High purity isotopically enriched <sup>70</sup>Ge and <sup>74</sup>Ge single crystals: Isotope separation, growth, and properties

Donor electron spins in semiconductors make exceptional quantum bits because of their long coherence times and compatibility with industrial fabrication techniques. Despite many advances in donor-based qubit technology, it remains difficult to selectively manipulate single donor electron spins. Here, we show that by replacing the prevailing semiconductor host material (silicon) with germanium, donor electron spin qubits can be electrically tuned by more than an ensemble linewidth, making them compatible with gate addressable quantum computing architectures. Using X-band pulsed electron spin resonance, we measured the Stark effect for donor electron spins in germanium. We resolved both spin-orbit and hyperfine Stark shifts and found that at 0.4 T, the spin-orbit Stark shift dominates. The spin-orbit Stark shift is highly anisotropic, depending on the electric field orientation relative to the crystal axes and external magnetic field. When the Stark shift is maximized, the spin-orbit Stark parameter is four orders of magnitude larger than in silicon. At select orientations a hyperfine Stark effect was also resolved and is an order of magnitude larger than in silicon. We report the Stark parameters for 75 As and 31 P donor electrons and compare them to the available theory. Our data reveal that 31 P donors in germanium can be tuned by at least four times the ensemble linewidth making germanium an appealing new host material for spin qubits that offers major advantages over silicon.

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“…73 Ge [9,32,33]. This crystal was neutron transmutation doped to a density of 3 × 10 15 75 As donors/cm 3 .…”

Section: Experimental Methodsmentioning

confidence: 99%

Large Stark tuning of donor electron spin qubits in germanium

et al. 2016

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“…The preparation of these crystals is described in more detail in Ref. 23. For the a-Ge films with intermediate 73 Ge concentrations of 31 and 51 %, the appropriate amounts of 70 Ge and 73 Ge were electron-beam melted in a single Be crucible before deposition in order to ensure a homogeneous mixing.…”

Section: Methodsmentioning

confidence: 99%

Hyperfine interactions at dangling bonds in amorphous germanium

et al. 2003

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Isotope-engineered amorphous germanium (a-Ge͒ films with 73 Ge concentrations in the range of 0.1 to 95.6 % have been investigated by electron spin resonance ͑ESR͒ and electrically detected magnetic resonance ͑EDMR͒ at microwave frequencies between 0.434 and 9.35 GHz. The hyperfine interactions of dangling bond ͑DB͒ defects with many 73 Ge nuclei and their spin localization radius have been extracted from the broadening of the EDMR signals in isotope enriched samples at different 73 Ge concentrations. Linewidths as low as ⌬B pp exp ϭ2.6 G have been observed at 0.434 GHz in a sample without 73 Ge nuclear spins. At low 73 Ge concentrations, the frequency-dependent linewidth B pp SO /ϭ4.4 G/GHz is determined by g-factor anisotropy and disorder. A frequency-independent linewidth contribution of about 1 G is attributed to dipolar broadening between the DB electronic spins. Over a large range of intermediate concentrations, the statistically distributed nuclear spins of 73 Ge atoms on sites close to the DB defect atom are responsible for the overall linewidth. The large linewidth ⌬B pp exp ϭ300 G of samples with 73 Ge concentrations of 95.6% requires a model wave function with a Fermi contact interaction of A iso ϭ29 Gϫg B at the defect atom, indicating that a fraction of 3.4% of the DB wave function originates from s-like orbitals there. The decay of the rest of the DB wave function can be described with a spin localization radius of 3.5 Å by a numerical model for the statistical hyperfine broadening. The delocalization of the DB spin is much smaller than that of the DB charge density determined in transport measurements.

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“…For spin-based quantum computing, 1 increasing research efforts have focused in recent years on C, Si, and Ge [2][3][4] because they can be isotopically enriched to only contain nuclei with zero spin 5,6 and thus exhibit exceptionally long spin lifetimes. 7,8 The one-dimensional character of Ge-Si core-shell nanowires leads to unique electronic properties in the valence band, where heavy and light hole states are mixed.…”

mentioning

confidence: 99%

Highly tuneable hole quantum dots in Ge-Si core-shell nanowires

Brauns

Ridderbos

et al. 2016

Applied Physics Letters

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We define single quantum dots of lengths varying from 60 nanometers up to nearly half a micron in Ge-Si core-shell nanowires. The charging energies scale inversely with the quantum dot length between 18 and 4 meV. Subsequently we split up a long dot into a double quantum dot with separate control over the tunnel couplings and the electrochemical potential of each dot. Both single and double quantum dot configurations prove to be very stable and show excellent control over the electrostatic environment of the dots, making this system a highly versatile platform for spin-based quantum computing.

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High purity isotopically enriched ⁷⁰Ge and ⁷⁴Ge single crystals: Isotope separation, growth, and properties

Cited by 96 publications

References 18 publications

Large Stark tuning of donor electron spin qubits in germanium

Large Stark tuning of donor electron spin qubits in germanium

Hyperfine interactions at dangling bonds in amorphous germanium

Highly tuneable hole quantum dots in Ge-Si core-shell nanowires

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High purity isotopically enriched 70Ge and 74Ge single crystals: Isotope separation, growth, and properties

Cited by 96 publications

References 18 publications

Large Stark tuning of donor electron spin qubits in germanium

Large Stark tuning of donor electron spin qubits in germanium

Hyperfine interactions at dangling bonds in amorphous germanium

Highly tuneable hole quantum dots in Ge-Si core-shell nanowires

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Product

Resources

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High purity isotopically enriched ⁷⁰Ge and ⁷⁴Ge single crystals: Isotope separation, growth, and properties