Cross sectional evaluation of boron doping and defect distribution in homoepitaxial diamond layers

Araújo, D.; Alegre, Mayer; García, Antonio J.; Villar, M. P.; Bustarret, Étienne; Achatz, Philipp; Volpe, Pierre‐Nicolas; Omnès, Franck

doi:10.1002/pssc.201083991

Cited by 7 publications

(8 citation statements)

References 8 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In order to study the intermediate stages of non-faceted or planarized overgrown diamond structures, a new approach is here proposed, which involves heavily doped nm-thick sublayers used as time markers in a stratigraphic 3 configuration, similar to previous studies of stacks of SiGe alloys 16 . As shown below for sample #2, the borondoped sublayers are easily distinguishable by transmission electron microscopy (TEM) in the conventional diffraction contrast mode 17 , and act as milestones of the growth plane orientation as growth proceeds. This method was designed to address both the issue of defect generation brought about by strong doping modulation, and that of progressive planarization of mesa or trench structures upon epitaxial overgrowth.…”

mentioning

confidence: 99%

Stratigraphy of a diamond epitaxial three-dimensional overgrowth using doping superlattices

Lloret

Fiori

Araújo

et al. 2016

Applied Physics Letters

View full text Add to dashboard Cite

International audienceThe selective doped overgrowth of 3D mesa patterns and trenches has become an essential fabrication step of advanced monolithic diamond-based power devices. A novel methodology is proposed here, combining the overgrowth of plasma-etched cylindrical mesa structures with the sequential growth of doping superlattices. The latter involve thin heavily boron doped epilayers separating thicker undoped epilayers in a periodic fashion. Beside the classical shape analysis under the scanning electron microscope relying on the appearance of facets corresponding to the main crystallographic directions and their evolution toward slow growing facets, the doping superlattices were used as markers in oriented cross-sectional lamellas prepared by Focused Ion Beam and observed by Transmission Electron Microscopy. This stratigraphic approach is shown here to be applicable to overgrown structures where faceting was not detectable. Intermediate growth directions were detected at different times of the growth process and the periodicity of the superlattice allowed to calculate the growth rates and parameters, providing an original insight into the planarization mechanism. Different configurations of the growth front were obtained for different sample orientations, illustrating the anisotropy of the 3D growth. Dislocations were also observed along the lateral growth fronts with two types of Burger vector: bsub01-1 = 1/2 [01-1] and bsub112 = 1/6 [112]. Moreover, the clustering of these extended defects in specific regions of the overgrowth prompted a proposal of two different dislocation generation mechanisms

show abstract

mentioning

confidence: 99%

Stratigraphy of a diamond epitaxial three-dimensional overgrowth using doping superlattices

Lloret

Fiori

Araújo

et al. 2016

Applied Physics Letters

View full text Add to dashboard Cite

show abstract

“…Heavily doped nm-thick sublayers work as time markers in a such a stratigraphic configuration. Such layers, which are easily distinguishable by transmission electron microscopy in conventional diffraction mode (CTEM), act as milestones of the growth plane orientation as growth proceeds. , In this context, growth orientations are determined easily by measuring the misorientation of the doped layers with respect to the {100} orientation of the initial substrate surface.…”

Section: Resultsmentioning

confidence: 99%

Three-Dimensional Diamond MPCVD Growth over MESA Structures: A Geometric Model for Growth Sector Configuration

Lloret

Araújo

Eon

et al. 2018

Crystal Growth & Design

Self Cite

View full text Add to dashboard Cite

The overgrowth of {100}-oriented patterned diamond substrates by microwave plasma enhanced chemical vapor deposition was studied by transmission electron microscopy through a stratigraphic approach. A sector-like growth behavior is evidenced, resulting from a competition between slowly growing facets at protruding (top) corners and edges against quickly growing facets at recessing (bottom) corners. Depending on the pattern orientation and height, under some particular experimental conditions, it is possible to predict the sequence of growth sectors, and thus to choose the crystallographic orientation of the overgrown surface, by stopping the growth at the right stage. A simple two-dimensional model is provided, allowing the fabrication of structures adapted to the requirements of specific electronic devices.

show abstract

“…This TEM related technique, however, is suitable to evaluate boron content when the dopant level is high, over the 10 19 cm −3 scale. When boron level is below that, CL on cross section foils constitutes a more suitable methodology [108]. By far, the control of defects, especially dislocations, in diamond is one of the main goals for diamond researchers, as they can be responsible for future leakage currents in the device.…”

Section: Structural Characterization Techniquesmentioning

confidence: 99%

Diamond for Electronics: Materials, Processing and Devices

et al. 2021

View full text Add to dashboard Cite

Progress in power electronic devices is currently accepted through the use of wide bandgap materials (WBG). Among them, diamond is the material with the most promising characteristics in terms of breakdown voltage, on-resistance, thermal conductance, or carrier mobility. However, it is also the one with the greatest difficulties in carrying out the device technology as a result of its very high mechanical hardness and smaller size of substrates. As a result, diamond is still not considered a reference material for power electronic devices despite its superior Baliga’s figure of merit with respect to other WBG materials. This review paper will give a brief overview of some scientific and technological aspects related to the current state of the main diamond technology aspects. It will report the recent key issues related to crystal growth, characterization techniques, and, in particular, the importance of surface states aspects, fabrication processes, and device fabrication. Finally, the advantages and disadvantages of diamond devices with respect to other WBG materials are also discussed.

show abstract

Cross sectional evaluation of boron doping and defect distribution in homoepitaxial diamond layers

Cited by 7 publications

References 8 publications

Stratigraphy of a diamond epitaxial three-dimensional overgrowth using doping superlattices

Stratigraphy of a diamond epitaxial three-dimensional overgrowth using doping superlattices

Three-Dimensional Diamond MPCVD Growth over MESA Structures: A Geometric Model for Growth Sector Configuration

Diamond for Electronics: Materials, Processing and Devices

Contact Info

Product

Resources

About