Direct detection of polystyrene equivalent nanoparticles with a diameter of 21 nm (∼λ/19) using coherent Fourier scatterometry

Kolenov, Dmytro; Zadeh, Iman Esmaeil; Horsten, Roland; Pereira, Silvania F.

doi:10.1364/oe.421145

Cited by 9 publications

(5 citation statements)

References 16 publications

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“…Notably, recent advancements have seen CFS successfully modeling and experimentally detecting an isolated defect in the periodic nanostructure [35]. However, compared to other techniques CFS is very sensitive to the alignment and stability of the system, and is limited by the surface roughness of the substrate and the noise of the camera pixels [36].…”

Section: Introductionmentioning

confidence: 99%

Investigation of coherent Fourier scatterometry as a calibration tool for determination of steep side wall angle and height of a nanostructure

Paul,

Rafighdoost,

Dou

et al. 2024

Meas. Sci. Technol.

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Nanostructures with steep side wall angles (swa) play a pivotal role in various technological applications. Accurate characterization of these nanostructures is crucial for optimizing their performance. In this study, we propose a far-field detection method based on coherent Fourier scatterometry (CFS) for accurate quantification of steep swa and heights in cliff-like nanostructures. Our approach introduces a parameter termed “visibility”, derived from the unique far-field signatures of cliff-like nanostructures. This parameter serves as a quantitative metric for the calibration of swa and heights. The heightened sensitivity of our method is demonstrated, particularly when the incident polarization is perpendicular to the invariant direction of the nanostructure for swa calibration, while both polarization states exhibit sensitivity to height calibration. Furthermore, a comprehensive sensitivity analysis reveals the stable nature of our method, showcasing that even with fluctuations of ±10 nm in the position of the nanostructure, the resulting swa remains stable within a range of ±0.5°. The exponential variation of the visibility parameter with edge roundness is observed, with fluctuations in edge roundness within 10 nm resulting in swa variations within 1.7° for both polarization states. In experimental validations, our results demonstrate reasonable agreement between CFS-derived and AFM measurements. The AFM data for swa (77.99° ± 1.37°) and height (148.35 nm ±2.11 nm) are corroborated with CFS-derived value of swa (77.75° ± 3.61°, 78.36° ± 3.89°) and height (149.42 nm ±1.66 nm, 150.05 nm ±1.04 nm) obtained from calibration curves for TM and TE incident beams, respectively. Overall, our findings underscore CFS as a potential and reliable tool for nanostructure characterization, offering precise measurements that are pivotal for advancing nanotechnology.

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Section: Introductionmentioning

confidence: 99%

Investigation of coherent Fourier scatterometry as a calibration tool for determination of steep side wall angle and height of a nanostructure

Paul,

Rafighdoost,

Dou

et al. 2024

Meas. Sci. Technol.

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“…13 There are already several reports in literature about the detection of defects or particles using CFS. 10,14,15 However, the investigation of different nanometer-range samples of different shape or geometrical arrangement, as presented in this work, has not been extensively investigated yet. However, this comprises an important advancement as it is important to identify possible directional dependencies of defects, which indicate systematic errors in semiconductor manufacturing, or to distinguish differently arranged clusters of nanoparticles.…”

Section: Introductionmentioning

confidence: 99%

Detection of geometrical patterns of self-assembled gold nanospheres and top-down fabricated nanostructures using coherent Fourier scatterometry

Krämer¹,

Kroth²,

Sure³

et al. 2023

Optical Measurement Systems for Industrial Inspection XIII

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Detection of nanoparticles gets more and more relevant in various fields of application, e.g., semiconductor technology, medicine or biology. A fast and universal detection method of nanoparticles is essential for these leading-edge technologies. Classical imaging methods struggle with the resolution of nanoparticles smaller than the diffraction limit. Established optical near-field methods are complex and time consuming. We demonstrate that using Coherent Fourier Scatterometry can overcome most of these challenges. For this purpose, we study the optical response of gold nanosphere arrangements on silicon wafers. In particular, we examine arrays of particles arranged in geometrical structures such as lines, squares, triangles, and L-shapes. The dimensions of these structures are in the order or even smaller than the Airy diameter. Correlations between the geometry of the particle arrangement and the intensity distributions in the Fourier plane are characterized by applying different analyzing methods. Thus, it is possible to distinguish between different structures and, furthermore, to extract their geometrical orientations. In addition, gold nanostructures of defined shape, but different sample thicknesses top-down fabricated on silicon are also investigated. These nanostructure shapes studied comprise the same geometries as mentioned above as well as spirals with a diameter comparable to the spot size of the used microscope objective.

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“…CFS is an optical metrology technique based on the light scattered from the object in the far field, which is very sensitive to detect small isolated particles or small changes in parameters of nanostructrues. In addition, the technique is not limited by diffraction, and the detection of deep subwavelength-size particles present on top of a plane substrate has been recently demonstrated [2]. However, as we move towards patterned surfaces, the detection of contamination becomes more complicated as we have to consider the effects of the background structure in addition to that of the contamination itself.…”

Section: Introductionmentioning

confidence: 99%

Coherent Fourier scatterometry for particle detection on structured surfaces

2022

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We demonstrate the detection of particles/contamination present on a structured surface using Coherent Fourier scatterometry (CFS) by applying Fourier filtering to the scanned maps, which eliminates background effects due to the electronic noise as well the structure itself. We show that by using filters in the Fourier space we can significantly improve the detection capabilities of the particles present on the structure.

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Direct detection of polystyrene equivalent nanoparticles with a diameter of 21 nm (∼λ/19) using coherent Fourier scatterometry

Cited by 9 publications

References 16 publications

Investigation of coherent Fourier scatterometry as a calibration tool for determination of steep side wall angle and height of a nanostructure

Investigation of coherent Fourier scatterometry as a calibration tool for determination of steep side wall angle and height of a nanostructure

Detection of geometrical patterns of self-assembled gold nanospheres and top-down fabricated nanostructures using coherent Fourier scatterometry

Coherent Fourier scatterometry for particle detection on structured surfaces

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