All-Nitride ALD Qubits

Updated 13 November 2025

All-nitride ALD qubits are superconducting circuits where both electrodes and tunnel barriers are made from nitrides deposited with atomic precision.
The process enables precise control over barrier thickness and tunable critical current densities spanning seven orders of magnitude for robust performance.
Scalable, CMOS-compatible fabrication reduces TLS losses and supports high-performance qubits operating above 300 mK using high-Tc materials like NbN and TiN.

All-nitride atomic-layer-deposition (ALD) qubits are a class of superconducting quantum circuits in which every key layer—including both electrodes and the tunnel barrier—comprises epitaxial or amorphous nitrides, with films deposited using plasma-enhanced ALD to achieve atomically sharp interfaces and sub-nanometer thickness control. In recent implementations, such as NbN/AlN/NbN trilayer transmon architectures, the ALD technique enables scalable, CMOS-compatible fabrication with critical-current densities tuned over seven decades and coherence times retained into elevated temperature regimes (>300 mK). All-nitride ALD qubits leverage the high superconducting critical temperature ( $T_c$ ) and stability of nitrides (e.g., NbN, TiN) for robust performance, minimal two-level-system (TLS) loss, and adaptability to integration with foundry processes (Wang et al., 12 Nov 2025, Shearrow et al., 2018).

1. Atomic-Layer Deposition of All-Nitride Josephson Junctions

All-nitride ALD qubits are predicated on the conformal, cycle-based ALD process, which enables precise, uniform growth of NbN/AlN/NbN trilayer junctions. The process employs an Ultratech/Cambridge Fiji G2 plasma-enhanced ALD reactor operating at 300–400 °C, with substrate options including c-plane sapphire (for optical alignment) or Si (for CMOS compatibility). The process sequence involves:

NbN: tert-butylimido tris(diethylamido)niobium (TBTDEN) precursor, Ar carrier.
AlN: trimethylaluminum (TMA) precursor, Ar carrier.
N $_2$ /H $_2$ plasma (1:1 flow, 300 W RF) for nitridation and surface activation.
Each ALD cycle: metal precursor pulse (0.5–1 s), Ar purge (10–20 s), N $_2$ /H $_2$ plasma exposure (5 s), and a final Ar purge (10–20 s).
Trilayer geometry: bottom (25–50 nm) and top (25–50 nm) NbN films sandwiching AlN barrier layers ranging from approximately 0.5 nm to 3 nm (set by 5–40 TMA cycles, $a ≈ 0.076$ nm/cycle).
At each NbN/AlN interface, an additional 10 plasma-only cycles are used to optimize interface sharpness and reduce residual ligands.

Cross-sectional STEM analysis reveals atomically abrupt interfaces and uniform AlN barriers (e.g., 1.6 nm at 21 cycles), while atom-probe tomography confirms oxygen impurities under 5% and barrier thickness variations less than 5% in a 15 nm lateral domain. Large-scale junction arrays (100–1000 devices) exhibit consistent room-temperature resistance-area relations, implying excellent film uniformity.

2. Barrier Thickness Calibration and Critical Current Density Tuning

The number of ALD cycles controls the AlN barrier thickness $d$ according to $d ≃ a N$ with $a ≈ 0.076$ nm/cycle (e.g., 21 cycles yields $d ≈ 1.6$ nm). This parameter directly tunes the Josephson junction critical current density ( $J_c$ ):

$\log_{10} J_c~(\mathrm{A/cm^2}) = -0.34~N + 4.2$

$J_c(N) ≃ 10^{4.2}·10^{-0.34 N}~\mathrm{A/cm^2}$

or, substituting for $N = d/a$ :

$J_c(d) ≃ J_0 \exp(-\alpha d),~\text{with}~\alpha ≃ (0.34\,\ln 10)/a ≃ 3.3~\mathrm{nm}^{-1}$

This formalism allows $J_c$ to be tuned from approximately $10^3$ A/cm $^2$ ( $N \sim 5$ cycles) down to $10^{-4}$ A/cm $^2$ ( $N \sim 30$ cycles), spanning seven orders of magnitude. The resulting junction resistance-area products ( $R_n A$ ) are stable near $20.8$ k $\Omega\cdot\mu$ m $^2$ across batches.

3. Josephson Junction and Qubit Electrical Properties

ALD qubits exhibit device-level and qubit-level electrical properties consistent with high-quality Josephson junctions:

4 K DC $I$ – $V$ characteristics: gap voltages $V_g ≈ 4.2$ mV (implying $\Delta ≈ 2.1$ meV; $T_c$ (NbN) ≈ 13 K), subgap-to-normal resistance ratio $R_{sg}/R_n$ up to $\approx 55$ .
Switching current ( $I_{sw}$ ) analysis supports $J_c$ extraction via $I_c = (\pi/4) I_g$ (where $I_g$ is gap current), with $J_c = I_c / A$ ( $A = \pi D^2/4$ for a circular junction).
Josephson ( $E_J$ $E_{J}$ ) and charging ( $E_C$ $E_{C}$ ) energies,
- $E_J = \Phi_0 I_c/(2\pi)$ , $\Phi_0 = h/2e$
- $E_C = e^2/(2C_\Sigma)$ , with $C_\Sigma$ the total capacitance including the junction and shunt pads,
Transmon transition frequencies ( $f_{01}$ ) calculated as $f_{01} \approx [\sqrt{8E_J E_C} - E_C]/h$ (approximating [Koch et al., 2007]), but extracted numerically (e.g., $α/2π ≈ 223$ MHz anharmonicity).

4. Transmon Integration, Device Geometry, and Coherence Measurements

The all-nitride ALD junctions are integrated into transmon qubits using a flip-chip platform:

Q-chip (top): ALD trilayer, Josephson junction and Ti/Au bonding pads.
C-chip (bottom): NbN readout resonator, feedline, and Ti/Au pads.
Flip-chip process utilizes room-temperature gold–gold bonding with sub-5μm alignment.

Qubit capacitance is set via large shunt pads on both chips, with total energy participation $p_J = C_J / C_\Sigma$ in the range 0.2–0.8. Readout employs quarter-wave resonators with $f_c ≈ 6$ –7 GHz, qubit–resonator coupling rates $g/2π ≈ 50$ –70 MHz, and measured readout internal quality factors $Q_i ≈ (2–6)\times10^4$ at the single-photon level.

Measured qubit parameters at base temperature (10 mK) are summarized:

Qubit	D $_J$ (μm)	$p_J$	$f_q$ (GHz)	$E_J/h$ (GHz)	$E_C/h$ (GHz)	$g/2\pi$ (MHz)	$T_1$ (μs)	$T_2^*$ (μs)
A1	1.0	0.30	5.063	20.02	0.172	48.7	1.43±0.03	0.74±0.04
A2	0.8	0.20	4.089	11.79	0.196	67.5	2.87±0.07	0.65±0.04
A3	0.8	0.20	4.057	11.55	0.197	68.5	3.00±0.03	1.20±0.04
B1	2.0	0.75	3.983	11.98	0.182	49.0	2.66±0.05	0.69±0.04
B2	2.0	0.74	3.907	11.19	0.188	55.0	3.43±0.08	–

Key time-domain results include Rabi oscillations with $\Omega_R/2\pi ≈ 18$ MHz, energy relaxation times ( $T_1$ ) from $1.4$ μs to $3.4$ μs (mean $T_1 ≈ 3.0$ μs for A3), and Ramsey dephasing times ( $T_2^*$ ) of $0.65$–$1.2$ μs. Notably, microsecond-scale $T_1$ persists up to $T = 400$ mK, where $T_1$ decreases gradually according to a spin-boson model: $T_1(T) ∝ [1 + \coth({\hbar ω_q}/{2k_B T})]^{-1}$ .

5. Elevated-Temperature Performance Enabled by High- $T_c$ Nitrides

The NbN electrodes ( $T_c ≈ 13$ K; $\Delta ≈ 2.1$ meV) enable coherent qubit operation well above the temperatures accessible to conventional Al-based qubits. At $T > 300$ mK ( $k_BT ≈ 26$ μeV), the density of thermally-generated quasiparticles $n_{qp} ∝ \exp(-\Delta / k_B T)$ remains negligible, ensuring that $T_1$ remains in the sub-microsecond to microsecond regime at $T=310$ –$400$ mK. This represents a significant relaxation of cryogenic cooling requirements in quantum processors, contrasting with Al-based circuits, where $T_1$ rapidly degrades above $\sim200$ mK.

6. Process Scalability, Foundry Integration, and Loss Mechanisms

ALD processes provide wafer-scale, conformal deposition with angstrom-level thickness controllability, directly translating to $J_c$ -spread below 5% across 100 mm wafers. The approach is compatible with CMOS back-end and photolithography techniques suitable for 0.8 μm junctions and below (193 nm immersion). Flip-chip architectures separate the qubit and wiring optimizations, avoid lossy sidewall spacers, reduce TLS participation by eliminating amorphous AlO $_x$ , and use a PECVD-free backend.

Intrinsic losses are subordinate to extrinsic packaging and surface oxides, with current loss analyses showing:

Subgap conduction-limited $Q_{JJ}>5\times 10^5$
Gold-bond loss $Q_{Au}>3\times 10^6$
AlN piezo loss $Q>10^5$
Qubit quality factors $Q_q = 4$ – $9\times 10^4$

This suggests that the ALD nitride stack and flip-chip process do not fundamentally limit coherence; rather, further improvement is expected as foundry process integration and surface-passivating strategies mature.

7. All-Nitride ALD Qubits in Context: Comparison and Future Prospects

Titanium nitride (TiN) grown by ALD further extends all-nitride strategies to quantum resonators and kinetic inductors, with demonstrated sheet kinetic inductance $L_s$ up to $234$ pH/□ (for $t=8.9$ nm), internal quality factors $Q_i ≈ 0.4$ –$1.0$ million for $t \geq 14$ nm, and characteristic impedances $Z_c$ up to 28 kΩ (Shearrow et al., 2018). In hybrid and protected qubit applications, these properties increase photon-qubit/spin coupling by a factor of 24 compared to 50 Ω architectures. Limitations from surface oxides and TLSs, along with etch and substrate treatments, remain key optimization areas.

A plausible implication is that all-nitride ALD techniques, encompassing both NbN/AlN and TiN nanoscale films, define a technological basis for scalable, high-coherence qubits compatible with elevated temperature operation and industrial foundry practices, providing routes to large-scale quantum processors with relaxed cryogenic requirements and robust materials engineering.

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References (2)

All-nitride superconducting qubits based on atomic layer deposition (2025)

Atomic layer deposition of titanium nitride for quantum circuits (2018)

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