Showing papers by "Irina V. Grigorieva published in 2021"

Quantum Rescaling, Domain Metastability, and Hybrid Domain‐Walls in 2D CrI 3 Magnets

Abstract: Higher-order exchange interactions and quantum effects are widely known to play an important role in describing the properties of low-dimensional magnetic compounds. Here, the recently discovered 2D van der Waals (vdW) CrI3 is identified as a quantum non-Heisenberg material with properties far beyond an Ising magnet as initially assumed. It is found that biquadratic exchange interactions are essential to quantitatively describe the magnetism of CrI3 but quantum rescaling corrections are required to reproduce its thermal properties. The quantum nature of the heat bath represented by discrete electron-spin and phonon-spin scattering processes induces the formation of spin fluctuations in the low-temperature regime. These fluctuations induce the formation of metastable magnetic domains evolving into a single macroscopic magnetization or even a monodomain over surface areas of a few micrometers. Such domains display hybrid characteristics of Neel and Bloch types with a narrow domain wall width in the range of 3-5 nm. Similar behavior is expected for the majority of 2D vdW magnets where higher-order exchange interactions are appreciable.

Single-Nucleus RNA Sequencing Identifies New Classes of Proximal Tubular Epithelial Cells in Kidney Fibrosis.

Abstract: Background Proximal tubular cells (PTCs) are the most abundant cell type in the kidney. PTCs are central to normal kidney function and to regeneration versus organ fibrosis following injury. This study used single-nucleus RNA sequencing (snRNA-seq) to describe the phenotype of PTCs in renal fibrosis. Methods Kidneys were harvested from naive mice and from mice with renal fibrosis induced by chronic aristolochic acid administration. Nuclei were isolated using Nuclei EZ Lysis buffer. Libraries were prepared on the 10X platform and snRNA-seq completed using the Illumina NextSeq 550 System. Genome mapping was carried out with high-performance computing. Results A total of 23,885 nuclei were analysed. PTCs were found in five abundant clusters, mapping to S1, S1-2, S2, S2-cortical S3, and medullary S3 segments. Additional cell clusters ("new PTC clusters") were at low abundance in normal kidney and in increased number in kidneys undergoing regeneration/fibrosis following injury. These clusters exhibited clear molecular phenotypes, permitting labelling as proliferating, New-PT1, New-PT2, and (present only following injury) New-PT3. Each cluster exhibited a unique gene expression signature, including multiple genes previously associated with renal injury response and fibrosis progression. Comprehensive pathway analyses revealed metabolic reprogramming, enrichment of cellular communication and cell motility, and various immune activations in new PTC clusters. In ligand-receptor analysis, new PTC clusters promoted fibrotic signaling to fibroblasts and inflammatory activation to macrophages. Conclusion These data identify unrecognized PTC phenotype heterogeneity and reveal novel PTCs associated with kidney fibrosis.

Out-of-equilibrium criticalities in graphene superlattices

Abstract: In thermodynamic equilibrium, current in metallic systems is carried by electronic states near the Fermi energy whereas the filled bands underneath contribute little to conduction. Here we describe a very different regime in which carrier distribution in graphene and its superlattices is shifted so far from equilibrium that the filled bands start playing an essential role, leading to a critical-current behavior. The criticalities develop upon the velocity of electron flow reaching the Fermi velocity. Key signatures of the out-of-equilibrium state are current-voltage characteristics resembling those of superconductors, sharp peaks in differential resistance, sign reversal of the Hall effect, and a marked anomaly caused by the Schwinger-like production of hot electron-hole plasma. The observed behavior is expected to be common for all graphene-based superlattices.

Exponentially selective molecular sieving through angstrom pores

Abstract: Two-dimensional crystals with angstrom-scale pores are widely considered as candidates for a next generation of molecular separation technologies aiming to provide extreme selectivity combined with high flow rates. Here we study gas transport through individual graphene pores with an effective diameter of about 2 angstroms, or about one missing carbon ring, which are created reproducibly by a short-time exposure to a low-kV electron beam. Helium and hydrogen permeate easily through these pores whereas larger molecules such as xenon and methane are blocked. Permeating gases experience activation barriers that increase quadratically with the kinetic diameter, and the transport process crucially involves surface adsorption. Our results reveal underlying mechanisms for the long sought-after exponential selectivity and suggest the bounds on possible performance of porous two-dimensional membranes.

Tunable spin-orbit coupling in two-dimensional InSe

Abstract: We demonstrate that spin-orbit coupling (SOC) strength for electrons near the conduction band edge in few-layer $\ensuremath{\gamma}$-InSe films can be tuned over a wide range. This tunability is the result of a competition between film-thickness-dependent intrinsic and electric-field-induced SOC, potentially, allowing for electrically switchable spintronic devices. Using a hybrid $\mathbf{k}\ifmmode\cdot\else\textperiodcentered\fi{}\mathbf{p}$ tight-binding model, fully parametrized with the help of density functional theory computations, we quantify SOC strength for various geometries of InSe-based field-effect transistors. The theoretically computed SOC strengths are compared with the results of weak antilocalization measurements on dual-gated multilayer InSe films, interpreted in terms of Dyakonov-Perel spin relaxation due to SOC, showing a good agreement between theory and experiment.

Enhanced spin injection in molecularly functionalized graphene via ultra-thin oxide barriers

Abstract: Realisation of practical spintronic devices relies on the ability to create and detect pure spin currents In graphene-based spin valves this is usually achieved by injection of spin-polarized electrons from ferromagnetic contacts via a tunnel barrier, with Al2O3 and MgO used most widely as barrier materials However, the requirement to make these barriers sufficiently thin often leads to pinholes and low contact resistances which in turn results in low spin injection efficiencies, typically 5% at room temperature, due to the so-called resistance mismatch problem Here we demonstrate an alternative approach to fabricate ultra-thin tunnel barrier contacts to graphene We show that laser-assisted chemical functionalization of graphene with sp3-bonded phenyl groups effectively provides a seed layer for growth of ultrathin Al2O3 films, ensuring smooth, high quality tunnel barriers and an enhanced spin injection efficiency Importantly, the effect of functionalization on spin transport in the graphene channel itself is relatively weak, so that the enhanced spin injection dominates and leads to an order of magnitude increase in spin signals Furthermore, spatial control of functionalization using a focused laser beam and lithographic techniques can in principle be used to limit functionalization to contact areas only, further reducing the effect on the graphene channel Our results open a new route towards circumventing the resistance mismatch problem in graphene-based spintronic devices based on the easily available and highly stable Al2O3, and facilitate a step forward in the development of their practical applications

Hypoxia stimulates angiogenesis and a metabolic switch in human parathyroid adenoma cells

Abstract: Hypoxia, a primary stimulus for angiogenesis, is important for tumour proliferation and survival. The effects of hypoxia on parathyroid tumour cells, which may also be important for parathyroid autotransplantation in patients, are, however, unknown. We, therefore, assessed the effects of hypoxia on gene expression in parathyroid adenoma (PA) cells from patients with primary hyperparathyroidism. Cell suspensions from human PAs were cultured under normoxic or hypoxic conditions and then subjected to cDNA expression analysis. In total, 549 genes were significantly upregulated and 873 significantly downregulated. The most highly upregulated genes (carbonic anhydrase 9 (CA9), Solute carrier family 2A1 (SLC2A1) and hypoxia-inducible lipid droplet-associated protein (HIG2)) had known involvement in hypoxia responses. Dysregulation of oxidative phosphorylation and glycolysis pathway genes were also observed, consistent with data indicating that cells shift metabolic strategy of ATP production in hypoxic conditions and that tumour cells predominantly utilise anaerobic glycolysis for energy production. Proliferation- and angiogenesis-associated genes linked with growth factor signalling, such as mitogen-activated protein kinase kinase 1 (MAP2K1), Jun proto-oncogene (JUN) and ETS proto-oncogene 1 (ETS1), were increased, however, Ras association domain family member 1 (RASSF1), an inhibitor of proliferation was also upregulated, indicating these pathways are unlikely to be biased towards proliferation. Overall, there appeared to be a shift in growth factor signalling pathways from Jak-Stat and Ras signaling to extracellular signal-regulated kinases (ERKs) and hypoxia-inducible factor (HIF)-1α signalling. Thus, our data demonstrate that PAs, under hypoxic conditions, promote the expression of genes known to stimulate angiogenesis, as well as undergoing a metabolic switch.

Tuneable spin injection in high-quality graphene with one-dimensional contacts

Abstract: Spintronics involves the development of low-dimensional electronic systems that support the creation and control of spin transport, with potential use in quantum-based computation. To advance these efforts structures that support spin transport while enabling high-quality electronic transport are desired, with graphene being an ideal platform to contribute towards this goal. There has been significant progress in improving spin transport characteristics, e.g. by encapsulation and reducing impurities in graphene, but the influence of standard two-dimensional (2D) tunnel contacts, such as pinholes and unintentional doping leading to non-uniformity in the graphene channel, remains difficult to eliminate. Here, we report the observation of efficient spin injection and tuneable spin signal in high-quality and fully-encapsulated graphene, enabled by van der Waals heterostructures with one-dimensional (1D) contacts. This architecture prevents significant doping from the contacts within the graphene channel, allowing the ability to routinely achieve high-quality channels, currently with mobilities up to 130,000 cm2V-1s-1 and spin diffusion lengths approaching 20 micrometer. Despite the direct contact between the ferromagnetic metal and graphene, the nanoscale-wide 1D contacts offer a sizeable contact resistance, allowing spin injection both at room and at low temperature, with the latter exhibiting spin injection efficiency comparable with standard 2D tunnel contacts. Furthermore, owing to gate tuneability of the 1D contacts' resistance at low temperature, the observed spin signals can be enhanced by as much as an order of magnitude by p-doping of the graphene channel, adding new functionality to the device performance.

Enhanced Spin Injection in Molecularly Functionalized Graphene via Ultrathin Oxide Barriers

Abstract: The realization of practical spintronic devices relies on the ability to create and detect pure spin currents. In graphene-based spin valves, this is usually achieved by the injection of spin-polarized electrons from ferromagnetic contacts via a tunnel barrier, with ${\mathrm{Al}}_{2}{\mathrm{O}}_{3}$ and $\mathrm{Mg}\mathrm{O}$ used most widely as barrier materials. However, the requirement to make these barriers sufficiently thin often leads to pinholes and low contact resistances, which, in turn, results in low spin-injection efficiencies, typically 5% at room temperature, due to the so-called resistance mismatch problem. Here, we demonstrate an alternative approach to fabricate ultrathin tunnel-barrier contacts to graphene. We show that laser-assisted chemical functionalization of graphene with $s{p}^{3}$-bonded phenyl groups effectively provides a seed layer for the growth of ultrathin ${\mathrm{Al}}_{2}{\mathrm{O}}_{3}$ films, ensuring smooth high-quality tunnel barriers and an enhanced spin-injection efficiency. Importantly, the effect of functionalization on spin transport in the graphene channel itself is relatively weak, so that the enhanced spin injection dominates and leads to an order of magnitude increase in spin signals. Furthermore, the spatial control of functionalization using a focused laser beam and lithographic techniques can, in principle, be used to limit functionalization to contact areas only, further reducing the effect on the graphene channel. Our results open a route towards circumventing the resistance mismatch problem in graphene-based spintronic devices based on easily available and highly stable ${\mathrm{Al}}_{2}{\mathrm{O}}_{3}$ and facilitate a step forward in the development of their practical applications.

Magnetization signature of topological surface states in a non-symmorphic superconductor.

Abstract: Superconductors with nontrivial band structure topology represent a class of materials with unconventional and potentially useful properties. Recent years have seen much success in creating artificial hybrid structures exhibiting main characteristics of two-dimensional (2D) topological superconductors. Yet, bulk materials known to combine inherent superconductivity with nontrivial topology remain scarce, largely because distinguishing their central characteristic -- topological surface states -- proved challenging due to a dominant contribution from the superconducting bulk. Reported here is a highly anomalous behaviour of surface superconductivity in topologically nontrivial 3D superconductor In2Bi where the surface states result from its nontrivial band structure, which itself is a consequence of the non-symmorphic crystal symmetry and strong spin-orbit coupling. In contrast to smoothly decreasing diamagnetic susceptibility above the bulk critical field Hc2, associated with surface superconductivity in conventional superconductors, we observe near-perfect, Meissner-like screening of low-frequency magnetic fields well above Hc2. The enhanced diamagnetism disappears at a new phase transition close to the critical field of surface superconductivity Hc3. Using theoretical modelling, we show that the anomalous screening is consistent with modification of surface superconductivity due to the presence of topological surface states. The demonstrated possibility to detect signatures of the surface states using macroscopic magnetization measurements provides an important new tool for discovery and identification of topological superconductors.

Magnetization Signature of Topological Surface States in a Non-Symmorphic Superconductor.

Abstract: Superconductors with nontrivial band structure topology represent a class of materials with unconventional and potentially useful properties. Recent years have seen much success in creating artificial hybrid structures exhibiting the main characteristics of 2D topological superconductors. Yet, bulk materials known to combine inherent superconductivity with nontrivial topology remain scarce, largely because distinguishing their central characteristic-the topological surface states-has proved challenging due to a dominant contribution from the superconducting bulk. In this work, a highly anomalous behavior of surface superconductivity in topologically nontrivial 3D superconductor In2 Bi, where the surface states result from its nontrivial band structure, itself a consequence of the non-symmorphic crystal symmetry and strong spin-orbit coupling, is reported. In contrast to smoothly decreasing diamagnetic susceptibility above the bulk critical field, Hc2 , as seen in conventional superconductors, a near-perfect, Meissner-like screening of low-frequency magnetic fields well above Hc2 is observed. The enhanced diamagnetism disappears at a new phase transition close to the critical field of surface superconductivity, Hc3 . Using theoretical modeling, the anomalous screening is shown to be consistent with modification of surface superconductivity by the topological surface states. The possibility of detecting signatures of the surface states using macroscopic magnetization provides a new tool for the discovery and identification of topological superconductors.