N
Nicholas Cheng Yang Tham
Researcher at Nanyang Technological University
Publications - 5
Citations - 301
Nicholas Cheng Yang Tham is an academic researcher from Nanyang Technological University. The author has contributed to research in topics: Surface micromachining & Interference lithography. The author has an hindex of 2, co-authored 5 publications receiving 178 citations.
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Journal ArticleDOI
Lasers in additive manufacturing: A review
Hyub Lee,Chin Huat Joel Lim,Mun Ji Low,Nicholas Cheng Yang Tham,Vadakke Matham Murukeshan,Young-Jin Kim +5 more
TL;DR: In this article, the authors introduce laser-based additive manufacturing methods and review the types of lasers widely used in 3D printing machines, and discuss the future prospects of laser technologies for additive manufacturing.
Journal ArticleDOI
Thermally Controlled Localized Porous Graphene for Integrated Graphene-Paper Electronics
Nicholas Cheng Yang Tham,Pankaj K. Sahoo,Yeongae Kim,Chidanand Hegde,Seok Woo Lee,Young-Jin Kim,Vadakke Matham Murukeshan +6 more
Journal ArticleDOI
Ultrafast volume holography for stretchable photonic structures.
TL;DR: This work proposes the concept of "ultrafast volume holography" for the fabrication of stretchable photonic structures such as tunable VPGs directly in unmodified PDMS, and translates insights in heat regulation via fs repetition rate control into volumetric patterning, forming periodic refractive index modulation in PDMS without post-processing.
Journal ArticleDOI
Erratum to: Lasers in Additive Manufacturing: A Review
Hyub Lee,Chin Huat Joel Lim,Mun Ji Low,Nicholas Cheng Yang Tham,Vadakke Matham Murukeshan,Young-Jin Kim +5 more
TL;DR: The figure 15 in page 315 should be modified as below: as mentioned in this paper, and the figure 16 in page 317 is modified as follows: [15]... ]..
Proceedings ArticleDOI
Multi-beam interferometric patterning in optically transparent materials
TL;DR: In this paper, a configurable multi-beam femtosecond laser interference is proposed to directly pattern nanoscale periodic features within optically transparent solid materials by means of configurable multiuser laser interference.