We present a flip-chip architecture for an array of coupled superconducting qubits, in which circuit components reside inside individual microwave enclosures. In contrast to other flip-chip approaches, the qubit chips in our architecture are electrically floating, which guarantees a simple, fully modular assembly of capacitively coupled circuit components, such as qubit, control, and coupling structures

Wide bandgap metal compound-based carrier-selective contacts have been intensively investigated for crystalline silicon (c-Si) solar cells. In this work, we develop the electron-selective contact tantalum oxynitride (TaOxNy) deposited via magnetron sputtering. The effect of deposition parameters (N2 concentration, power, and pressure) on the optoelectronic properties of TaOxNy is investigated. The

Miniature atomic clocks based on the interrogation of the ground state hyperfine splitting of buffer gas cooled ions confined in radio frequency Paul traps have shown great promise as high precision prototype clocks. We report on the performance of two miniature ion trap vacuum packages after being sealed for as much as 10 years. We find the lifetime of the ions within the trap has increased over time

The discovery of spin current generation through an additional ferromagnetic layer has unlocked new possibilities for spin–orbit torque (SOT) devices, particularly in tri-layer SOT configurations. This breakthrough facilitates field-free switching (FFS) with perpendicular magnetic anisotropy (PMA) under the influence of z-polarization. Despite this progress, a significant challenge persists in lowering

Enhancing the energy density of flexible asymmetric supercapacitors (ASCs) necessitates developing and implementing high-performance anode materials for technological developments in wearable energy storage systems. Tungsten nitride (W2N) offers enormous potential as an anode material for ASCs, ascribed to its substantial specific capacitance, massive electrical conductivity, and extended negative

The carrier-envelope phase (CEP) is a key parameter for attosecond waveform control of ultrashort laser pulses. For laser systems with high repetition rates, however, single-shot CEP detection is still challenging. Building on recent findings on phase detection with electric current generation in gases, we show that with an optimized detection method, a long-term stable single-shot phase detection

The precise identification of the optical anisotropy principal axis and the controlled modulation of optical anisotropy in low-dimensional semiconductor materials are critical for advancing polarization optoelectronic devices. This paper introduces an enhanced reflectance difference spectroscopy imaging technique that can simultaneously determine the optical anisotropy principal axis of ReSe2 across

The existence of random media is challenging in optical imaging, as the existing approaches usually cannot work well when the optical channel exhibits a certain level of randomness. Here, we report an automated adaptive correction scheme for single-pixel imaging through random media. An alternating projection method is developed to reconstruct an object from light intensities recorded by a single-pixel

The detection and portable monitoring of organic amine is necessary for hazardous substance warning, life, and health. Herein, capsule-like tungsten oxide nanoparticles (NPs) were prepared to detect triethylamine, and the gas-sensing property is further enhanced by adjusting oxygen vacancy and band structure by doping tungsten oxide with Ag NPs. As-prepared nanomaterial consists of well-dispersed nanoparticles

In this work, we report a magnonic device capable of dynamic control over magnon propagation. By leveraging voltage-controlled magnetic anisotropy on yttrium iron garnet waveguides, we have carried out simulations of an active demultiplexer and half-adder designed using inverse design principles. A high output intensity multiplexer was similarly developed via inverse design to mitigate the magnon re-emission

We utilize ultrafast time-resolved pump-probe spectroscopy to investigate photoinduced quasiparticle dynamics in the topological materials LaSbTe and CeSbTe. Our results reveal that the relaxation dynamics in both materials are characterized by two distinct decay channels. In LaSbTe, the amplitude of the photoinduced reflectivity related to the first decay channel exhibits two pronounced peaks at 163

Silicon holds significant potential as a material for future quantum processors. Transistors built in silicon-on-insulator technology and functioning as silicon qubit devices can be fabricated using industry-standard processes, allowing for easy integration with classical control hardware. However, achieving precise management of carrier transfer within the transistor channel is essential, requiring

In this paper, we report a high endurance and low coercive voltage (Vc) ferroelectric tunnel junction (FTJ) device by replacing the TiN top electrode with W electrode after annealing. This method implants a TiNOx thin layer, which reduces leakage current and increases breakdown voltage (Vbd), leading to better device endurance. It can also effectively promote the formation of orthogonal phase and inhibit

The electrical resistance change of a device when subjected to applied magnetic fields is essential for magnetoresistive magnetometers as well as for studying fundamental transport phenomena in condensed matter. One of the largest magnetoresistances at room temperature is observed in extraordinary magnetoresistance (EMR) devices composed of high-mobility materials with metal inclusions. However, the

Dielectric crystals, despite their rich optical properties and great potential in integrated optoelectronics, had generally fallen behind the competing photonic platforms, mainly due to the significant difficulties of material processing. By combining the unique capabilities of ion implantation in photosensitization and femtosecond laser direct writing (FsLDW) in nanostructuring, in this study, we

The half-Heusler TiNiSn alloy is a promising candidate for thermoelectric power generation, capable of directly converting waste heat into electric power, due to its high thermoelectric performance over a wide temperature range from 500 to 1000 K. However, the thermoelectric performance of p-type TiNiSn is much lower than that of its n-type counterpart. Here, we demonstrate that Hf substitution in

Hexagonal boron nitride (h-BN) and aluminum nitride (AlN) are highly suitable for the development of flexible nitride-based ultraviolet devices. However, there are limited reports on the integration of high-quality h-BN within III-nitride systems. We have fabricated thickness-controllable h-BN on a step-flow AlN template using a two-step growth method through metalorganic chemical vapor deposition

Single-pixel imaging, which is recognized for its high sensitivity and wide spectral range, has a great potential for development in many fields. However, noise from ambient light and detector poses great challenges to its application. In this work, we present a phase-locked single pixel imaging (PL-SPI) technique that uses a lock-in amplifier (LIA) as detector. With the assistance of tunable illumination

Utilizing 2D layered semiconductor as ultrafast photoacoustic transducer, we all-optically generate and track the propagation of picosecond acoustic pulses in 2D layered semiconductor/PMMA thin-film heterostructure via femtosecond laser pump-probe. By varying the environmental temperatures and the incident direction of pump laser pulse, the acoustic velocity of PMMA thin-film has been in situ monitored

With the development of two-dimensional (2D) magnetic materials, the magneto-optical Kerr effect (MOKE) is widely used to measure ferromagnetism in 2D systems. Although this effect is usually inactive in antiferromagnets (AFM), recent theoretical studies have demonstrated that the presence of MOKE relies on the symmetry of the system and antiferromagnets with noncollinear magnetic order can also induce

Microwave impedance microscopy (MIM) is an emerging scanning probe technique that allows non-contact measurement of local linear complex permittivity with nanometer spatial resolution. In this work, we extend traditional MIM to nonlinear operation to probe local electrical nonlinearity. We develop a quantitative framework relating the multi-harmonic MIM signals to nonlinear tip–sample admittance using

This study proposes and experimentally validates a multilayer composite acoustic absorber based on ultra-microperforated panels with a dual-gradient configuration, incorporating decreasing pore diameters and perforation ratios across multiple layers. The innovative design achieves ultra-broadband, wide-angle, and near-perfect sound absorption, with absorption coefficients exceeding 0.98 over a wide

We explore the transport characteristics of a graphene–MoS2 heterostructure transistor in the low carrier density regime at cryogenic temperatures, specifically between 30 and 50 K. The device exhibits persistent current oscillations between two distinct levels, which we attribute to the trapping and de-trapping of charge carriers in defect states within the forbidden bandgap. These oscillations show

The electrocaloric effect (ECE)-induced temperature change (ΔT) in (Ba, Sr)TiO3-based ferroelectrics under unipolar electric fields was analyzed from the separate contributions of the dielectric constant (ε) and remanent polarization (Pr) based on the Maxwell relation. Consideration of the contributions of both ε and Pr is particularly important in a unipolar electric field operation, such as on/off

The Rydberg atomic communication antenna exhibits exceptional properties superior to traditional antennas. The use of heterodyne technology further establishes a foundation for high-precision digital communication. However, current signal solvers limit its application in integrated radar-communication systems. To address this, we propose a multi-parameter mapping model between Rydberg heterodyne communication

Achieving laser-induced periodic surface structures with both excellent regularity and high tunability is a challenging task. In this study, we address this challenge by utilizing a hybrid film structure, comprising an amorphous silicon coating on a copper film, to create periodic structures through a photochemical reaction induced by laser-plasmon interference. Our experiments, corroborated by numerical

In this Letter, we report on a p-Cr2O3/n-Ga2O3 vertical heterojunction diode (HJD) with a kilovolt-level breakdown voltage (BV). The chromium oxide (Cr2O3) film was deposited via magnetron sputtering, with a controlled thickness of approximately 20 nm and a hole concentration of 1 × 1016 cm−3. High-resolution transmission electron microscopy of the p-Cr2O3 film reveals a polycrystalline lattice structure

Growth on patterned graphene/Ge provides a route to improve the film quality of large mismatch heteroepitaxy and simultaneously facilitate the transfer of epitaxial films; however, the growth process and its associated technical challenges remain unclear. In this work, the molecular beam epitaxy (MBE) growth of CdTe films on micro-scale patterned strip-like graphene/Ge (100), containing selective area

Structural energy storage combines energy storage with structural strength, reducing weight, saving space, and improving efficiency. Among various types, transparent structural energy storage shows strong potential for seamless integration into windows, screens, surfaces, consumer electronics, and automotive applications. Developing new electrode designs with environmentally abundant materials is essential

Enhancement-mode hydrogen-terminated diamond (C-H diamond) field effect transistors (FETs) are strongly desirable for safety protection, energy saving, etc., and low work function gate material is an effective and convenient way to deplete the two-dimensional hole gas and realize the enhancement-mode. In this article, we demonstrate a C-H diamond FET with low work function gadolinia (Gd2O3) gate materials

The family of transition metal dichlorides are recently found to be ferrovalley materials, exhibiting desirable spontaneous valley polarization that is a key to practical applications. In this work, Janus monolayer H-FeClBr is investigated as a case study by performing first-principles calculations. We focus on the giant correlation and many-body and exciton effects that will essentially modulate the

Charge localization is an important phenomenon that influences various material properties, including excited-state energetics, charge transport, catalytic activity, and recombination. As such, it has significant implications for optoelectronic and photocatalytic applications. In this Perspective, we begin by addressing the methodological challenges associated with modeling localized charges, highlighting

Magnetic materials featuring topology and flatband in their electronic structure bridge the topological quantum physics and strongly correlated many-body physics, but materials that manifest this feature are rare. Here, we predict a class of ideal intrinsic magnetic topological insulators naturally featuring a nontrivial flatband in the two-dimensional (2D) honeycomb-kagome lattices X2Rb3 (X=Cr, Mo

Based on an effective k·p model, we form breathing Kagome bilayers with two different interlayer antiferroelectric (AFE) couplings, i.e., tail to tail and head to head, to study their magnetic and valley properties. Spin–orbit coupling and magnetic exchange interaction induce valley-layer locking when the bilayer is ferromagnetic, however, spin-layer locking appears for the case of antiferromagnetic

High efficiency and out-of-plane spin–orbit torque (OOP-SOT) driven magnetization switching is essential for developing spin-based memory and logic devices. In this study, we report the generation of a large charge-to-spin conversion and bidirectional OOP-SOT by engineering a vertical magnetization gradient within a Co/Ho multilayer system. Exploiting the antiferromagnetic coupling between Co and Ho

The planar Hall effect (PHE) offers notable advantages in spintronic applications, particularly because of its high signal-to-noise ratio and minimal thermal drift. In this study, we present a tunable PHE in MnGe (111)/Si (111) thin films. Typically, PHE demonstrates π-periodicity as the magnetic field rotates within the plane. Interestingly, we observed that in MnGe thin films, both π- and π/2-periodicities

We demonstrate the unidirectional propagation of structure-induced edge waves in a thin plate. These waves, termed designer flexural edge waves (DFEWs), are observed along the free edge of a thin plate featuring periodically corrugated rectangular grooves. These DFEWs can be activated unidirectionally using either a pair of point sources exhibiting phase differences or a “chiral” source characterized

The metal–semiconductor contact resistivity has become a severe challenge for three-dimensional (3D) integration. In this work, starting from the physical origin, we propose that the charge redistribution is an effective strategy for decreasing Schottky barrier height (SBH), subsequently leading to a reduction in contact resistivity. Guided by this perspective, first-principles calculations are utilized

Further unleashing the full potential of YBa2Cu3O7−x (YBCO), a premier high-temperature superconductor, for devices in advanced communication technologies hinges on the refinement of its fabrication process. In this work, a synchrotron three-dimension reciprocal space mapping (3D-RSM) technique, which offers a larger Q-space range and higher spatial resolution, was developed and used to analyze YBCO

The aim of this Perspective is to provide an in-depth discussion of a certain class of 2D ferroelectrics that feature a van der Waals gap where more than one polar phase can exist energetically close to the ground state. Polar phases of interest can include different ferroelectric, antiferroelectric, and paraelectric phases, which can be transformed into each other through external stimuli, offering

Lasing from HgCdTe microdisk cavities is demonstrated at wavelengths as long as 20–25 μm. The optical threshold and operation temperature are mainly limited by nonradiative Shockley–Read–Hall type recombination. The employed ion etching technology appears to introduce additional defects in the vicinity of the microdisks, degrading figures of merit as the height of the cavity increases. However, a watt-level

The experimentally observed 2D magnets have unlocked the possibility of realizing a stable long-range order in the low-dimensional limit, which also gives a boost to the family of 1D magnets. Recently, a family of Fe-based nanowires has been observed in high-throughput transition metal chalcogenides synthesized by chemical vapor deposition [Zhou et al., Nat. Mater. 22, 450–458 (2023)]. In this work

InGaN-based pin-type visible light photodetectors (PDs), exhibiting enormous advantages of fast photoresponse speed and low noise, have drawn tremendous interest in visible light communication (VLC) applications. However, the insufficient light absorption capacity and low photoelectric conversion efficiency of InGaN-based pin heterojunction hinder the realization of high-sensitivity PDs for achieving

To enhance the efficiency and performance of p-type GaN-based power devices (diode, MOSFET) and p-channel transistors (p-FET), forming an Ohmic contact with low specific contact resistance (ρc) at p-GaN can be an effective way. However, the specific contact resistance values of p-GaN remain limited to the range of mid-10−2Ω cm2 due to the low activation ratio of Mg dopants and high work function. Here

The controllability of the spectral width and intensity of long-wave infrared (LWIR) emission is essential for various applications, including optical stealth, infrared radiation sources, and infrared lasers. Here, we proposed a multifunctional LWIR metasurface emitter with a switchable radiation state, which consists of germanium (Ge) rectangular pair resonators placed on a vanadium oxide (VO2) film

Cu-doped ZnO:Cu/ZnO heterojunctions were fabricated via a three-step laser-induced doping technique. This study systematically investigated the electrical properties, microstructure, elemental valence states, and energy-band alignment of these heterojunctions through multiple analytical techniques. Current–voltage measurements revealed an asymmetric, nonlinear behavior due to the depletion region at

Vanadium dioxide (VO2) exhibits multiple insulating states and complex transitions, both among these states and to a metallic rutile (R) phase. In this study, we investigate freestanding VO2 microbeams that undergo reversible transitions from an insulating triclinic (T) phase to an insulating monoclinic (M2) phase, followed by a transition to the R phase. The latent heat changes associated with these

Cesium lead bromide perovskites have demonstrated enormous potential in detecting applications, benefitting from their excellent optoelectronic properties and environmental stability. However, their intrinsic properties of photoluminescence intensity and carrier lifetime, key to photodetector performance, are still limited with conventional approaches (e.g., material purification and defect passivation)

In this work, we developed a computational framework that integrates first-principles density functional theory (DFT) calculations with Monte Carlo (MC) algorithm to search for the most stable configuration of high-entropy (HE) MXenes. This framework can predict the minimum energy configurations of HE MXenes with interlayer segregation. For instance, DFT/MC simulation indicates that (Ti0.5Cr0.5)4C3

This article introduces a memristor-coupled oscillatory network utilizing niobium dioxide (NbO2) memristors and a biomimetic spider web structure. It focuses on the dynamic behaviors of single oscillators and small-scale networks within this unique system, particularly emphasizing voltage, current, and frequency characteristics. By strategically applying step voltage signals on a 1 + 3 node single-layer

We report on the fabrication and characterization of p–n diodes made from wide bandgap II-VI semiconductors (p-ZnTe/n-CdTe) containing nano-inclusions of narrow bandgap material (PbTe). The diodes are fabricated by molecular beam epitaxy on semi-insulating GaAs (100) substrates. The PbTe nano-inclusions are formed either as a single layer of PbTe with a thickness of 350 nm or as multilayers built from

Cavity coupled flopping-mode spin qubit is considered as a promising scheme for enabling long-range qubit interactions in large-scale semiconductor quantum computation. In this work, we fabricate a linear Si/SiGe triple quantum dot (TQD) array coupled with a high-impedance TiN coplanar waveguide cavity via the gate of outer quantum dot. By utilizing two adjacent dots within the TQD, we sequentially

The inverse spinel oxide NiCo2O4, known for its high Curie temperature, low resistivity, and perpendicular magnetic anisotropy, is a promising candidate for the development of next-generation spintronic devices. However, reducing the thickness of the NiCo2O4 film to a few atomic layers degrades its room temperature magnetic and electrical properties, limiting its practical application. In this study

Open stopband (OSB) mitigation techniques are commonly used to improve the far-field radiating properties of leaky-wave antennas based on periodic structures. Recently, leaky waves have been proposed to focus energy in the near field through Bessel beams. However, the focusing character of Bessel beams is notably limited to a maximum distance known as the nondiffractive range. In this work, an OSB

Fourier ptychography (FP) is widely adopted for label-free, high-resolution quantitative phase imaging (QPI) of biological samples. However, its imaging speed is limited by the need for multiple acquisitions. In this work, we propose a single-shot FP technique that uses linear polarizers to encode multiple illumination wavevectors and a polarization camera to capture multiple sets of information simultaneously

The ultra-high piezoelectric activity of K0.5Na0.5NbO3 (KNN)-based single crystals with excellent electromechanical coupling characteristics has attracted great interest. However, the growth of KNN-based single crystals is restricted by their high melting point and harsh equipment conditions. In this work, a large-sized single crystal of (K0.5Na0.5)0.994Bi0.006Nb0.998Cu0.004O3 (KNNBC) was grown using

This paper presents a comprehensive study of silicon germanium (SiGe) cladded channels for stacked nanowires (NWs), focusing on morphological control and strain engineering to enhance device performance. High-resolution transmission electron microscopy (TEM) was used to characterize the Si NWs and SiGe cladding morphology. The results demonstrate that the morphology of SiGe cladding can be controlled

In this study, we propose black phosphorene (BP) for surface-enhanced Raman spectroscopy of DNA nucleotides. BP-enhanced Raman spectroscopy provides superior enhancement compared to other 2D materials, such as graphene and molybdenum disulfide, for biomolecular detection. We show that BP significantly amplifies the Raman signals of DNA nucleotides, enabling more sensitive and accurate detection of

Photovoltaic (PV) neuromorphic devices with photocurrents under illumination as readouts have gained increasing attention due to their ultralow latency and excellent energy efficiency during reading process. However, they face significant challenges in processing temporal data because of the lack of inherent temporal dynamics, limiting their application in reservoir computing (RC) systems. Here, we

CsPbBr3 single crystal is a promising candidate for room temperature radiation detector. However, the experimental mobilities reported exhibit considerable discrepancy, ranging widely from 10 to 4500 cm2/(V · s) at room temperature. Here, vertical Bridgman grown CsPbBr3 single crystal has been used to measure the mobility accurately using pulse-biased time-of-flight method. The hole mobility for CsPbBr3