@article{19401,
  abstract     = {High kinetic inductance superconductors are gaining increasing interest for the realisation of qubits, amplifiers and detectors. Moreover, thanks to their high impedance, quantum buses made of such materials enable large zero-point fluctuations of the voltage, boosting the coupling rates to spin and charge qubits. However, fully exploiting the potential of disordered or granular superconductors is challenging, as their inductance and, therefore, impedance at high values are difficult to control. Here, we report a reproducible fabrication of granular aluminium resonators by developing a wireless ohmmeter, which allows in situ measurements during film deposition and, therefore, control of the kinetic inductance of granular aluminium films. Reproducible fabrication of circuits with impedances (inductances) exceeding 13 kΩ (1 nH per square) is now possible. By integrating a 7.9 kΩ resonator with a germanium double quantum dot, we demonstrate strong charge-photon coupling with a rate of gc/2π = 566 ± 2 MHz. This broadly applicable method opens the path for novel qubits and high-fidelity, long-distance two-qubit gates.},
  author       = {Janik, Marian and Roux, Kevin Etienne Robert and Borja Espinosa, Carla N and Sagi, Oliver and Baghdadi, Abdulhamid and Adletzberger, Thomas and Calcaterra, Stefano and Botifoll, Marc and Garzón Manjón, Alba and Arbiol, Jordi and Chrastina, Daniel and Isella, Giovanni and Pop, Ioan M. and Katsaros, Georgios},
  issn         = {2041-1723},
  journal      = {Nature Communications},
  publisher    = {Springer Nature},
  title        = {{Strong charge-photon coupling in planar germanium enabled by granular aluminium superinductors}},
  doi          = {10.1038/s41467-025-57252-4},
  volume       = {16},
  year         = {2025},
}

@misc{18886,
  abstract     = {Research Data for publication 'Strong charge-photon coupling in planar germanium enabled by granular aluminium superinductors'},
  author       = {Janik, Marian},
  publisher    = {Institute of Science and Technology Austria},
  title        = {{Research data for publication 'Strong charge-photon coupling in planar germanium enabled by granular aluminium superinductors'}},
  doi          = {10.15479/AT:ISTA:18886},
  year         = {2025},
}

@article{18602,
  abstract     = {Semiconductor quantum dots (QDs) in planar germanium (Ge) heterostructures have emerged as front-runners for future hole-based quantum processors. Here, we present strong coupling between a hole charge qubit, defined in a double quantum dot (DQD) in planar Ge, and microwave photons in a high-impedance (Zr = 1.3 kΩ) resonator based on an array of superconducting quantum interference devices (SQUIDs). Our investigation reveals vacuum-Rabi splittings with coupling strengths up to g0/2π = 260 MHz, and a cooperativity of C ~ 100, dependent on DQD tuning. Furthermore, utilizing the frequency tunability of our resonator, we explore the quenched energy splitting associated with strong Coulomb correlation effects in Ge QDs. The observed enhanced coherence of the strongly correlated excited state signals the presence of distinct symmetries within related spin functions, serving as a precursor to the strong coupling between photons and spin-charge hybrid qubits in planar Ge. This work paves the way towards coherent quantum connections between remote hole qubits in planar Ge, required to scale up hole-based quantum processors.},
  author       = {De Palma, Franco and Oppliger, Fabian and Jang, Wonjin and Bosco, Stefano and Janik, Marian and Calcaterra, Stefano and Katsaros, Georgios and Isella, Giovanni and Loss, Daniel and Scarlino, Pasquale},
  issn         = {2041-1723},
  journal      = {Nature Communications},
  publisher    = {Springer Nature},
  title        = {{Strong hole-photon coupling in planar Ge for probing charge degree and strongly correlated states}},
  doi          = {10.1038/s41467-024-54520-7},
  volume       = {15},
  year         = {2024},
}

@article{14793,
  abstract     = {Superconductor/semiconductor hybrid devices have attracted increasing interest in the past years. Superconducting electronics aims to complement semiconductor technology, while hybrid architectures are at the forefront of new ideas such as topological superconductivity and protected qubits. In this work, we engineer the induced superconductivity in two-dimensional germanium hole gas by varying the distance between the quantum well and the aluminum. We demonstrate a hard superconducting gap and realize an electrically and flux tunable superconducting diode using a superconducting quantum interference device (SQUID). This allows to tune the current phase relation (CPR), to a regime where single Cooper pair tunneling is suppressed, creating a sin(2y) CPR. Shapiro experiments complement this interpretation and the microwave drive allows to create a diode with ≈ 100% efficiency. The reported results open up the path towards integration of spin qubit devices, microwave resonators and (protected) superconducting qubits on  the same silicon technology compatible platform.},
  author       = {Valentini, Marco and Sagi, Oliver and Baghumyan, Levon and de Gijsel, Thijs and Jung, Jason and Calcaterra, Stefano and Ballabio, Andrea and Aguilera Servin, Juan L and Aggarwal, Kushagra and Janik, Marian and Adletzberger, Thomas and Seoane Souto, Rubén and Leijnse, Martin and Danon, Jeroen and Schrade, Constantin and Bakkers, Erik and Chrastina, Daniel and Isella, Giovanni and Katsaros, Georgios},
  issn         = {2041-1723},
  journal      = {Nature Communications},
  publisher    = {Springer Nature},
  title        = {{Parity-conserving Cooper-pair transport and ideal superconducting diode in planar germanium}},
  doi          = {10.1038/s41467-023-44114-0},
  volume       = {15},
  year         = {2024},
}

@article{17202,
  abstract     = {Gate-tunable transmons (gatemons) employing semiconductor Josephson junctions have recently emerged as building blocks for hybrid quantum circuits. In this study, we present a gatemon fabricated in planar Germanium. We induce superconductivity in a two-dimensional hole gas by evaporating aluminum atop a thin spacer, which separates the superconductor from the Ge quantum well. The Josephson junction is then integrated into an Xmon circuit and capacitively coupled to a transmission line resonator. We showcase the qubit tunability in a broad frequency range with resonator and two-tone spectroscopy. Time-domain characterizations reveal energy relaxation and coherence times up to 75 ns. Our results, combined with the recent advances in the spin qubit field, pave the way towards novel hybrid and protected qubits in a group IV, CMOS-compatible material.},
  author       = {Sagi, Oliver and Crippa, Alessandro and Valentini, Marco and Janik, Marian and Baghumyan, Levon and Fabris, Giorgio and Kapoor, Lucky and Hassani, Farid and Fink, Johannes M and Calcaterra, Stefano and Chrastina, Daniel and Isella, Giovanni and Katsaros, Georgios},
  issn         = {2041-1723},
  journal      = {Nature Communications},
  publisher    = {Springer Nature},
  title        = {{A gate tunable transmon qubit in planar Ge}},
  doi          = {10.1038/s41467-024-50763-6},
  volume       = {15},
  year         = {2024},
}

@phdthesis{18129,
  abstract     = {State-of-the-art quantum computers, with roughly a thousand qubits, face a crucial technological challenge of scaling up. Spins confined in quantum dots (QDs) are a promising candidate
for qubits due to their long coherence, tunability, control, and readout. However, their natural
coupling is the short-ranged (∼ 100 nm) exchange interaction, limited to nearest neighbours.
Long-ranged (∼ 1 mm) qubit interactions mediated by a photon could be engineered through a
coherent spin-photon coupling. Achieving a strong coupling to a photon is inherently challenging in QDs due to the small dipole moment of the confined charge. However, the potential of
high-impedance resonators to compensate for this has gained significant attention in the past
decade. Nevertheless, previous QD circuit quantum electrodynamics implementations have not
exceeded the impedance of ∼ 3.8 kΩ, leaving opportunities for significant improvement. The
large kinetic inductance of granular aluminium (grAl) could provide an order-of-magnitude
enhancement. However, fully exploiting the potential of disordered or granular superconductors
is challenging as their impedances close to the superconductor-to-insulator transition are
difficult to control reproducibly. We report on the realization of a wireless ohmmeter which
allows in situ resistance measurements during film deposition and, therefore, indirect control
of the kinetic inductance of grAl films. This allows us to reproducibly fabricate resonators
with characteristic impedance exceeding the resistance quantum, even reaching 22.3 kW, due
to the large sheet kinetic inductance of up to 3 nH □−1
. By integrating an 8 kW resonator
with a germanium double QD, we demonstrate a strong charge-photon coupling with the
highest rate reported, 566 MHz. The demonstrated method and grAl properties make these
resonators suitable for boosting the spin-photon coupling strength, a crucial requirement for
fast, high-fidelity, long-distance two-qubit gates.
},
  author       = {Janik, Marian},
  issn         = {2663-337X},
  pages        = {164},
  publisher    = {Institute of Science and Technology Austria},
  title        = {{Strong charge-photon coupling in Germanium enabled by granular aluminium superinductors}},
  doi          = {10.15479/at:ista:18129},
  year         = {2024},
}

@unpublished{18144,
  abstract     = {High kinetic inductance superconductors are gaining increasing interest for
the realisation of qubits, amplifiers and detectors. Moreover, thanks to their
high impedance, quantum buses made of such materials enable large zero-point
fluctuations of the voltage, boosting the coupling rates to spin and charge
qubits. However, fully exploiting the potential of disordered or granular
superconductors is challenging, as their inductance and, therefore, impedance
at high values are difficult to control. Here we have integrated a granular
aluminium resonator, having a characteristic impedance exceeding the resistance
quantum, with a germanium double quantum dot and demonstrate strong
charge-photon coupling with a rate of $g_\text{c}/2\pi= (566 \pm 2)$ MHz. This
was achieved due to the realisation of a wireless ohmmeter, which allows
\emph{in situ} measurements during film deposition and, therefore, control of
the kinetic inductance of granular aluminium films. Reproducible fabrication of
circuits with impedances (inductances) exceeding 13 k$\Omega$ (1 nH per square)
is now possible. This broadly applicable method opens the path for novel qubits
and high-fidelity, long-distance two-qubit gates.},
  author       = {Janik, Marian and Roux, Kevin Etienne Robert and Borja Espinosa, Carla N and Sagi, Oliver and Baghdadi, Abdulhamid and Adletzberger, Thomas and Calcaterra, Stefano and Botifoll, Marc and Manjón, Alba Garzón and Arbiol, Jordi and Chrastina, Daniel and Isella, Giovanni and Pop, Ioan M. and Katsaros, Georgios},
  booktitle    = {arXiv},
  title        = {{Strong charge-photon coupling in planar germanium enabled by granular  aluminium superinductors}},
  doi          = {10.48550/arXiv.2407.03079},
  year         = {2024},
}

@unpublished{13312,
  abstract     = {Superconductor/semiconductor hybrid devices have attracted increasing
interest in the past years. Superconducting electronics aims to complement
semiconductor technology, while hybrid architectures are at the forefront of
new ideas such as topological superconductivity and protected qubits. In this
work, we engineer the induced superconductivity in two-dimensional germanium
hole gas by varying the distance between the quantum well and the aluminum. We
demonstrate a hard superconducting gap and realize an electrically and flux
tunable superconducting diode using a superconducting quantum interference
device (SQUID). This allows to tune the current phase relation (CPR), to a
regime where single Cooper pair tunneling is suppressed, creating a $ \sin
\left( 2 \varphi \right)$ CPR. Shapiro experiments complement this
interpretation and the microwave drive allows to create a diode with $ \approx
100 \%$ efficiency. The reported results open up the path towards monolithic
integration of spin qubit devices, microwave resonators and (protected)
superconducting qubits on a silicon technology compatible platform.},
  author       = {Valentini, Marco and Sagi, Oliver and Baghumyan, Levon and Gijsel, Thijs de and Jung, Jason and Calcaterra, Stefano and Ballabio, Andrea and Servin, Juan Aguilera and Aggarwal, Kushagra and Janik, Marian and Adletzberger, Thomas and Souto, Rubén Seoane and Leijnse, Martin and Danon, Jeroen and Schrade, Constantin and Bakkers, Erik and Chrastina, Daniel and Isella, Giovanni and Katsaros, Georgios},
  booktitle    = {arXiv},
  keywords     = {Mesoscale and Nanoscale Physics},
  title        = {{Radio frequency driven superconducting diode and parity conserving  Cooper pair transport in a two-dimensional germanium hole gas}},
  doi          = {10.48550/arXiv.2306.07109},
  year         = {2023},
}