Polarity Control in Group-III Nitrides beyond Pragmatism

Mohn, Stefan; Stolyarchuk, N. V.; Markurt, Toni; Kirste, Ronny; Hoffmann, Marc P.; Collazo, Ramón; Courville, Aimeric; Felice, Rosa Di; Sitar, Zlatko; Vennéguès, P.; Albrecht, M.

doi:10.1103/physrevapplied.5.054004

Cited by 102 publications

(92 citation statements)

References 40 publications

(59 reference statements)

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“…The roughness characteristics of each area are noteworthy, Figure c. The roughness difference is related to the response of each particular polar domain region to the particular growth conditions . The Ga‐polar regions (circles) are smooth with rms values of 2.1 ± 0.6 nm.…”

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confidence: 99%

Persistent Photoconductivity, Nanoscale Topography, and Chemical Functionalization Can Collectively Influence the Behavior of PC12 Cells on Wide Bandgap Semiconductor Surfaces

Snyder

Kirste

Collazo

et al. 2017

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Wide bandgap semiconductors such as gallium nitride (GaN) exhibit persistent photoconductivity properties. The incorporation of this asset into the fabrication of a unique biointerface is presented. Templates with lithographically defined regions with controlled roughness are generated during the semiconductor growth process. Template surface functional groups are varied using a benchtop surface functionalization procedure. The conductivity of the template is altered by exposure to UV light and the behavior of PC12 cells is mapped under different substrate conductivity. The pattern size and roughness are combined with surface chemistry to change the adhesion of PC12 cells when the GaN is made more conductive after UV light exposure. Furthermore, during neurite outgrowth, surface chemistry and initial conductivity difference are used to facilitate the extension to smoother areas on the GaN surface. These results can be utilized for unique bioelectronics interfaces to probe and control cellular behavior.

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confidence: 99%

Persistent Photoconductivity, Nanoscale Topography, and Chemical Functionalization Can Collectively Influence the Behavior of PC12 Cells on Wide Bandgap Semiconductor Surfaces

Snyder

Kirste

Collazo

et al. 2017

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“…Further, the agreement extends to the bond angles, matching experiment and theory to within 0.5 • .Given the structure of the stable 2D oxides, there are a number of consequences. First, inversion domain boundaries are often found in thin film nitrides(24), and the observed oxides offer a mechanism for their creation. Notably, the oxides inherently reverse polarity through the transition from octahedral to tetrahedral bonding as discussed above.The inversion of polarity in the outer most layer of the oxide would seed N-polar nitride growth.…”

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confidence: 99%

Structure of Ultrathin Native Oxides on III–Nitride Surfaces

Dycus

Mirrielees

Grimley

et al. 2018

ACS Appl. Mater. Interfaces

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When pristine material surfaces are exposed to air, highly reactive broken bonds can promote the formation of surface oxides with structures and properties differing greatly from bulk. Determination of the oxide structure is often elusive through the use of indirect diffraction methods or techniques that probe only the outermost layer. As a result, surface oxides forming on widely used materials, such as group III-nitrides, have not been unambiguously resolved, even though critical properties can depend sensitively on their presence. In this study, aberration corrected scanning transmission electron microscopy reveals directly, and with depth dependence, the structure of ultrathin native oxides that form on AlN and GaN surfaces. Through atomic resolution imaging and spectroscopy, we show that the oxide layers are comprised of tetrahedra-octahedra cation-oxygen units, in an arrangement similar to bulk θ-AlO and β-GaO. By applying density functional theory, we show that the observed structures are more stable than previously proposed surface oxide models. We place the impact of these observations in the context of key III-nitride growth, device issues, and the recent discovery of two-dimensional nitrides.

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“…Recently, it was reported that Ga-polar GaN grows on N-polar GaN substrates with the introduction of surface-oxidized AlN thin films [27]. Mohn et al have shown that formation of a rhombohedral AlON layer may be able to convert an N-polar surface to a metal-polar one [28]. In the present case of GaN on AlN/graphene, surface-oxidized AlN layers were formed before GaN growth by thermal oxidization in air at 200…”

Section: Growth and Characterization Of Gan Filmsmentioning

confidence: 65%

GaN-Based Light-Emitting Diodes with Graphene Buffers for Their Application to Large-Area Flexible Devices

Ohta

Shon

Ueno

et al. 2017

IEICE Trans. Electron.

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SUMMARYCrystalline GaN films can be grown even on amorphous substrates with the use of graphene buffer layers by pulsed sputtering deposition (PSD). The graphene buffer layers allowed us to grow highly c-axisoriented GaN films at low substrate temperatures. Full-color GaN-based LEDs can be fabricated on the GaN/graphene structures and they are operated successfully. This indicates that the present technique is promising for future large-area light-emitting displays on amorphous substrates.

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Polarity Control in Group-III Nitrides beyond Pragmatism

Cited by 102 publications

References 40 publications

Persistent Photoconductivity, Nanoscale Topography, and Chemical Functionalization Can Collectively Influence the Behavior of PC12 Cells on Wide Bandgap Semiconductor Surfaces

Persistent Photoconductivity, Nanoscale Topography, and Chemical Functionalization Can Collectively Influence the Behavior of PC12 Cells on Wide Bandgap Semiconductor Surfaces

Structure of Ultrathin Native Oxides on III–Nitride Surfaces

GaN-Based Light-Emitting Diodes with Graphene Buffers for Their Application to Large-Area Flexible Devices

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