Semiconductor Characterization by Scanning Ion Beam Induced Charge (IBIC) Microscopy

Vittone, E.

doi:10.1155/2013/637608

Cited by 14 publications

(8 citation statements)

References 104 publications

(128 reference statements)

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“…Only samples with the lowest reverse current have been considered for our radiation hardness study. Additional care was taken during final sample selection by performing the scanning Ion Beam Induced Charge (IBIC) microscopy [23] in frontal mode (ion microbeam with a very low rate of up to 1000 cps is scanned perpendicular over a front metal contact) on each pre-selected sample to establish a good uniformity of charge collection efficiency (CCE) across the whole active SBD volume. Subsequent irradiation conditions meant to generate defects in 4H-SiC layer have been optimized for the direct single ion detection and on-line fluence monitoring by counting the number of pulses in each pixel of irradiated areas utilizing the IBIC technique.…”

Section: Methodsmentioning

confidence: 99%

Radiation hardness of n-type SiC Schottky barrier diodes irradiated with MeV He ion microbeam

Pastuović

Capan

Cohen

et al. 2015

Nuclear Instruments and Methods in Physics Research Section B:

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Section: Methodsmentioning

confidence: 99%

Radiation hardness of n-type SiC Schottky barrier diodes irradiated with MeV He ion microbeam

Pastuović

Capan

Cohen

et al. 2015

Nuclear Instruments and Methods in Physics Research Section B:

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“…This task can be performed either through the detection of secondary electrons produced by the impact of the impinging ions, or through the exploitation of the diamond substrate, equipped with suitable electrodes, as a solid‐state single‐ion detector . In this latter case, the detection relies on the measurement of the induced charge signal formed as a consequence of the motion of the electron–hole cloud generated by the ion energy loss in the material . Despite the large electron–hole pair energy creation of diamond (13.2 eV) in comparison to traditional detector materials, the approach has been successfully assessed for the room‐temperature single‐ion detection at energies as low as 200 keV .…”

Section: Deterministic Placement Of Color Centersmentioning

confidence: 99%

“…[128,132] In this latter case, the detection relies on the measurement of the induced charge signal formed as a consequence of the motion of the electron-hole cloud generated by the ion energy loss in the material. [133] Despite the large electron-hole pair energy creation of diamond (13.2 eV) in comparison to traditional detector materials, the approach has been successfully assessed for the room-temperature single-ion detection at energies as low as 200 keV. [132] A further significant improvement in the sensitivity can be expected with the adoption of ion detection techniques at cryogenic temperatures and the development of high-sensitive, low-noise induced charge amplification chains.…”

Section: Fabricationmentioning

confidence: 99%

Quantum Micro–Nano Devices Fabricated in Diamond by Femtosecond Laser and Ion Irradiation

et al. 2019

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Diamond has attracted great interest as a quantum technology platform thanks to its optically active nitrogen vacancy (NV) center. The NV's ground state spin can be read out optically, exhibiting long spin coherence times of ≈1 ms even at ambient temperatures. In addition, the energy levels of the NV are sensitive to external fields. These properties make NVs attractive as a scalable platform for efficient nanoscale resolution sensing based on electron spins and for quantum information systems. Diamond photonics enhance optical interactions with NVs, beneficial for both quantum sensing and information. Diamond is also compelling for microfluidic applications due to its outstanding biocompatibility, with sensing functionality provided by NVs. However, it remains a significant challenge to fabricate photonics, NVs, and microfluidics in diamond. In this Progress Report, an overview is provided of ion irradiation and femtosecond laser writing, two promising fabrication methods for diamond‐based quantum technological devices. The unique capabilities of both techniques are described, and the most important fabrication results of color center, optical waveguide, and microfluidics in diamond are reported, with an emphasis on integrated devices aiming toward high performance quantum sensors and quantum information systems of tomorrow.

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“…The detector was subsequently placed inside the FIB, where a 12 keV 1 H + 2 beam was then scanned over a 25 × 25 µm 2 area inside the CS. Light ions are employed for the initial characterisation because they produce less sample damage and greater ionisation than heavier species for the same kinetic energy [30]. Each 1 H + 2 molecule ion dissociates quasi-instantaneously upon surface impact, due to the energy transfer exceeding the binding energy by several orders of magnitude [31].…”

Section: Fib Performancementioning

confidence: 99%

Near-Surface Electrical Characterisation of Silicon Electronic Devices Using Focused keV Ions

Robson¹,

Räcke²,

Jakob³

et al. 2022

Preprint

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The demonstration of universal quantum logic operations near the fault-tolerance threshold establishes nearsurface implanted donor spin qubits as a plausible platform for scalable quantum computing in silicon. The next technological step to realise this vision is a deterministic fabrication method to create shallowly placed donor arrays. Here, we present a new approach to manufacture such arrays using custom-fabricated single ion detection devices. By combining a focused ion beam system incorporating an electron-beam-ion-source with in-situ ion detection electronics, we first demonstrate a versatile method to spatially evaluate the device response characteristics to near-surface implanted low-energy 1 H + 2 ions. The results aid in understanding the critical role that the oxide interface plays in the ion detection response, and support the development of a new generation of single ion detector technology incorporating an ultra-thin 3.2 nm gate oxide. Next, deterministic implantation of individual 24 keV 40 Ar 2+ ions is demonstrated with ≥99.99% detection confidence. With the forthcoming installation of a 31 P + ion source, this equates to an projected controlled silicon doping yield of 99.62% for 14 keV 31 P + ions, lying well beyond current qubit loss fault threshold estimates for surface code quantum error correction protocols. Our method thus represents an attractive framework for the rapid mask-free prototyping of large high-fidelity silicon donor spin-qubit arrays.

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Semiconductor Characterization by Scanning Ion Beam Induced Charge (IBIC) Microscopy

Cited by 14 publications

References 104 publications

Radiation hardness of n-type SiC Schottky barrier diodes irradiated with MeV He ion microbeam

Radiation hardness of n-type SiC Schottky barrier diodes irradiated with MeV He ion microbeam

Quantum Micro–Nano Devices Fabricated in Diamond by Femtosecond Laser and Ion Irradiation

Near-Surface Electrical Characterisation of Silicon Electronic Devices Using Focused keV Ions

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