Laser Engineering Nanocarbon Phases within Diamond for Science and Electronics

Salter, Patrick S.; Villar, M. Pilar; Lloret, Fernando; Reyes, Daniel F.; Krueger, Marta; Henderson, Calum S.; Araujo, Daniel; Jackman, Richard B.

doi:10.1021/acsnano.3c07116

ACS Nano

2024

DOI: 10.1021/acsnano.3c07116

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Laser Engineering Nanocarbon Phases within Diamond for Science and Electronics

Patrick S. Salter,

M. Pilar Villar,

Fernando Lloret

et al.

Abstract: Diamond, as the densest allotrope of carbon, displays a range of exemplary material properties that are attractive from a device perspective. Despite diamond displaying high carbon–carbon bond strength, ultrashort (femtosecond) pulse laser radiation can provide sufficient energy for highly localized internal breakdown of the diamond lattice. The less-dense carbon structures generated on lattice breakdown are subject to significant pressure from the surrounding diamond matrix, leading to highly unusual formatio… Show more

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Cited by 4 publications

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Covalently‐Bonded Diaphite Nanoplatelet with Engineered Electronic Properties of Diamond

Zhai,

Zhang,

Chen

et al. 2024

Adv Funct Materials

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Diamond, as a highly promising “extreme” semiconductor material, necessitates electronic property engineering to unleash its full potential in electronic and photonic devices. In this work, the diaphite nanoplatelet, consisting of (11) planes of diamond nanoplatelet covalently bonded with graphite (0001) planes, is facilely synthesized using one‐step microwave plasma enhanced chemical vapor deposition method. The high‐energy plasma created by the pillar plays a crucial role in the formation. Importantly, altered electronic and optical properties are determined in the diaphite nanoplatelet through electron energy loss spectrum, density functional theory calculations, and cathodoluminescence spectroscopy. It is revealed that the strong sp3/sp2‐hybridized interfacial covalent bonding in the diaphite nanoplatelet induces the electron transfer from diamond to graphite. This modulates the electronic structure of the near‐interface layer of diamond and triggers a new local trapping band below the conduction band minimum within the bandgap. Consequently, the covalently‐bonded diaphite exhibits a different optical emission characteristic ranging from 2.5 to 3.64 eV, featuring a significant peak blueshift of 430 meV compared to the H‐terminated diamond. This work demonstrates a novel method to engineer the electronic properties of diamond, opening avenues for functional semiconductor device applications of diamond.

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Covalently‐Bonded Diaphite Nanoplatelet with Engineered Electronic Properties of Diamond

Zhai,

Zhang,

Chen

et al. 2024

Adv Funct Materials

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Applications of diamond films: a review

Zulkharnay,

May

2024

Functional Diamond

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Parallel laser fabrication of electrically conductive graphitic columns in diamond

Krueger,

Booth,

Salter

2024

Opt. Express

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An ultrashort pulsed laser focused beneath the surface of diamond can breakdown the lattice and induce graphite, and can hence be used for the fabrication of electrical connections embedded in the diamond bulk. In this work, an adaptive hologram displayed on a liquid crystal spatial light modulator is used to simultaneously generate multiple foci and correct for aberrations associated with refraction at the diamond interface. Arrays of graphitic columns are thus laser written with a single scan through the thickness of the diamond, improving fabrication times by more than an order of magnitude. The electrical characteristics of the fabricated structures are analyzed as a function of the number and lateral spacing of foci in an array, and compared with results where structures are fabricated sequentially with a single laser focus.

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Laser Engineering Nanocarbon Phases within Diamond for Science and Electronics

Cited by 4 publications

References 50 publications

Covalently‐Bonded Diaphite Nanoplatelet with Engineered Electronic Properties of Diamond

Covalently‐Bonded Diaphite Nanoplatelet with Engineered Electronic Properties of Diamond

Applications of diamond films: a review

Parallel laser fabrication of electrically conductive graphitic columns in diamond

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