Optical microlithography on oblique and multiplane surfaces using diffractive phase masks

Wang, Peng; Menon, Rajesh

doi:10.1117/1.jmm.14.2.023507

Cited by 15 publications

(13 citation statements)

References 37 publications

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“…Here, we reiterate that diffractive optics can readily enable broadband focusing, while still maintaining the planar architecture. Previously, we have functionalized diffractive optics as a solar spectrum splitter/concentrator 21 , multi-color encoder 22 , phase masks for 3D lithography 23 and dispersion elements in computational spectroscopy 24 .…”

mentioning

confidence: 99%

“…For simplicity, we utilize a positive-tone photoresist, SC1827 deposited on a soda-lime glass substrate as the device material. A commercial grayscale lithography tool was employed to rapidly pattern the device in a single step 21 22 23 24 . The width, Δ is dictated by the resolution of this tool.…”

mentioning

confidence: 99%

“…In order to achieve super-achromatic performance, we applied a modified direct-binary-search (DBS) algorithm to optimize the distribution of groove heights, h i 21 22 23 24 27 . It is a perturbation-based iterative method.…”

mentioning

confidence: 99%

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Chromatic-aberration-corrected diffractive lenses for ultra-broadband focusing

Wang

Mohammad

Menon

2016

Sci Rep

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176

135

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We exploit the inherent dispersion in diffractive optics to demonstrate planar chromatic-aberration-corrected lenses. Specifically, we designed, fabricated and characterized cylindrical diffractive lenses that efficiently focus the entire visible band (450 nm to 700 nm) onto a single line. These devices are essentially pixelated, multi-level microstructures. Experiments confirm an average optical efficiency of 25% for a three-wavelength apochromatic lens whose chromatic focus shift is only 1.3 μm and 25 μm in the lateral and axial directions, respectively. Super-achromatic performance over the continuous visible band is also demonstrated with averaged lateral and axial focus shifts of only 1.65 μm and 73.6 μm, respectively. These lenses are easy to fabricate using single-step grayscale lithography and can be inexpensively replicated. Furthermore, these devices are thin (<3 μm), error tolerant, has low aspect ratio (<1:1) and offer polarization-insensitive focusing, all significant advantages compared to alternatives that rely on metasurfaces. Our design methodology offers high design flexibility in numerical aperture and focal length, and is readily extended to 2D.

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confidence: 99%

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confidence: 99%

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Chromatic-aberration-corrected diffractive lenses for ultra-broadband focusing

Wang

Mohammad

Menon

2016

Sci Rep

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176

135

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“…3 under monochromatic illumination [9]. In fact, we previously demonstrated this inter-changeability in experiments with laser illumination [10]. However, this inter-changeability is not obvious for broadband illumination.…”

Section: Experimental Results For Full-color Multi-band and Multi-plmentioning

confidence: 91%

Multi-plane, multi-band image projection via broadband diffractive optics

Meem

Majumder²,

Menon³

2019

Appl. Opt.

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We demonstrate visible and near-IR image projection via non-absorbing, multi-level Broadband Diffractive-Optical Elements (BDOEs) in 1 or more planes. By appropriate design of the BDOE topography, we experimentally demonstrate: (1) different images in different spectral bands; (2) different images in different image planes; (3) image magnification by changing the distance between the illumination source and the BDOE; (4) completely flat BDOE via an index-contrast top-coating; and (5) reflective BDOEs. All of these are accomplished with broadband illumination. Furthermore, the BDOEs are highly efficient, versatile and can be inexpensively mass manufactured using imprint-based replication techniques.

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“…is significantly worse than lateral resolution This limitation of single-beam projection has been explored, but not overcome, by investigators developing algorithms to holographically define 3D optical fields with arbitrary intensity distributions at multiple axial planes [72,73], or in a 3D volume [49]. In all cases, axial feature spacing is 10-100-fold greater than the in-plane feature spacing.…”

Section: Rationale For Multibeam Superpositionmentioning

confidence: 99%

Volumetric Additive Manufacturing of Polymer Structures by Holographically Projected Light Fields

Shusteff

2017

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The experience of completing this doctoral dissertation has been akin to the effort of climbing a tall mountain peakreaching the top, you look around with satisfaction and a sense of accomplishment (and possibly also fatigue), and see all the others who made the climb with you. Just as the tallest peaks are virtually impossible to climb without a team, this PhD is not something that I did alone, and the accomplishment belongs as much to my family, friends, and colleagues as it does to me. Most prominently, I owe an enormous debt of gratitude to my wife Tamar. Thank you for supporting and encouraging this slightly foolish endeavor of a PhD all the way through, in the myriad ways that you did (and the ways I didn't even notice), though I was already prone to bouts of working a little too hard even before I started. Мама и папа, вам я вечно благодарен за прочное основание знаний и любви к учёбe. Вы научили меня что такое старание до последних усилий, и зародили во мне безграничноe любопытство, без которых никакой исследователь из меня не мог бы выйтидоктор или нет. И конечно за тот месяц, что вы провели у нас, позволив мне сделать последний рывок к финишу. To my brother Sasha, thank you for putting me up for every visit to Boston to meet with my committee, and for always keeping me humble. To my kids, thank you for being a constant reminder that life is more than work; I hope one day this thesis might serve as a measure of inspiration to climb your own mountain. Thank you to all the friends who cheered, needled, heckled, commiserated, and cheered again along the way, especially Jessica Blazer, and Dr. Dave Sopchak. In the professional realm, thank you foremost to Chris Spadaccini, my friend and unfailingly supportive center lead, for the trust you place in those who work for you, and the example you set as a leader. To my thesis supervisor Prof. Nick Fang, our longtime collaborator, for being willing to take on a grad student with a very weird arrangement, and to my other committee members Profs. Karl Berggren and Jeff Lang for your guidance and mentorship throughout. To the staff of the MIT EECS Graduate Office, who enabled me to thread the administrative and bureaucratic needles needed to get to this point. The reason I could carry out this research at all is because I'm highly fortunate to work with the additive manufacturing team at LLNL, a truly exceptional group of people. When talking about my job, I always tell people how lucky I am to be able to learn something literally every single day; my generous, creative, and knowledgeable colleagues are the reason why. Thanks especially to Allie Browar for the Kingdom of Cubes, and to James Oakdale and Todd Weisgraber for giving me a framework which allowed me to start filling in the yawning gaps in my understanding of photopolymerization. Thank you to my other colleagues, who are too many to nameyour kindness and advice, technical and otherwise, and good humor most of all give me the real reasons that I like coming in to work every day. To those of my managers who s...

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Optical microlithography on oblique and multiplane surfaces using diffractive phase masks

Cited by 15 publications

References 37 publications

Chromatic-aberration-corrected diffractive lenses for ultra-broadband focusing

Chromatic-aberration-corrected diffractive lenses for ultra-broadband focusing

Multi-plane, multi-band image projection via broadband diffractive optics

Volumetric Additive Manufacturing of Polymer Structures by Holographically Projected Light Fields

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