Flutter Influence Mode Analysis of High Speed Wing Model

AbstractIn flutter wind tunnel test, the matching degree between scaled model and prototype would directly affect the reliability of test results. It is difficult to achieve completely dynamic similarity because of some material or technological constrains, and only lower order modes including mode shape and frequency are accurately simulated to construct a compromised model. Theoretical support would be necessary to answer the question which modes must be simulated to guarantee data validity of wind tunnel flutter test. An analytical study of a sweepback winghas been undertaken to estimate the flutter influence mode needed for accurate flutter prediction by analyzing generalized aerodynamic stiffness coefficient, unsteady aerodynamic force and flutter results. The results show that the aerodynamic stiffness coefficient with expression of mode shape could be taken as a quick criterion for mode selection in flutter model design and analysis

Atomic-Scale Strain Manipulation of a Charge Density Wave

A charge density wave (CDW) is one of the fundamental instabilities of the Fermi surface occurring in a wide range of quantum materials. In dimensions higher than one, where Fermi surface nesting can play only a limited role, the selection of the particular wave vector and geometry of an emerging CDW should in principle be susceptible to controllable manipulation. In this work, we implement a simple method for straining materials compatible with low-temperature scanning tunneling microscopy/spectroscopy (STM/S), and use it to strain-engineer new CDWs in 2H-NbSe2. Our STM/S measurements combined with theory reveal how small strain-induced changes in the electronic band structure and phonon dispersion lead to dramatic changes in the CDW ordering wave vector and geometry. Our work unveils the microscopic mechanism of a CDW formation in this system, and can serve as a general tool compatible with a range of spectroscopic techniques to engineer novel electronic states in any material where local strain or lattice symmetry breaking plays a role.Comment: to appear in PNAS (2018

Domain Re-Modulation for Few-Shot Generative Domain Adaptation

In this study, we delve into the task of few-shot Generative Domain Adaptation (GDA), which involves transferring a pre-trained generator from one domain to a new domain using only a few reference images. Inspired by the way human brains acquire knowledge in new domains, we present an innovative generator structure called Domain Re-Modulation (DoRM). DoRM not only meets the criteria of high quality, large synthesis diversity, and cross-domain consistency, which were achieved by previous research in GDA, but also incorporates memory and domain association, akin to how human brains operate. Specifically, DoRM freezes the source generator and introduces new mapping and affine modules (M&A modules) to capture the attributes of the target domain during GDA. This process resembles the formation of new synapses in human brains. Consequently, a linearly combinable domain shift occurs in the style space. By incorporating multiple new M&A modules, the generator gains the capability to perform high-fidelity multi-domain and hybrid-domain generation. Moreover, to maintain cross-domain consistency more effectively, we introduce a similarity-based structure loss. This loss aligns the auto-correlation map of the target image with its corresponding auto-correlation map of the source image during training. Through extensive experiments, we demonstrate the superior performance of our DoRM and similarity-based structure loss in few-shot GDA, both quantitatively and qualitatively. The code will be available at https://github.com/wuyi2020/DoRM.Comment: Under Revie

Emergence of unidirectional coherent quasiparticles from high-temperature rotational symmetry broken phase of AV3Sb5 kagome superconductors

Kagome metals AV3Sb5 display a rich phase diagram of correlated electron states, including superconductivity and novel density waves. Within this landscape, recent experiments reveal signs of a new transition below T ~ 35 K attributed to the highly sought-after electronic nematic phase that spontaneously breaks rotational symmetry of the lattice. We use spectroscopic-imaging scanning tunneling microscopy to study atomic-scale signatures of electronic symmetry breaking as a function of temperature across several materials in this family: CsV3Sb5, KV3Sb5 and Sn-doped CsV3Sb5. We find that rotational symmetry breaking onsets universally at a high temperature in these materials, toward the 2 x 2 charge density wave (CDW) transition temperature T*. At a significantly lower temperature of about 30 K, we discover a striking emergence of the quantum interference of coherent quasiparticles, a key signature for the formation of a coherent electronic state. These quasiparticles display a pronounced unidirectional reciprocal-space fingerprint, which strengthens on approaching the superconducting state. Our experiments reveal that the high-temperature charge ordering states are separated from the superconducting ground state by an intermediate-temperature regime with coherent unidirectional quasiparticles. Their emergence that occurs significantly below the onset of rotational symmetry breaking is phenomenologically different compared to high-temperature superconductors, shedding light on the complex nature of electronic nematicity in AV3Sb5 kagome superconductors