photons). At the same time, for the tasks of X-ray nanolithography, a number of research groups propose concepts of optical elements that are alternative to multilayer Bragg mirrors in modern EUV scanners [17]: diffraction optics (Fresnel zone plates [18]), refractive optics (biconcave parabolic lenses [19]), as well as composite (refractive-diffraction) kinoform lenses [20]. 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.…”

Section: De Ementioning

confidence: 99%

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

Demin,

Korneev,

Glagolev

et al. 2023

Preprint

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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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“…X-ray lithography (XRL) along with its branches (including LIGA) is a versatile technology for microfabrication purposes compared to other types of lithography: optical, e-beam and ion-beam ones [1,2]. It provides new possibilities for creating micro-devices (MEMS and MOEMS) with a high aspect ratio in thick (∼1 mm) resists with almost vertical sidewalls [3], offering various resist illumination techniques (dynamic, maskless, interference ones, etc). Many x-ray optical elements, such as x-ray refractive lenses [4], collimators [5], and diffraction gratings [6] are manufactured by this technique.…”

Section: Introductionmentioning

confidence: 99%

Reflective x-ray masks for x-ray lithography

Chumak,

Peredkov,

Devizenko

et al. 2024

J. Micromech. Microeng.

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Application of X-ray multilayers as reflective X-ray masks (RXMs) for X-ray lithography is proposed. The mask is a specially prepared multilayer mirror capable to selectively reflect X-rays. The use of grazing geometry allows a pattern design on the mask to be compressed in one direction. Application examples are given for the masks (WC/Si multilayers) with two types of a radiation source: an X-ray tube (λ=0.154 nm) and a synchrotron (λ~0.35 nm). The compression of the mask segments by 14-30 times with the imprint size in the resist plane 3.5-4 μm is obtained. The advantages of the proposed masks are given. The possibilities of obtaining submicron imprints are discussed.

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X-Ray Lithography for Nanofabrication: Is There a Future?

Cited by 15 publications

References 76 publications

Advances in lithographic techniques for precision nanostructure fabrication in biomedical applications

Advances in lithographic techniques for precision nanostructure fabrication in biomedical applications

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

Reflective x-ray masks for x-ray lithography

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