Optical properties of an ensemble of G-centers in silicon

Beaufils, Clément; Redjem, Walid; Rousseau, Emmanuel; Jacques, Vincent; Kuznetsov, A. Yu.; Raynaud, Christophe; Voisin, Christophe; Benali, Abdennacer; Herzig, Tobias; Pezzagna, Sébastien; Meijer, Jan; Abbarchi, Marco; Cassabois, Guillaume

doi:10.1103/physrevb.97.035303

Cited by 73 publications

(110 citation statements)

References 94 publications

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“…The inhomogeneous isotope broadening inherent to nat Si can be eliminated in 28 Si, resulting in linewidth improvements of over two order of magnitude for the C and G centers. Indeed, the linewidth of the G center components seen in 28 Si are only slightly more than twice the limit imposed by homogeneous lifetime broadening, given the measured 5.9 ns G center lifetime [4]. The improved linewidths in 28 Si allow for the clear observation of distinct isotopeshifted components which are much more difficult to observe in nat Si.…”

Section: Discussionmentioning

confidence: 88%

“…The G center, with a NP line at ∼969 meV (∼1280 nm) is one of the most studied radiation damage centers in Si due to its extraordinarily bright emission, as well as large oscillator strength as evidenced by strong optical absorption even for relatively low G center concentrations [1]. Beaufils et al [4] provide an up-to-date and comprehensive review of the G center literature, together with new data on temperature dependences, and a precise measurement of the 5.9 ns luminescence decay time. The G center is now widely agreed to consist of a substitutional-interstitial C pair (C i -C s ) coupled to a Si i .…”

Section: Resultsmentioning

confidence: 99%

“…Here we report on optical emission and absorption studies on three well-known damage centers produced in very high purity Si enriched to 99.995% 28 Si as part of the Avogadro project [12]. All three emit in or near important optical communication bands: the C center (790 meV, or 1571 nm, thought to contain an interstitial C (C i ) and an interstitial O (O i ) [13][14][15][16][17][18]), the G center (969 meV, or 1280 nm, thought to contain a substitutional C (C s ), C i , and an interstitial Si (Si i ) [4,15,19,20]), and the W center (1019 meV, or 1217 nm, thought to consist of three Si i [21][22][23]). All three produce strong photoluminescence (PL) in 28 Si irradiated with 10 MeV electrons, and the G center also has relatively strong absorption transitions.…”

Section: Introductionmentioning

confidence: 99%

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Highly enriched Si28 reveals remarkable optical linewidths and fine structure for well-known damage centers

et al. 2018

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Luminescence and optical absorption due to radiation damage centers in silicon has been studied exhaustively for decades, but is receiving new interest for applications as emitters for integrated silicon photonic technologies. While a variety of other optical transitions have been found to be much sharper in enriched 28 Si than in natural Si, due to the elimination of inhomogeneous isotopic broadening, this has not yet been investigated for radiation damage centers. We report results for the well-known G, W and C damage centers in highly enriched 28 Si, with optical linewidth improvements in some cases of over two orders of magnitude, revealing previously hidden fine structure in the G center emission and absorption. These results have direct implications for the linewidths to be expected from single center emission, even in natural Si, and for models for the G center structure. The advantages of 28 Si can be readily extended to the study of other radiation damage centers in Si. * thewalt@sfu.ca

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Section: Discussionmentioning

confidence: 88%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Highly enriched Si28 reveals remarkable optical linewidths and fine structure for well-known damage centers

et al. 2018

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“…Here, we measure the donor/QD energy spectrum by single-electron transport [46,47] to quantify the strength of the intervalley interference processes in the exchange coupling J(R). We note that the tunability of the exchange interaction opens up interesting possibilities to electrically probe small-scale dopant-based quantum simulators [48][49][50], or to perform electrical spin readout on optically active impurity centers in materials like silicon carbide [51,52], silicon [53,54], and diamond [55,56].…”

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confidence: 99%

Valley Filtering in Spatial Maps of Coupling between Silicon Donors and Quantum Dots

et al. 2018

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Exchange coupling is a key ingredient for spin-based quantum technologies since it can be used to entangle spin qubits and create logical spin qubits. However, the influence of the electronic valley degree of freedom in silicon on exchange interactions is presently the subject of important open questions. Here we investigate the influence of valleys on exchange in a coupled donor/quantum dot system, a basic building block of recently proposed schemes for robust quantum information processing. Using a scanning tunneling microscope tip to position the quantum dot with subnm precision, we find a near monotonic exchange characteristic where lattice-aperiodic modulations associated with valley degrees of freedom comprise less than 2 % of exchange. From this we conclude that intravalley tunneling processes that preserve the donor's ±x and ±y valley index are filtered out of the interaction with the ±z valley quantum dot, and that the ±x and ±y intervalley processes where the electron valley index changes are weak. Complemented by tight-binding calculations of exchange versus donor depth, the demonstrated electrostatic tunability of donor/QD exchange can be used to compensate the remaining intravalley ±z oscillations to realise uniform interactions in an array of highly coherent donor spins. arXiv:1706.09261v2 [cond-mat.mes-hall] 1 Sep 2018

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“…The G-centre emission at 1280 nm is in the spectral range that is vital in long-haul fiber-optic networks and is ideally suited to silicon intra-chip and inter-chip lowpower data interconnects. A new method fully compatible with complementary metal oxide semiconductor (CMOS) technology to produce the lasing G-centre has been reported (Beaufils et al 2018;Berhanuddin et al 2012b). The technique combines implantation of carbon, subsequent heat treatment followed by high energy proton implantation on bulk silicon substrates to form C s C i complexes and Si interstitials.…”

Section: Introductionmentioning

confidence: 99%

G-Centre Formation and Behavior in a Silicon on Insulator Platform by Carbon Ion Implantation and Proton Irradiation

Berhanuddin

Razak

Lourenço

et al. 2019

JSM

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The interest in the G-centre is driven by reports that it can lase in silicon. To further this, the transfer of this technology from bulk silicon to a silicon-on-insulator (SOI) platform is an essential requirement to progress to lasing and optical amplification on silicon. We report on the efficient generation of the lasing G-centre in SOI substrates by proton irradiation of carbon ion implants. Following carbon implantation samples were annealed and then proton irradiated to form the G-centre and characterized by photoluminescence measurements. The temperature dependence of the emission and the behaviour of the G-centre with post proton annealing were investigated and results are compared with identical implants in control samples of bulk silicon. Overall, we find that the optically active G-centre can be up to 300% brighter and has better survivability over a wider process window in SOI than in bulk silicon.

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Optical properties of an ensemble of G-centers in silicon

Cited by 73 publications

References 94 publications

Highly enriched Si28 reveals remarkable optical linewidths and fine structure for well-known damage centers

Highly enriched Si28 reveals remarkable optical linewidths and fine structure for well-known damage centers

Valley Filtering in Spatial Maps of Coupling between Silicon Donors and Quantum Dots

G-Centre Formation and Behavior in a Silicon on Insulator Platform by Carbon Ion Implantation and Proton Irradiation

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