Chemical carving lithography with scanning catalytic probes

Ki, Bugeun; Kim, Kyung-Hwan; Choi, Kee-Bong; Oh, Jungwoo

doi:10.1038/s41598-020-70407-1

Cited by 3 publications

(1 citation statement)

References 29 publications

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“…MACE fabricates various Si patterns such as wires, trenches, and holes from nano-to micro-scale regimes through a simpler process than other etching processes. [11][12][13][14][15] In MACE, Si is etched through two chemical reaction steps: oxidation and oxide removal. H 2 O 2 is a strong oxidant but does not directly oxidize Si in an HF/H 2 O 2 solution.…”

Section: Introductionmentioning

confidence: 99%

Catalytic nickel silicide as an alternative to noble metals in metal-assisted chemical etching of silicon

Kim¹,

Choi²,

Bong³

et al. 2023

Nanoscale

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Section: Introductionmentioning

confidence: 99%

Catalytic nickel silicide as an alternative to noble metals in metal-assisted chemical etching of silicon

Kim¹,

Choi²,

Bong³

et al. 2023

Nanoscale

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Voltage‐ and Metal‐assisted Chemical Etching of Micro and Nano Structures in Silicon: A Comprehensive Review

Surdo,

Barillaro

2024

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Sculpting silicon at the micro and nano scales has been game‐changing to mold bulk silicon properties and expand, in turn, applications of silicon beyond electronics, namely, in photonics, sensing, medicine, and mechanics, to cite a few. Voltage‐ and metal‐assisted chemical etching (ECE and MaCE, respectively) of silicon in acidic electrolytes have emerged over other micro and nanostructuring technologies thanks to their unique etching features. ECE and MaCE have enabled the fabrication of novel structures and devices not achievable otherwise, complementing those feasible with the deep reactive ion etching (DRIE) technology, the gold standard in silicon machining. Here, a comprehensive review of ECE and MaCE for silicon micro and nano machining is provided. The chemistry and physics ruling the dissolution of silicon are dissected and similarities and differences between ECE and MaCE are discussed showing that they are the two sides of the same coin. The processes governing the anisotropic etching of designed silicon micro and nanostructures are analyzed, and the modulation of etching profile over depth is discussed. The preparation of micro‐ and nanostructures with tailored optical, mechanical, and thermo(electrical) properties is then addressed, and their applications in photonics, (bio)sensing, (nano)medicine, and micromechanical systems are surveyed. Eventually, ECE and MaCE are benchmarked against DRIE, and future perspectives are highlighted.

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Scanning Electrochemical Probe Lithography for Ultra‐Precision Machining of Micro‐Optical Elements with Freeform Curved Surface

Xu,

Han,

Huang

et al. 2024

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Two challenges should be overcome for the ultra‐precision machining of micro‐optical element with freeform curved surface: one is the intricate geometry, the other is the hard‐to‐machining optical materials due to their hardness, brittleness or flexibility. Here scanning electrochemical probe lithography (SECPL) is developed, not only to meet the machining need of intricate geometry by 3D direct writing, but also to overcome the above mentioned mechanical properties by an electrochemical material removal mode. Through the electrochemical probe a localized anodic voltage is applied to drive the localized corrosion of GaAs. The material removal rate is obtained as a function of applied voltage, motion rate, scan segment, etc. Based on the material removal function, an arbitrary geometry can be converted to a spatially distributed voltage. Thus, a series of micro‐optical element are fabricated with a machining accuracy in the scale of 100 s of nanometers. Notably, the spiral phase plate shows an excellent performance to transfer parallel light to vortex beam. SECPL demonstrates its excellent controllability and accuracy for the ultra‐precision machining of micro‐optical devices with freeform curved surface, providing an alternative chemical approach besides the physical and mechanical techniques.

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Chemical carving lithography with scanning catalytic probes

Cited by 3 publications

References 29 publications

Catalytic nickel silicide as an alternative to noble metals in metal-assisted chemical etching of silicon

Catalytic nickel silicide as an alternative to noble metals in metal-assisted chemical etching of silicon

Voltage‐ and Metal‐assisted Chemical Etching of Micro and Nano Structures in Silicon: A Comprehensive Review

Scanning Electrochemical Probe Lithography for Ultra‐Precision Machining of Micro‐Optical Elements with Freeform Curved Surface

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