Deterministic Shallow Dopant Implantation in Silicon with Detection Confidence Upper‐Bound to 99.85% by Ion–Solid Interactions

Jakob, Alexander; Robson, Simon G.; Schmitt, Vivien; Mourik, Vincent; Posselt, M.; Spemann, D.; Johnson, Brett C.; Firgau, Hannes R.; Mayes, Edwin; McCallum, Jeffrey C.; Morello, Andrea; Jamieson, David N.

doi:10.1002/adma.202103235

Cited by 28 publications

(44 citation statements)

References 58 publications

(81 reference statements)

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“…The latter results in a low energy dispersion, important for avoiding chromatic aberration when focusing by electric field lenses. Additionally, our method uses singly charged ions at energies lower than 10 keV, unlike methods that rely on the detection of single ion impact events [15]. The low energy implantation reduces position uncertainty due to straggling and surface destruction of the bulk diamond.…”

Section: Motivationmentioning

confidence: 99%

“…Along the axial direction, the trap is encapsulated by two pierced end-caps with a length of 10 mm, allowing for the extraction of the ions by switching them to high voltage. The ion gun serves as a source for molecular 15 N + 2 ions, which are loaded into the linear Paul trap together with atomic Ca + ions from an oven. A Wien filter after the ion gun (not shown) may be used.…”

Section: Experimental Apparatus and Proceduresmentioning

confidence: 99%

“…In case of a higher charge to mass ratio compared to calcium, the dark ion e.g. 15 N 2 will arrive earlier at the endcap. At the moment the dark ion is inside the endcap, the voltage of the endcap is switched to a positive value, deflecting the calcium ion back when approaching the endcap.…”

Section: Experimental Apparatus and Proceduresmentioning

confidence: 99%

“…For an unambiguous determination of the dark ion species, i.e. to identify the trapped particle as a successfully loaded 15 N + 2 molecular ion, we extract theions and detect them after a flight of 428 mm in length using a secondary electron multiplier with an efficiency of 96±2 %. During ion extraction, we switch off the RF amplitude, to avoid shot-to-shot modifications of the ion trajectory.…”

Section: Experimental Apparatus and Proceduresmentioning

confidence: 99%

“…Since each single nitrogen ion is trapped and identified prior to implantation, After carefully purging all tube connections between 15 N 2 gas bottle and ion gun we found no indication for 14 N + 2 ions. However, after a waiting time of 5 days, the histogram shows a peak at mass 28, which was assigned to the isotope 14 N. b) Velocity variations of 40 Ca (purple) and 15 N 2 (blue) ions as a function of delay between RF and DC switching. Ions with a mass of 40 and 30, respectively, arrive at different times at the position of the endcap hole, and explore different phases of the RF drive field.…”

Section: Sample Preparation and Implantationmentioning

confidence: 99%

See 4 more Smart Citations

Fabrication of $^{15}\textrm{NV}^{-}$ centers in diamond using a deterministic single ion implanter

Groot-Berning,

Jacob,

Osterkamp

et al. 2021

Preprint

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Nitrogen Vacancy (NV) centers in diamond are a platform for several important quantum technologies, including sensing, communication and elementary quantum processors. In this letter we demonstrate the creation of NV centers by implantation using a deterministic single ion source. For this we sympathetically laser-cool single 15 N + 2 molecular ions in a Paul trap and extract them at an energy of 5.9 keV. Subsequently the ions are focused with a lateral resolution of 121(35) nm and are implanted into a diamond substrate without any spatial filtering by apertures or masks. After high-temperature annealing, we detect the NV centers in a confocal microscope and determine a conversion efficiency of about 0.6 %. The 15 NV centers are characterized by optically detected magnetic resonance (ODMR) on the hyperfine transition and coherence time.

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Section: Motivationmentioning

confidence: 99%

Section: Experimental Apparatus and Proceduresmentioning

confidence: 99%

Section: Experimental Apparatus and Proceduresmentioning

confidence: 99%

Section: Experimental Apparatus and Proceduresmentioning

confidence: 99%

Section: Sample Preparation and Implantationmentioning

confidence: 99%

See 3 more Smart Citations

Fabrication of $^{15}\textrm{NV}^{-}$ centers in diamond using a deterministic single ion implanter

Groot-Berning,

Jacob,

Osterkamp

et al. 2021

Preprint

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A High‐Resolution Versatile Focused Ion Implantation Platform for Nanoscale Engineering

Adshead,

Coke,

Aresta

et al. 2023

Adv Eng Mater

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The ability to spatially control and modify material properties on the nanoscale, including within nanoscale objects themselves, is a fundamental requirement for the development of advanced nanotechnologies. We demonstrate the development of a platform for nanoscale advanced materials engineering (P‐NAME) designed to meet this demand. P‐NAME delivers a high‐resolution focused ion beam system with a co‐incident scanning electron microscope and secondary electron detection of single‐ion implantation events. We demonstrate the isotopic mass resolution capability of the P‐NAME system for a wide range of ion species, offering access to the implantation of isotopes that are vital for nanomaterials engineering and nano‐functionalisation. The performance of the isotopic mass selection is independently validated using secondary ion mass spectrometry (SIMS) for a number of species implanted into intrinsic silicon. The SIMS results are shown to be in good agreement with dynamic ion implantation simulations, demonstrating the validity of this simulation approach. We also demonstrate the wider performance capabilities of P‐NAME including sub‐10 nm ion beam imaging resolution and the ability to perform direct‐write ion beam doping and nanoscale ion lithography.This article is protected by copyright. All rights reserved.

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Graphene‐Enhanced Single Ion Detectors for Deterministic Near‐Surface Dopant Implantation in Diamond

Collins,

Jakob,

Robson

et al. 2023

Adv Funct Materials

Self Cite

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Diamond color centers with applications to single photon sources, quantum computation, and magnetic field sensing down to the nanoscale have been investigated using ensembles of near‐surface implanted atoms. Deterministic ion implantation for ions stopping between 30 and 130 nm deep is demonstrated by configuring an electronic‐grade diamond substrate with a biased surface graphene electrode connected to charge sensitive electronics. The thin graphene electrode has a negligible surface dead layer, so implantation events are signaled from the drift of electron–hole pairs induced by the dissipation of ion kinetic energy in the substrate. Ion beam induced charge maps from a scanned 1 MeV He microbeam show the graphene electrode is highly effective with a charge collection efficiency up to 86% compared to an O‐terminated diamond surface of 30%. For lower energy ions, applicable to near surface implantation, single ion detection confidence is >99(1)% for 19.5 keV H and 85(2)% for 24 keV N ions to allow maps of device surface features by employing a focused ion beam microscope or an atomic force microscope cantilever incorporating a nanostencil beam collimator. In the near‐term, this system can be used to investigate the annealing dynamics for the conversion of single implanted ions into diamond color centers.

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Deterministic Shallow Dopant Implantation in Silicon with Detection Confidence Upper‐Bound to 99.85% by Ion–Solid Interactions

Cited by 28 publications

References 58 publications

Fabrication of $^{15}\textrm{NV}^{-}$ centers in diamond using a deterministic single ion implanter

Fabrication of $^{15}\textrm{NV}^{-}$ centers in diamond using a deterministic single ion implanter

A High‐Resolution Versatile Focused Ion Implantation Platform for Nanoscale Engineering

Graphene‐Enhanced Single Ion Detectors for Deterministic Near‐Surface Dopant Implantation in Diamond

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