M. Lucas scite author profile

In the metallic magnet Nb1−yFe2+y, the low temperature threshold of ferromagnetism can be investigated by varying the Fe excess y within a narrow homogeneity range. We use elastic neutron scattering to track the evolution of magnetic order from Fe-rich, ferromagnetic Nb0.981Fe2.019 to approximately stoichiometric NbFe2, in which we can, for the first time, resolve a long-wavelength spin density wave state. The associated ordering wavevector qSDW =(0,0,lSDW) is found to depend significantly on y and T , staying finite but decreasing as the ferromagnetic state is approached.The results indicate that the interplay between FM and SDW order in NbFe2 is consistent with the theoretically predicted scenario of a hidden ferromagnetic quantum critical point, which is masked by emerging modulated magnetic order.

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Cooling low-dimensional electron systems into the microkelvin regime

Levitin

Vliet

Theisen

et al. 2022

Nat Commun

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Two-dimensional electron gases (2DEGs) with high mobility, engineered in semiconductor heterostructures host a variety of ordered phases arising from strong correlations, which emerge at sufficiently low temperatures. The 2DEG can be further controlled by surface gates to create quasi-one dimensional systems, with potential spintronic applications. Here we address the long-standing challenge of cooling such electrons to below 1 mK, potentially important for identification of topological phases and spin correlated states. The 2DEG device was immersed in liquid 3He, cooled by the nuclear adiabatic demagnetization of copper. The temperature of the 2D electrons was inferred from the electronic noise in a gold wire, connected to the 2DEG by a metallic ohmic contact. With effective screening and filtering, we demonstrate a temperature of 0.9 ± 0.1 mK, with scope for significant further improvement. This platform is a key technological step, paving the way to observing new quantum phenomena, and developing new generations of nanoelectronic devices exploiting correlated electron states.

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Quantum bath suppression in a superconducting circuit by immersion cooling

et al. 2023

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Quantum circuits interact with the environment via several temperature-dependent degrees of freedom. Multiple experiments to-date have shown that most properties of superconducting devices appear to plateau out at T ≈ 50 mK – far above the refrigerator base temperature. This is for example reflected in the thermal state population of qubits, in excess numbers of quasiparticles, and polarisation of surface spins – factors contributing to reduced coherence. We demonstrate how to remove this thermal constraint by operating a circuit immersed in liquid 3He. This allows to efficiently cool the decohering environment of a superconducting resonator, and we see a continuous change in measured physical quantities down to previously unexplored sub-mK temperatures. The 3He acts as a heat sink which increases the energy relaxation rate of the quantum bath coupled to the circuit a thousand times, yet the suppressed bath does not introduce additional circuit losses or noise. Such quantum bath suppression can reduce decoherence in quantum circuits and opens a route for both thermal and coherence management in quantum processors.

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High-Performance Cryogen-Free Platform for Microkelvin-Range Refrigeration

et al. 2022

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High performance cryogen-free microkelvin platform

Nyéki¹,

Lucas²,

Knappová³

et al. 2022

Preprint

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M. Lucas

Ultrasmall Moment Incommensurate Spin Density Wave Order Masking a Ferromagnetic Quantum Critical Point in NbFe2

Cooling low-dimensional electron systems into the microkelvin regime

Quantum bath suppression in a superconducting circuit by immersion cooling

High-Performance Cryogen-Free Platform for Microkelvin-Range Refrigeration

High performance cryogen-free microkelvin platform

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