This study describes the successful upgrade of a mechanically pumped CO2 two-phase cooling system in space by designing a new pump module for the Alpha Magnetic Spectrometer-02 on the International ...Space Station. Key factors for mission success are emphasized, including achieving high coolant filling accuracy within 10% of the target and maintaining system stability within ±1 °C. The impact of adding radiators to improve cooling efficiency is examined, and it is found that operating multi-radiators out-of-phase does not significantly affect system reliability. The centrifugal pump design is shown to allow for better lubricant circulation, while the in-house designed controller incorporates protective measures to prevent cavitation, overheating, and over-current. This research advances the understanding of circulation loop systems and their upgrades in space and demonstrates the potential for extending the lifetime of space-borne mechanically pumped two-phase cooling systems.
•First in-space upgrade of a pumped two-phase cooling system.•Quantitative on-orbit fluid transfer achieves 7% accuracy.•Superior system control stability of 1 °C with multiple out-f-phase radiators.•Prolonged mechanical pump lifetime via hardware and software manners.
Abstract
Harnessing the spin–momentum locking of topological surface states in conjunction with magnetic materials is the first step to realize novel topological insulator-based devices. Here, we ...report strong interfacial coupling in Bi
2
Se
3
/yttrium iron garnet (YIG) bilayers manifested as large interfacial in-plane magnetic anisotropy (IMA) and enhancement of damping probed by ferromagnetic resonance. The interfacial IMA and damping enhancement reaches a maximum when the Bi
2
Se
3
film approaches its two-dimensional limit, indicating that topological surface states play an important role in the magnetization dynamics of YIG. Temperature-dependent ferromagnetic resonance of Bi
2
Se
3
/YIG reveals signatures of the magnetic proximity effect of
T
C
as high as 180 K, an emerging low-temperature perpendicular magnetic anisotropy competing the high-temperature IMA, and an increasing exchange effective field of YIG steadily increasing toward low temperature. Our study sheds light on the effects of topological insulators on magnetization dynamics, essential for the development of topological insulator-based spintronic devices.
•Invention of metal MBE for magnetic superlattices in pioneering spintronics research.•A shutter-less method in growing composition-gradient DBRs with reduced resistance.•Combined oxide/semiconductor ...MBE for first Fermi level unpinning in GaAs MOS.•Integrating MBE/ALD/analysis via UHV for high-performance MOS and topological matters.•Understanding (In)GaAs surfaces and interfaces with high-κ and metal by in-situ SRPES.
Molecular beam epitaxy (MBE) invented for the growth of compound semiconductors in the 70’s has been successfully extended to the advanced growth of metals, oxides, oxide/semiconductor interfaces and emergent topological materials by our endeavor in the past three and half decades. In the 80’s, Kwo et al. have invented metal MBE and oxide MBE methods in pioneering spintronics and high-temperature superconducting oxide films. In driving compound semiconductors for optoelectronics, Hong et al. have produced distributed Bragg reflectors with a continuously graded composition between each constituent without shutter operation, and greatly reduced the electrical resistance; this simple method has made easy manufacture of vertical-cavity surface-emitting lasers. In the 90’s, combining (In)GaAs and oxide MBE chambers via ultra-high vacuum, Hong et al. were the first to unpin the Fermi level in oxide/GaAs, which led to the first demonstration of inversion-channel (In)GaAs metal-oxide-semiconductor (MOS) field-effect transistors (MOSFETs). Integrating MBE, atomic layer deposition (ALD), and many other functions in ultra-high vacuum, advances have been made in pushing ultimate complementary MOS (CMOS) of record-high device performances and beyond in growing emergent topological materials for spintronics. Our novel method in preserving as-grown (In)GaAs surfaces and interfaces with high-κ oxides and metals enables employing in-situ synchrotron radiation photoemission to study electronic structures in an atomic scale.
Thulium iron garnet (TmIG) films with perpendicular magnetic anisotropy (PMA) were grown on gadolinium gallium garnet (GGG) (111) substrates by off-axis sputtering. High-resolution synchrotron ...radiation X-ray diffraction studies and spherical aberration-corrected scanning transmission electron microscope (Cs-corrected STEM) images showed the excellent crystallinity of the films and their sharp interface with GGG. Damping constant of TmIG thin film was determined to be 0.0133 by frequency-dependent ferromagnetic resonance (FMR) measurements. The saturation magnetization (M
) and the coercive field (H
) were obtained systematically as a function of the longitudinal distance (L) between the sputtering target and the substrate. A 170% enhancement of PMA field (H
) was achieved by tuning the film composition to increase the tensile strain. Moreover, current-induced magnetization switching on a Pt/TmIG structure was demonstrated with an ultra-low critical current density (j
) of 2.5 × 10
A/cm
, an order of magnitude smaller than the previously reported value. We were able to tune M
, H
and H
to obtain an ultra-low j
of switching the magnetization, showing the great potential of sputtered TmIG films for spintronics.
High-quality single-crystal thulium iron garnet (TmIG) films of 10-30 nm thick were grown by off-axis sputtering at room temperature (RT) followed by post-annealing. X-ray photoelectron spectroscopy ...(XPS) was employed to determine the TmIG film composition to optimize the growth conditions, along with the aid of x-ray diffraction (XRD) structural analysis and atomic force microscope (AFM) for surface morphology. The optimized films exhibited perpendicular magnetic anisotropy (PMA) and the saturation magnetization at RT was ∼99 emu/cm3, close to the RT bulk value ∼110 emu/cm3 with a very low coercive field of ∼2.4 Oe. We extracted the
H
⊥
of 1734 Oe and the peak-to-peak linewidth ΔH of ferromagnetic resonance are only about 99 Oe, significantly lower than that of PLD grown TmIG film and bulk single crystals. The high-quality sputtered single-crystal TmIG films show great potential to be integrated with topological insulators or heavy metals with strong spin-orbit coupling for spintronic applications.
Transport signatures of exchange gap opening because of magnetic proximity effect (MPE) are reported for bilayer structures of Bi2Se3 thin films on yttrium iron garnet (YIG) and thulium iron garnet ...(TmIG) of perpendicular magnetic anisotropy (PMA). Pronounced negative magnetoresistance (MR) was detected, and attributed to an emergent weak localization (WL) effect superimposing on a weak antilocalization (WAL). Thickness-dependent study shows that the WL originates from the time-reversal-symmetry breaking of topological surface states by interfacial exchange coupling. The weight of WL declined when the interfacial magnetization was aligned toward the in-plane direction, which is understood as the effect of tuning the exchange gap size by varying the perpendicular magnetization component. Importantly, magnetotransport study revealed anomalous Hall effect (AHE) of square loops and anisotropic magnetoresistance (AMR) characteristic, typifying a ferromagnetic conductor in Bi2Se3/TmIG, and the presence of an interfacial ferromagnetism driven by MPE. Coexistence of MPE-induced ferromagnetism and the finite exchange gap provides an opportunity of realizing zero magnetic-field dissipation-less transport in topological insulator/ferromagnetic insulator heterostructures.
The electronic structure of single-crystal (In)GaAs deposited with tri-methylaluminum (TMA) and water via atomic layer deposition (ALD) is presented with high-resolution synchrotron radiation ...core-level photoemission and capacitance-voltage (CV) characteristics. The interaction of the precursor atoms with (In)GaAs is confined at the topmost surface layer. The Ga-vacant site on the GaAs(111)A-2 × 2 surface is filled with Al, thereby effectively passivating the As dangling bonds. The As-As dimers on the GaAs(001)-2 × 4 surface are entirely passivated by one cycle of TMA and water. The presumed layerwise deposition fails to happen in GaAs(001)-4 × 6. In In0.20Ga0.80As(001)-2 × 4, the edge row As atoms are partially bonded with the Al, and one released methyl then bonds with the In. It is suggested that the unpassivated surface and subsurface atoms cause large frequency dispersions in CV characteristics under the gate bias. We also found that the (In)GaAs surface is immune to water in ALD. However, the momentary exposure of it to air (less than one minute) introduces significant signals of native oxides. This indicates the necessity of in situ works of high κ (In)GaAs-related experiments in order to know the precise interfacial atomic bonding and thus know the electronic characteristics. The electric CV measurements of the ALD-Al2O3 on these (In)GaAs surfaces are correlated with their electronic properties.
Glass ionomers have been used for perforation repair and retrograde filling where biointegration with periodontal tissue is required. Collagen has been demonstrated to promote cellular adhesion and ...enhance mineral tissue compressive strength. It was hypothesized that an appropriate concentration of collagen integrated into glass ionomer may improve both bio-compatibility and the mechanical properties of the material. By SEM and AFM, we discovered 70-nm granules appearing on the surfaces of glass-ionomer/collagen hybrids. Acid-etching revealed irregularly shaped particles interlinked by membrane-like sheets on the surface of the material with the typical 70-nm granules. WST-1 assay showed that acid-etching significantly enhanced the viability of attached gingival fibroblasts. However, the glass-ionomer/collagen hybrids’ combined surface-etching outperformed other groups. The glass-ionomer/collagen hybrids presented enhanced compressive strength when integrated with 0.01% collagen, while higher concentrations of collagen compromised their mechanical property. In summary, collagen improved both the mechanical and biocompatible properties of glass ionomers. Further in vivo study is warranted.
The Prototype Synchrotron Radiation Detector (PSRD) Anderhub, H; Baetzner, D; Baumgartner, S ...
Nuclear instruments & methods in physics research. Section A, Accelerators, spectrometers, detectors and associated equipment,
02/2002, Letnik:
478, Številka:
1
Journal Article
Recenzirano
The components of the PSRD, a detector to study the flux of X-rays and charged particles in the keV–MeV energy range in outer space, are described. The device is a precursor for the Synchrotron ...Radiation Detector, which is one of the detector components of the Alpha Magnetic Spectrometer (AMS02). The AMS02 will be operated for several years on the International Space Station.