Displacement Talbot lithography for nano-engineering of III-nitride materials

Coulon, Pierre-Marie; Damilano, B.; Alloing, Blandine; Chausse, Pierre; Walde, Sebastian; Enslin, Johannes; Armstrong, R. L.; Vézian, S.; Hagedorn, Sylvia; Wernicke, Tim; Massies, J.; Zúñiga‐Pérez, Jesús; Weyers, M.; Kneissl, Michael; Shields, P. A.

doi:10.1038/s41378-019-0101-2

Cited by 42 publications

(41 citation statements)

References 69 publications

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“…Optimized thermal etching parameters were then used for further experiments on various mask configurations created on c-plane and (1122) semi-polar GaN templates. A detailed description of the dielectric mask fabrication process can be found in the Methods section and our previous publication 33 , while SEM images of the SiN x openings are shown in Fig. S1.…”

Section: Resultsmentioning

confidence: 99%

“…However, the process was reported to be strongly sensitive to threading defects, resulting in the formation of pores under the mask and, therefore, with a poor organization of nanoholes overall and poor uniformity of the nanohole dimensions. More recently, Damilano and co-authors reported several works on the selective area sublimation (SAS) of nanorods and nanoholes having a straight sidewall profile, achieved in a molecular beam epitaxy (MBE) chamber either from a SiN x self-organized mask 15,31 , or a SiN x nanopatterned mask 32,33 . With their conditions, nanorods and nanoholes with a high organization and fairly uniform dimensions were successfully achieved 32,33 .…”

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confidence: 99%

“…More recently, Damilano and co-authors reported several works on the selective area sublimation (SAS) of nanorods and nanoholes having a straight sidewall profile, achieved in a molecular beam epitaxy (MBE) chamber either from a SiN x self-organized mask 15,31 , or a SiN x nanopatterned mask 32,33 . With their conditions, nanorods and nanoholes with a high organization and fairly uniform dimensions were successfully achieved 32,33 . Despite the successful formation of nanoholes, few technical details have been provided on the impact of the thermal etching environment on the morphology of the nanohole arrays.…”

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confidence: 99%

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Influence of the reactor environment on the selective area thermal etching of GaN nanohole arrays

Coulon

Feng

Damilano

et al. 2020

Sci Rep

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Selective area thermal etching (SATE) of gallium nitride is a simple subtractive process for creating novel device architectures and improving the structural and optical quality of III-nitride-based devices. In contrast to plasma etching, it allows, for example, the creation of enclosed features with extremely high aspect ratios without introducing ion-related etch damage. We report how SATE can create uniform and organized GaN nanohole arrays from c-plane and (11-22) semi-polar GaN in a conventional MOVPE reactor. The morphology, etching anisotropy and etch depth of the nanoholes were investigated by scanning electron microscopy for a broad range of etching parameters, including the temperature, the pressure, the NH 3 flow rate and the carrier gas mixture. The supply of NH 3 during SATE plays a crucial role in obtaining a highly anisotropic thermal etching process with the formation of hexagonal non-polar-faceted nanoholes. Changing other parameters affects the formation, or not, of non-polar sidewalls, the uniformity of the nanohole diameter, and the etch rate, which reaches 6 µm per hour. Finally, the paper discusses the SATE mechanism within a MOVPE environment, which can be applied to other mask configurations, such as dots, rings or lines, along with other crystallographic orientations. Nanostructures are continuously drawing the attention of the III-nitride community for their success in improving light emitting devices 1-4 and their use for emerging applications such as water splitting 5 , single photon sources 6 , piezoelectric nanogenerators 7 or solar light harvesting 8. Among the different geometries available, arrays of nanoholes, in the form of a porous or two-dimensional photonic crystal (2D PhC) layer, have been widely investigated. On one side, a porous layer can provide a change in refractive index 9,10 , an increased surface area resulting in both higher sensitivity 11 and larger photocurrent 12,13 , a more efficient light extraction due to enhanced scattering 14,15 , and improved crystal quality by reducing strain and dislocation density 16-19. On the other side, a 2D PhC layer allows one to enhance the IQE thanks to the Purcell effect, increase the light extraction efficiency and improve/control the directionality of III-nitride based light emitting diodes (LED) 20-23. As such, networks of nanoholes have been used in several applications such as distributed Bragg reflectors 10 , sensors 11 , hydrogen generation 12,13 , LEDs 14,22,23 , free-standing GaN films 17 , and energy storage 18,19. The fabrication of nanohole arrays is usually achieved from a III-nitride layer or an LED structure via a subtractive process or what is called a top-down approach. Porous layers are generally obtained from GaN layers by various techniques, such as electrochemical etching 9,11,14,16 , photo-electrochemical etching 12,13 , metal assisted chemical etching 24,25 , and high temperature annealing with 26 , or without, a catalyst 15,17-19,27,28. Although the depth of the pores can reach a few microns 13,17-19,24,2...

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Section: Resultsmentioning

confidence: 99%

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Influence of the reactor environment on the selective area thermal etching of GaN nanohole arrays

Coulon

Feng

Damilano

et al. 2020

Sci Rep

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“…Furthermore, a metal mask is preferred to obtain high aspect ratio structures by deep plasma etching. While displacement talbot lithography can pattern thick resist at the nanoscale 30 , it is still an emerging technique with a resolution limited by the wavelength illumination source, often 365 nm 30 or 266 nm 31 , while NIL resolution can be scaled further down.…”

Section: Openmentioning

confidence: 99%

Strain-induced yellow to blue emission tailoring of axial InGaN/GaN quantum wells in GaN nanorods synthesized by nanoimprint lithography

Avit

Robin

Liao

et al. 2021

Sci Rep

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GaN nanorods (NRds) with axial InGaN/GaN MQWs insertions are synthesized by an original cost-effective and large-scale nanoimprint-lithography process from an InGaN/GaN MQWs layer grown on c-sapphire substrates. By design, such NRds exhibit a single emission due to the c-axis MQWs. A systematic study of the emission of the NRds by time-resolved luminescence (TR-PL) and power dependence PL shows a diameter-controlled luminescence without significant degradation of the recombination rate thanks to the diameter-controlled strain tuning and QSCE. A blueshift up to 0.26 eV from 2.28 to 2.54 eV (543 nm to 488 nm) is observed for 3.2 nm thick InGaN/GaN QWs with an In composition of 19% when the NRds radius is reduced from 650 to 80 nm. The results are consistent with a 1-D based strain relaxation model. By combining state of the art knowledge of c-axis growth and the strong strain relieving capability of NRds, this process enables multiple and independent single-color emission from a single uniform InGaN/GaN MQWs layer in a single patterning step, then solving color mixing issue in InGaN based nanorods LED devices.

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“…2.5D structures can be created using 2-photon lithography [40]. For diffractive structures, special techniques can prove successful, such as interference lithography [45] and Talbot lithography [46], which are uniquely suited to produce periodic structures.…”

Section: Diamond Micro-and Nanofabricationmentioning

confidence: 99%

Diamond diffractive optics—recent progress and perspectives

Kiss

Huszka

et al. 2020

Advanced Optical Technologies

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Diamond is an exceptional material that has recently seen a remarkable increase in interest in academic research and engineering since high-quality substrates became commercially available and affordable. Exploiting the high refractive index, hardness, laser-induced damage threshold, thermal conductivity and chemical resistance, an abundance of applications incorporating ever higher-performance diamond devices has seen steady growth. Among these, diffractive optical elements stand out—with progress in fabrication technologies, micro- and nanofabrication techniques have enabled the creation of gratings and diffractive optical elements with outstanding properties. Research activities in this field have further been spurred by the unique property of diamond to be able to host optically active atom scale defects in the crystal lattice. Such color centers allow generation and manipulation of individual photons, which has contributed to accelerated developments in engineering of novel quantum applications in diamond, with diffractive optical elements amidst critical components for larger-scale systems. This review collects recent examples of diffractive optical devices in diamond, and highlights the advances in manufacturing of such devices using micro- and nanofabrication techniques, in contrast to more traditional methods, and avenues to explore diamond diffractive optical elements for emerging and future applications are put in perspective.

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Displacement Talbot lithography for nano-engineering of III-nitride materials

Cited by 42 publications

References 69 publications

Influence of the reactor environment on the selective area thermal etching of GaN nanohole arrays

Influence of the reactor environment on the selective area thermal etching of GaN nanohole arrays

Strain-induced yellow to blue emission tailoring of axial InGaN/GaN quantum wells in GaN nanorods synthesized by nanoimprint lithography

Diamond diffractive optics—recent progress and perspectives

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