Ferric and ferrous ion plays critical roles in bioprocesses,their influences in many fields have not been fully explored due to the lack of methods for quantification of ferric and ferrous ions in biological system or...Ferric and ferrous ion plays critical roles in bioprocesses,their influences in many fields have not been fully explored due to the lack of methods for quantification of ferric and ferrous ions in biological system or complex matrix.In this study,an M13 bacteriophage(phage) was engineered for use as a sensor for ferric and ferrous ions via the display of a tyrosine residue on the P8 coat protein.The interaction between the specific phenol group of tyrosine and Fe^(3+)./ Fe^(2+).was used as the sensor.Transmission electron microscopy showed aggregation of the tyrosine-displaying phages after incubation with Fe^(3+) and Fe^(2+).The aggregated phages infected the host bacterium inefficiently.This phenomenon could be utilized for detection of ferric and ferrous ions.For ferric ions,a calibration curve ranging from 200 nmol/L to 8 μmol/L with a detection limit of 58 nmol/L was acquired.For ferrous ions,a calibration curve ranging from 800 nmol/L to 8μmol/L with a detection limit of 641.7 nmol/L was acquired.The assay was specific for Fe^((3+)) and Fe^((2+)) when tested against Ni^(2+),Pb^(2+),Zn^(2+),Mn^(2+),Co^(2+),Ca^(2+),Cu^(2+),Cr^(3+),Ba^(2+),and K^+.The tyrosine displaying phage to Fe^(3+) and Fe^(2+) interaction would have plenty of room in application to biomatenals and bionanotechnology.展开更多
Hepatitis B virus (HBV) is one of the major causes of chronic hepatitis, cirrhosis and liver cancer. In combating HBV infections, HBV diagnosis and vaccination are therefore critical. The hepatitis B virus surface ant...Hepatitis B virus (HBV) is one of the major causes of chronic hepatitis, cirrhosis and liver cancer. In combating HBV infections, HBV diagnosis and vaccination are therefore critical. The hepatitis B virus surface antigen (HBsAg) is a key target molecule in developing vaccines and diagnostic systems. To date, although HBsAg has been expressed in bacteria, yeasts and mammalian cells, there are still limitations in the existing ones, which leave the necessity for searching new HBsAg production methods. In this study, a simple phage display-based method was developed to produce the purified full-length HBsAg molecules for further immunization studies. For this purpose, the HBsAg coding gene was cloned into a pCANTAB5E phagemid vector and expressed on the surface of M13 filamentous phages. The HBsAg-expressing phage nanosystem was then used as immunization agent in BALB/cJ mice. The ELISA results for sera obtained from mice immunized with HBsAg-displaying phage particles revealed an immune response against HBsAg. These results demonstrate the potential use of a full-length antigen to be displayed on phages as cost effective adjuvant-free immunization agents as an alternative to the highly purified and more expensive antigens conjugated with carrier molecules.展开更多
Three-dimensional(3D) display technology—a cutting-edge medium for human-machine interaction—enhances visual information density via image dimensional expansion and reduces the cognitive load to improve the efficien...Three-dimensional(3D) display technology—a cutting-edge medium for human-machine interaction—enhances visual information density via image dimensional expansion and reduces the cognitive load to improve the efficiency of information exchange [1–3].展开更多
Limitations of difference maps showing circulation anomalies are analyzed, and the definition of the local pattern analogue coefficient (LPAC) is given together with the procedure for constructing such a map, followed...Limitations of difference maps showing circulation anomalies are analyzed, and the definition of the local pattern analogue coefficient (LPAC) is given together with the procedure for constructing such a map, followed by an example illustrating its useful application in circulation anomaly.展开更多
Neutralizing antibodies are essential tools in antiviral therapy and epidemic preparedness,capable of directlyinhibiting viral entry and limiting disease progression.However,traditional antibody discovery strategies—...Neutralizing antibodies are essential tools in antiviral therapy and epidemic preparedness,capable of directlyinhibiting viral entry and limiting disease progression.However,traditional antibody discovery strategies—suchas animal immunization or B cell isolation from infected individuals—are often hindered by biosafety concerns,lengthy development timelines,and limited adaptability during outbreaks.In the present study,we aimed toestablish a robust and rapid in vitro platform for the efficient isolation of neutralizing antibodies targetingconserved viral epitopes.We developed an epitope-guided negative screening strategy that integrates phagedisplay technology with rational antigen mutagenesis to exclude antibodies against variable regions whileenriching for those that recognize functionally constrained epitopes.When applied to the receptor-binding domainof severe acute respiratory syndrome coronavirus 2,this method enabled the identification of six neutralizingantibodies(one IgG and five nanobodies)exhibiting broad-spectrum neutralizing activity across multiple viralvariants.Notably,antibodies recognizing distinct epitopes demonstrated significant synergistic neutralizationwhen used in combination(P<0.05).This screening approach facilitates the rapid discovery of potent andmutation-resistant antibodies and holds promise for application to other emerging pathogens.Our findingsunderscore the potential of epitope-guided,in vitro platforms in expediting therapeutic antibody developmentunder conditions of high biosafety requirements.展开更多
Mobile applications(apps for short)often need to display images.However,inefficient image displaying(IID)issues are pervasive in mobile apps,and can severely impact app performance and user experience.This paper first...Mobile applications(apps for short)often need to display images.However,inefficient image displaying(IID)issues are pervasive in mobile apps,and can severely impact app performance and user experience.This paper first establishes a descriptive framework for the image displaying procedures of IID issues.Based on the descriptive framework,we conduct an empirical study of 216 real-world IID issues collected from 243 popular open-source Android apps to validate the presence and severity of IID issues,and then shed light on these issues’characteristics to support research on effective issue detection.With the findings of this study,we propose a static IID issue detection tool TAPIR and evaluate it with 243 real-world Android apps.Encouragingly,49 and 64 previously-unknown IID issues in two different versions of 16 apps reported by TAPIR are manually confirmed as true positives,respectively,and 16 previously-unknown IID issues reported by TAPIR have been confirmed by developers and 13 have been fixed.Then,we further evaluate the performance impact of these detected IID issues and the performance improvement if they are fixed.The results demonstrate that the IID issues detected by TAPIR indeed cause significant performance degradation,which further show the effectiveness and efficiency of TAPIR.展开更多
In an era dominated by visual information,the display interface serves as a critical gateway between the human and digital worlds.The relentless pursuit of visual immersion has driven display technology from cinema sc...In an era dominated by visual information,the display interface serves as a critical gateway between the human and digital worlds.The relentless pursuit of visual immersion has driven display technology from cinema screens to smart-phones and now to virtual and augmented reality(VR/AR)headsets,progressively moving closer to the human eye.This evolution places unprecedented demands on pixel density,power efficiency,and form factor,pushing up against funda-mental physical and physiological limits.展开更多
As the sunlight scattered on the sea of Guanyinshan in Xiamen,a space that bridges creativity and industry opened its door to the world.On December 15th,following a ribbon-cutting and unveiling ceremony,YKK Xiamen Gua...As the sunlight scattered on the sea of Guanyinshan in Xiamen,a space that bridges creativity and industry opened its door to the world.On December 15th,following a ribbon-cutting and unveiling ceremony,YKK Xiamen Guanyinshan Showroom,the brand's second and largest comprehensive showroom,was officially inaugurated.This showroom is more than a product display window,it is an"Inspiration Hub"integrating exhibition,co-creation,and service.Its launch signifies YKK's progression in the Chinese market from“building an efficient product proposal system”to a new stage of“deep collaborative co-creation.”展开更多
Detector and event visualization are crucial components of high-energy physics(HEP)experimental software.Virtual reality(VR)technologies and multimedia development platforms,such as Unity,offer enhanced display effect...Detector and event visualization are crucial components of high-energy physics(HEP)experimental software.Virtual reality(VR)technologies and multimedia development platforms,such as Unity,offer enhanced display effects and flexible extensibility for visualization in HEP experiments.In this study,we present a VR-based method for detector and event displays in the Jiangmen Underground Neutrino Observatory(JUNO)experiment.This method shares the same detector geometry descriptions and event data model as those in the offline software and provides the necessary data conversion interfaces.The VR methodology facilitates an immersive exploration of the virtual environment in JUNO,enabling users to investigate the detector geometry,visualize event data,and tune the detector simulation and event reconstruction algorithms.Additionally,this approach supports applications in data monitoring,physics data analysis,and public outreach initiatives.展开更多
The advent of artificial intelligence(AI)has propelled augmented reality(AR)display technology to a pivotal juncture,positioning it as a contender for the next generation of mobile intelligent terminals.However,the pu...The advent of artificial intelligence(AI)has propelled augmented reality(AR)display technology to a pivotal juncture,positioning it as a contender for the next generation of mobile intelligent terminals.However,the pursuit of advanced AR displays,particularly those capable of delivering immersive 3D experiences,is significantly hindered by the performance limitations of current hardware and the complexity of system integration.In this study,we present an innovative multi-focal plane AR display system that integrates a non-orthogonal polarization-multiplexing metasurface,freeform optical elements,and an OLED display screen.All optical elements are integrated into a single solid-state architecture,based on a joint optimization design approach of ray tracing and diffraction theory.The multi-focal plane AR visual effect is realized by the compact and multiplexing metasurface,which performs distinct phase functions across diverse polarization channels.Meanwhile,freeform surfaces offer ample design flexibility for the collaborative optimization of multi-focal plane imaging and the see-through systems.Followed by a mechanical design and prototype assembly,we demonstrate the system's capabilities in real-time and multi-focal plane display.The digital images at all virtual image distances seamlessly integrate with the real environment,fully exhibiting the system's high parallelism and real-time interactivity.With the innovative design concept and joint design method,we believe that our work will spur more innovative and compact intelligent solutions for AR displays and inject new vitality into hybrid optical systems.展开更多
Head-up displays(HUDs)are emerging as key components of intelligent vehicles,requiring wide-depth,large-area,and high-efficiency dynamic imaging,which remains difficult to realize with traditional refractive optics.Co...Head-up displays(HUDs)are emerging as key components of intelligent vehicles,requiring wide-depth,large-area,and high-efficiency dynamic imaging,which remains difficult to realize with traditional refractive optics.Computer-generated holography(CGH)with diffraction optics offers a promising solution to these technical demands.However,CGH optimization based on the fast Fourier transform(FFT)faces limitations such as zero-padding redundancy,coupled sampling intervals,and incompatible near-and farfield propagation models.Here,we report a holography-based multiplane HUD using a matrix multiplication(MM)-assisted diffraction algorithm that restructures the Fresnel integral into two sequential matrix operations,thus eliminating zero-padding and enabling fully decoupled sampling between object and image planes.Compared with FFT-based angular spectrum methods,the MM approach significantly improves computational speed and memory efficiency for hologram design,which is validated by demonstrating dual-plane holography with a size ratio exceeding 100:1 and unified reconstruction across Fresnel and Fraunhofer regimes within a single computation.A prototype HUD system is demonstrated successfully to exhibit multiple-plane holographic virtual images that can be mixed with real-world objects at three independent planes.The technique might be one of the potential candidates for next-generation intelligent vehicle displays.展开更多
Unlike conventional electrochromic devices,Zinc anode-based electrochromic devices(ZECDs)ensure excellent charge balance between the electrochromic layer and Zn anode during the coloring/bleaching by reversible metal ...Unlike conventional electrochromic devices,Zinc anode-based electrochromic devices(ZECDs)ensure excellent charge balance between the electrochromic layer and Zn anode during the coloring/bleaching by reversible metal deposition/stripping on the Zn anode.Meanwhile,the inherent potential difference between the metal anode and the electrochromic layer can drive the spontaneous coloration/bleaching of ZECDs,featuring energy retrieval functionality.This review discusses the working mechanisms,performance indexes of ZECDs,and the impact of material selection on ZECD performance.Furthermore,we comprehensively summarize the latest research progress of ZECDs in energy storage,smart windows,and multicolor displays.We argue that using high-transparency zinc mesh,additive manufacturing processes,and self-healing electrochromic materials can significantly advance the commercialization of large-area ZECDs.Finally,“electrode-free”device structures,renewable or replaceable electrolytes,and strategies to suppress zinc dendrites are prospected to overcome cost-effectiveness and lifespan issues of ZECDs.This review aims at enabling more efficient and advanced ZECDs for multifunctional applications.展开更多
To address the challenges of complexity,power consumption,and cost constraints in traditional display driver integrated circuits(DDICs)caused by external NOR Flash and SRAM,this work proposes an embedded resistive ran...To address the challenges of complexity,power consumption,and cost constraints in traditional display driver integrated circuits(DDICs)caused by external NOR Flash and SRAM,this work proposes an embedded resistive random-access memory(RRAM)integration solution based on a 40 nm high-voltage CMOS logic platform.Targeting the yield fluctuations and stability challenges during RRAM mass production,systematic process optimizations are implemented to achieve synergistic improvements in RRAM performance and yield.Through modifications to the film sputtering and pre-deposition treatment,the withinwafer resistance uniformity(RSU)of the oxygen-deficient layer(ODL)thin film is improved from 11%to 8%,while inter-wafer process stability variation reduces from 23%to below 6%.Consequently,the yield of 8 Mb RRAM embedded mass production products increases from 87%to 98.5%.In terms of device performance,the RRAM demonstrates a fast 4.8 ns read speed,exceptional read disturb immunity of 3×10^(8) cycles at 95℃,10^(3) write/erase endurance cycles for the 1 Mb cells,and data retention of 12.5 years at 125℃.Post high-temperature operating life(HTOL)testing exhibits stable high/low resistance window.This study provides process optimization strategies and a reliability assurance framework for the mass production of highly integrated,low-power embedded RRAM display driver IC.展开更多
White Cyphochilus insulanus beetles,exhibiting both environmental camouflage display and radiative cooling functions,serve as a good prototype for biomimetic fabrication.As inspired,this work presents a femtosecond(fs...White Cyphochilus insulanus beetles,exhibiting both environmental camouflage display and radiative cooling functions,serve as a good prototype for biomimetic fabrication.As inspired,this work presents a femtosecond(fs)laser-based biomimetic fabrication strategy that takes full use of the synthesized radiative cooling nanomaterials for a groundbreaking stimuli-responsive infrared(IR)impressionistic camouflage display.The proposed technique is capable of readily transforming various substrates(quartz glass and metals including Ti,Al,Zr,and W)into self-assembled porous networks(aerogels)consisting of oxygen-vacancy-rich oxide nanoparticles.Surprisingly,the emissions of all as-prepared porous particle-networks in the radiative-cooling long-wavelength infrared(LWIR)band are above 95%,with the SiO_(2) aerogels reaching a maximum of 99.6%.Benefiting from the far-from-equilibrium thermodynamic kinetics,metastable phases of anatase TiO_(2),tetragonal zirconia(t-ZrO_(2)),and monoclinic WO_(3)(Pc)are synthesizable,opening up opportunities for exploring their optical applications.Taking the low-temperature metastable phase WO_(3)(Pc)as representative for systematic studies,it is found that(1)the ratio WO_(3)(Pc)phase to that of room-temperature phase of WO_(3)(P2_(1)/n)can be tailored by modulation of processing parameters;(2)laser synthesized aerogels with hybrid phases of WO_(3)(Pc)and WO_(3)(P2_(1)/n)have a brighter visible whiteness,higher visible/nearinfrared(NIR)spectral selectivity than the natural prototype of white Cyphochilus insulanus beetles but with comparable LWIR emittance.White WO_(3) aerogel in situ deposited during flexibly fs laser artistic patterning can blur the painting features due to its radiative cooling effect,allowing a colorful impressionistic IR display in the heating mode.What's more,invisible painting features concealed by the white deposited WO_(3) aerogel are clearly/faintly distinguishable by introducing external stimuli of a human hand and sample heating,respectively,catalyzing progress in optical encryption and selectively stimuli-responsive decryption display in the infrared band.展开更多
Beijing Museum of Natural History is located in Chongwen District, close to the Temple of Heaven and Tianqiao Theater. It was founded in 1951 and formally named Beijing Museum of Natural History in 1962.
A method of drawing color spectrogram of speech by using microcomputer is described in this paper , and referred to the metod of drawing spectrogram by computer . With the software and no addition any other aqripment....A method of drawing color spectrogram of speech by using microcomputer is described in this paper , and referred to the metod of drawing spectrogram by computer . With the software and no addition any other aqripment., we can draw color three - dimension spectrogram ( or black -white spectrogram without color monitor ), and it is similar to spectrogram of sonagrapher .展开更多
Trehalose is a disaccharide with many applications in cosmetics,refrigeration,and food.Trehalose synthase is a significant enzyme in trehalose production.Escherichia coli is usually used to express this enzyme heterol...Trehalose is a disaccharide with many applications in cosmetics,refrigeration,and food.Trehalose synthase is a significant enzyme in trehalose production.Escherichia coli is usually used to express this enzyme heterologously.Since E.coli is a pathogenic strain,we chose Corynebacterium glutamicum ATCC13032 as an engineering strain in this study for food safety reasons.Because of its poor permeability,we constructed two recombinant C.glutamicum strains using two anchor proteins,PorH,and short-length NCgl1337,to anchor trehalose synthase from Streptomyces coelicolor on the cell surface and synthesize trehalose directly from maltose.Studies on enzymatic properties indicated that NCgl1337S–ScTreSK246A had better enzyme activity and thermal stability than the free enzyme.After optimizing the whole-cell transformation,the optimal transformation condition was 35°C,pH 7.0,and OD600 of 30.Under this condition,the conversion rate of 300 g/L maltose reached 69.5%in a 5 L fermentor.The relative conversion rate was still above 75%after repeated five times.展开更多
The purpose of this study was to assess the potential application of cell surface display in Candida tropicalis.Surface display gene cassettes were constructed using five anchoring proteins from Saccharomyces cerevisi...The purpose of this study was to assess the potential application of cell surface display in Candida tropicalis.Surface display gene cassettes were constructed using five anchoring proteins from Saccharomyces cerevisiae,three of which[(suppression of exponential defect protein,SED1),(cell wall protein 2,CWP2)and(delayed anaerobic protein 4,DAN4)]were reported to show higher activity of heterologous proteins thanα-agglutinin(AGα1).The performance of yeast-enhanced green fluorescent protein(yeGFP)was evaluated using laser scanning confocal microscopy and flow cytometry.The results showed that the three anchoring regions(SED1,CWP2 and AGα1)successfully displayed yeGFP on the cell wall.To investigate the effect of the three anchoring proteins on the surface display of Rhizopus oryzaeα-amylase(ROA1)and Aspergillus aculeatusβ-glucosidase(BGL1)in C.tropicalis,we constructed surface display gene cassettes for ROA1 and BGL1,respectively.The strains containing the anchoring proteins SED1 and CWP2 showed higher activity of ROA1 and BGL1 than the strains containing the anchoring protein AGα1.The highest ROA1 and BGL1 activities of strains with SED1 were 6.37 U/g CDW and 7.93 U/g CDW,respectively,which were sixfold and eightfold higher than those of strain with AGα1.In addition,we also optimized signal peptides.The results indicated that signal peptides have an impact on enzyme activity.展开更多
Smart electronic textiles with electronic functions like displaying can provide transformative opportunities for wearable devices that traditional rigid devices are hard to realize.A general strategy of enabling texti...Smart electronic textiles with electronic functions like displaying can provide transformative opportunities for wearable devices that traditional rigid devices are hard to realize.A general strategy of enabling textiles to display is weaving light-emitting fibers into textiles and designing control circuits.However,it remains challenging for the current electronic textiles to display full-color images and videos.Here,we demonstrate a large-area integrated electronic textile system(with a size of 72 cm×50 cm)by weaving light-emitting diode(LED)fibers,touch-sensing fibers and polyester fibers,which could display full-color images(with a gamut of 117.6%NTSC)and continuous videos(with a refresh rate of 11.7 Hz)by designing low-voltage supply mode and parallelly transmitting circuits.After integration of touch-sensing fibers,such textile system could achieve various touch display and interactive functions like smart phones or computers,including hand input of text,hand painting,computing and playing games.The stability and durability of textile system withstanding 5000 bending cycles was also demonstrated for wearable applications.The integrated electronic textile system shows similar flexibility and breathability with regular textiles,which is promising to serve as new human-machine interface to change the way in which people interact with electronics.展开更多
基金funded by the National Natural Science Foundation of China (No. 31300829)Natural Science Foundation of Hubei Province of China (No. 2014CFC1117)Open Research Fund Program of the State Key Laboratory of Virology of China (No. 2015IOV002)
文摘Ferric and ferrous ion plays critical roles in bioprocesses,their influences in many fields have not been fully explored due to the lack of methods for quantification of ferric and ferrous ions in biological system or complex matrix.In this study,an M13 bacteriophage(phage) was engineered for use as a sensor for ferric and ferrous ions via the display of a tyrosine residue on the P8 coat protein.The interaction between the specific phenol group of tyrosine and Fe^(3+)./ Fe^(2+).was used as the sensor.Transmission electron microscopy showed aggregation of the tyrosine-displaying phages after incubation with Fe^(3+) and Fe^(2+).The aggregated phages infected the host bacterium inefficiently.This phenomenon could be utilized for detection of ferric and ferrous ions.For ferric ions,a calibration curve ranging from 200 nmol/L to 8 μmol/L with a detection limit of 58 nmol/L was acquired.For ferrous ions,a calibration curve ranging from 800 nmol/L to 8μmol/L with a detection limit of 641.7 nmol/L was acquired.The assay was specific for Fe^((3+)) and Fe^((2+)) when tested against Ni^(2+),Pb^(2+),Zn^(2+),Mn^(2+),Co^(2+),Ca^(2+),Cu^(2+),Cr^(3+),Ba^(2+),and K^+.The tyrosine displaying phage to Fe^(3+) and Fe^(2+) interaction would have plenty of room in application to biomatenals and bionanotechnology.
文摘Hepatitis B virus (HBV) is one of the major causes of chronic hepatitis, cirrhosis and liver cancer. In combating HBV infections, HBV diagnosis and vaccination are therefore critical. The hepatitis B virus surface antigen (HBsAg) is a key target molecule in developing vaccines and diagnostic systems. To date, although HBsAg has been expressed in bacteria, yeasts and mammalian cells, there are still limitations in the existing ones, which leave the necessity for searching new HBsAg production methods. In this study, a simple phage display-based method was developed to produce the purified full-length HBsAg molecules for further immunization studies. For this purpose, the HBsAg coding gene was cloned into a pCANTAB5E phagemid vector and expressed on the surface of M13 filamentous phages. The HBsAg-expressing phage nanosystem was then used as immunization agent in BALB/cJ mice. The ELISA results for sera obtained from mice immunized with HBsAg-displaying phage particles revealed an immune response against HBsAg. These results demonstrate the potential use of a full-length antigen to be displayed on phages as cost effective adjuvant-free immunization agents as an alternative to the highly purified and more expensive antigens conjugated with carrier molecules.
文摘Three-dimensional(3D) display technology—a cutting-edge medium for human-machine interaction—enhances visual information density via image dimensional expansion and reduces the cognitive load to improve the efficiency of information exchange [1–3].
基金The work is supported by the Research Funds of Long-Range Weather Prediction,State Meteorological Ad.ministration.China
文摘Limitations of difference maps showing circulation anomalies are analyzed, and the definition of the local pattern analogue coefficient (LPAC) is given together with the procedure for constructing such a map, followed by an example illustrating its useful application in circulation anomaly.
基金supported by the Natural Science Foundation of the Jiangsu Higher Education Institutions of China(Grant No.22KJB310001 to W.G.)the Special Project of the Jiangsu Provincial Department of Science and Technology(Grant No.BE2023603 to W.G.)the Nanjing Medical University Science and Technology Development Foundation(Grant No.NMUB20210006 to W.G.).
文摘Neutralizing antibodies are essential tools in antiviral therapy and epidemic preparedness,capable of directlyinhibiting viral entry and limiting disease progression.However,traditional antibody discovery strategies—suchas animal immunization or B cell isolation from infected individuals—are often hindered by biosafety concerns,lengthy development timelines,and limited adaptability during outbreaks.In the present study,we aimed toestablish a robust and rapid in vitro platform for the efficient isolation of neutralizing antibodies targetingconserved viral epitopes.We developed an epitope-guided negative screening strategy that integrates phagedisplay technology with rational antigen mutagenesis to exclude antibodies against variable regions whileenriching for those that recognize functionally constrained epitopes.When applied to the receptor-binding domainof severe acute respiratory syndrome coronavirus 2,this method enabled the identification of six neutralizingantibodies(one IgG and five nanobodies)exhibiting broad-spectrum neutralizing activity across multiple viralvariants.Notably,antibodies recognizing distinct epitopes demonstrated significant synergistic neutralizationwhen used in combination(P<0.05).This screening approach facilitates the rapid discovery of potent andmutation-resistant antibodies and holds promise for application to other emerging pathogens.Our findingsunderscore the potential of epitope-guided,in vitro platforms in expediting therapeutic antibody developmentunder conditions of high biosafety requirements.
基金supported by the Leading-Edge Technology Program of Jiangsu Natural Science Foundation of China under Grant No.BK20202001the National Natural Science Foundation of China under Grant No.61932021.
文摘Mobile applications(apps for short)often need to display images.However,inefficient image displaying(IID)issues are pervasive in mobile apps,and can severely impact app performance and user experience.This paper first establishes a descriptive framework for the image displaying procedures of IID issues.Based on the descriptive framework,we conduct an empirical study of 216 real-world IID issues collected from 243 popular open-source Android apps to validate the presence and severity of IID issues,and then shed light on these issues’characteristics to support research on effective issue detection.With the findings of this study,we propose a static IID issue detection tool TAPIR and evaluate it with 243 real-world Android apps.Encouragingly,49 and 64 previously-unknown IID issues in two different versions of 16 apps reported by TAPIR are manually confirmed as true positives,respectively,and 16 previously-unknown IID issues reported by TAPIR have been confirmed by developers and 13 have been fixed.Then,we further evaluate the performance impact of these detected IID issues and the performance improvement if they are fixed.The results demonstrate that the IID issues detected by TAPIR indeed cause significant performance degradation,which further show the effectiveness and efficiency of TAPIR.
基金supported by the National Natural Science Foundation of China(Grant No.22105106)the Jiangsu Youth Science and Technology Talent Support Program(Grant No.JSTJ-2025-063)+1 种基金Nanjing Science and Technology Innovation Project for Overseas Students(Grant No.NJKCZYZZ2022-05)Start-up Funding from NUPTSF(Grant No.NY221003).
文摘In an era dominated by visual information,the display interface serves as a critical gateway between the human and digital worlds.The relentless pursuit of visual immersion has driven display technology from cinema screens to smart-phones and now to virtual and augmented reality(VR/AR)headsets,progressively moving closer to the human eye.This evolution places unprecedented demands on pixel density,power efficiency,and form factor,pushing up against funda-mental physical and physiological limits.
文摘As the sunlight scattered on the sea of Guanyinshan in Xiamen,a space that bridges creativity and industry opened its door to the world.On December 15th,following a ribbon-cutting and unveiling ceremony,YKK Xiamen Guanyinshan Showroom,the brand's second and largest comprehensive showroom,was officially inaugurated.This showroom is more than a product display window,it is an"Inspiration Hub"integrating exhibition,co-creation,and service.Its launch signifies YKK's progression in the Chinese market from“building an efficient product proposal system”to a new stage of“deep collaborative co-creation.”
基金supported by the National Natural Science Foundation of China(Nos.12175321,W2443004,11975021,11675275,U1932101)Strategic Priority Research Program of the Chinese Academy of Sciences(No.XDA10010900)+2 种基金National Key Research and Development Program of China(Nos.2023YFA1606000 and 2020YFA0406400)National College Students Science and Technology Innovation ProjectUndergraduate Base Scientific Research Project of Sun Yat-sen University。
文摘Detector and event visualization are crucial components of high-energy physics(HEP)experimental software.Virtual reality(VR)technologies and multimedia development platforms,such as Unity,offer enhanced display effects and flexible extensibility for visualization in HEP experiments.In this study,we present a VR-based method for detector and event displays in the Jiangmen Underground Neutrino Observatory(JUNO)experiment.This method shares the same detector geometry descriptions and event data model as those in the offline software and provides the necessary data conversion interfaces.The VR methodology facilitates an immersive exploration of the virtual environment in JUNO,enabling users to investigate the detector geometry,visualize event data,and tune the detector simulation and event reconstruction algorithms.Additionally,this approach supports applications in data monitoring,physics data analysis,and public outreach initiatives.
基金funding provided by National Natural Science Foundation of China(U21A20140)National Key Research and Development Program of China(2021YFA1401200)+2 种基金Beijing Natural Science Foundation(JQ24028)Beijing Nova Program(20240484557)Synergetic Extreme Condition User Facility(SECUF).
文摘The advent of artificial intelligence(AI)has propelled augmented reality(AR)display technology to a pivotal juncture,positioning it as a contender for the next generation of mobile intelligent terminals.However,the pursuit of advanced AR displays,particularly those capable of delivering immersive 3D experiences,is significantly hindered by the performance limitations of current hardware and the complexity of system integration.In this study,we present an innovative multi-focal plane AR display system that integrates a non-orthogonal polarization-multiplexing metasurface,freeform optical elements,and an OLED display screen.All optical elements are integrated into a single solid-state architecture,based on a joint optimization design approach of ray tracing and diffraction theory.The multi-focal plane AR visual effect is realized by the compact and multiplexing metasurface,which performs distinct phase functions across diverse polarization channels.Meanwhile,freeform surfaces offer ample design flexibility for the collaborative optimization of multi-focal plane imaging and the see-through systems.Followed by a mechanical design and prototype assembly,we demonstrate the system's capabilities in real-time and multi-focal plane display.The digital images at all virtual image distances seamlessly integrate with the real environment,fully exhibiting the system's high parallelism and real-time interactivity.With the innovative design concept and joint design method,we believe that our work will spur more innovative and compact intelligent solutions for AR displays and inject new vitality into hybrid optical systems.
基金supported by the National Key Research and Development Program of China(Grant No.2022YFB3607300)the National Natural Science Foundation of China(Grant Nos.62322512,62225506,and 12134013)+7 种基金the Fundamental Research Funds for the Central Universities(Grant Nos.WK2030000108 and WK2030000090)the CAS Project for Young Scientists in Basic Research(Grant No.YSBR-049)supported by the National Natural Science Foundation of China(Grant Nos.12174260 and 12574326)the Shanghai Rising-Star Program(Grant No.21QA1406400)the Shanghai Science and Technology Development Fund(Grant Nos.21ZR1443500 and 21ZR1443600)the support from the China Postdoctoral Science Foundation(Grant No.2023M743364)support from the Center for Micro and Nanoscale Research and Fabrication,University of Science and Technology of Chinasupported by the UPOLabs,which provided the experimental and technical support。
文摘Head-up displays(HUDs)are emerging as key components of intelligent vehicles,requiring wide-depth,large-area,and high-efficiency dynamic imaging,which remains difficult to realize with traditional refractive optics.Computer-generated holography(CGH)with diffraction optics offers a promising solution to these technical demands.However,CGH optimization based on the fast Fourier transform(FFT)faces limitations such as zero-padding redundancy,coupled sampling intervals,and incompatible near-and farfield propagation models.Here,we report a holography-based multiplane HUD using a matrix multiplication(MM)-assisted diffraction algorithm that restructures the Fresnel integral into two sequential matrix operations,thus eliminating zero-padding and enabling fully decoupled sampling between object and image planes.Compared with FFT-based angular spectrum methods,the MM approach significantly improves computational speed and memory efficiency for hologram design,which is validated by demonstrating dual-plane holography with a size ratio exceeding 100:1 and unified reconstruction across Fresnel and Fraunhofer regimes within a single computation.A prototype HUD system is demonstrated successfully to exhibit multiple-plane holographic virtual images that can be mixed with real-world objects at three independent planes.The technique might be one of the potential candidates for next-generation intelligent vehicle displays.
基金supports from the National Natural Science Foundation of China(62105185,52202320)the“Qilu Young Scholar”program(62460082163097)of Shandong University,open foundation of the State Key Laboratory of Vanadium and Titanium Resources Comprehensive Utilization(2023P4FZG08A)+1 种基金Fundamental Research Funds for the Central Universities(No.862201013153)Shandong Excellent Young Scientists Fund Program(Overseas)(2023HWYQ-060).
文摘Unlike conventional electrochromic devices,Zinc anode-based electrochromic devices(ZECDs)ensure excellent charge balance between the electrochromic layer and Zn anode during the coloring/bleaching by reversible metal deposition/stripping on the Zn anode.Meanwhile,the inherent potential difference between the metal anode and the electrochromic layer can drive the spontaneous coloration/bleaching of ZECDs,featuring energy retrieval functionality.This review discusses the working mechanisms,performance indexes of ZECDs,and the impact of material selection on ZECD performance.Furthermore,we comprehensively summarize the latest research progress of ZECDs in energy storage,smart windows,and multicolor displays.We argue that using high-transparency zinc mesh,additive manufacturing processes,and self-healing electrochromic materials can significantly advance the commercialization of large-area ZECDs.Finally,“electrode-free”device structures,renewable or replaceable electrolytes,and strategies to suppress zinc dendrites are prospected to overcome cost-effectiveness and lifespan issues of ZECDs.This review aims at enabling more efficient and advanced ZECDs for multifunctional applications.
文摘To address the challenges of complexity,power consumption,and cost constraints in traditional display driver integrated circuits(DDICs)caused by external NOR Flash and SRAM,this work proposes an embedded resistive random-access memory(RRAM)integration solution based on a 40 nm high-voltage CMOS logic platform.Targeting the yield fluctuations and stability challenges during RRAM mass production,systematic process optimizations are implemented to achieve synergistic improvements in RRAM performance and yield.Through modifications to the film sputtering and pre-deposition treatment,the withinwafer resistance uniformity(RSU)of the oxygen-deficient layer(ODL)thin film is improved from 11%to 8%,while inter-wafer process stability variation reduces from 23%to below 6%.Consequently,the yield of 8 Mb RRAM embedded mass production products increases from 87%to 98.5%.In terms of device performance,the RRAM demonstrates a fast 4.8 ns read speed,exceptional read disturb immunity of 3×10^(8) cycles at 95℃,10^(3) write/erase endurance cycles for the 1 Mb cells,and data retention of 12.5 years at 125℃.Post high-temperature operating life(HTOL)testing exhibits stable high/low resistance window.This study provides process optimization strategies and a reliability assurance framework for the mass production of highly integrated,low-power embedded RRAM display driver IC.
基金financial support received from the Shanghai Pujiang Program(23PJ1406500)。
文摘White Cyphochilus insulanus beetles,exhibiting both environmental camouflage display and radiative cooling functions,serve as a good prototype for biomimetic fabrication.As inspired,this work presents a femtosecond(fs)laser-based biomimetic fabrication strategy that takes full use of the synthesized radiative cooling nanomaterials for a groundbreaking stimuli-responsive infrared(IR)impressionistic camouflage display.The proposed technique is capable of readily transforming various substrates(quartz glass and metals including Ti,Al,Zr,and W)into self-assembled porous networks(aerogels)consisting of oxygen-vacancy-rich oxide nanoparticles.Surprisingly,the emissions of all as-prepared porous particle-networks in the radiative-cooling long-wavelength infrared(LWIR)band are above 95%,with the SiO_(2) aerogels reaching a maximum of 99.6%.Benefiting from the far-from-equilibrium thermodynamic kinetics,metastable phases of anatase TiO_(2),tetragonal zirconia(t-ZrO_(2)),and monoclinic WO_(3)(Pc)are synthesizable,opening up opportunities for exploring their optical applications.Taking the low-temperature metastable phase WO_(3)(Pc)as representative for systematic studies,it is found that(1)the ratio WO_(3)(Pc)phase to that of room-temperature phase of WO_(3)(P2_(1)/n)can be tailored by modulation of processing parameters;(2)laser synthesized aerogels with hybrid phases of WO_(3)(Pc)and WO_(3)(P2_(1)/n)have a brighter visible whiteness,higher visible/nearinfrared(NIR)spectral selectivity than the natural prototype of white Cyphochilus insulanus beetles but with comparable LWIR emittance.White WO_(3) aerogel in situ deposited during flexibly fs laser artistic patterning can blur the painting features due to its radiative cooling effect,allowing a colorful impressionistic IR display in the heating mode.What's more,invisible painting features concealed by the white deposited WO_(3) aerogel are clearly/faintly distinguishable by introducing external stimuli of a human hand and sample heating,respectively,catalyzing progress in optical encryption and selectively stimuli-responsive decryption display in the infrared band.
文摘Beijing Museum of Natural History is located in Chongwen District, close to the Temple of Heaven and Tianqiao Theater. It was founded in 1951 and formally named Beijing Museum of Natural History in 1962.
文摘A method of drawing color spectrogram of speech by using microcomputer is described in this paper , and referred to the metod of drawing spectrogram by computer . With the software and no addition any other aqripment., we can draw color three - dimension spectrogram ( or black -white spectrogram without color monitor ), and it is similar to spectrogram of sonagrapher .
基金the National Natural Science Foundation of China(No.32171471)Key Research and Development Project of Shandong Province,China(2019JZZY020605)the Project Funded by the Priority Academic Program Development of Jiangsu Higher Education Institutions,Top-notch Academic Programs Project of Jiangsu Higher Education Institutions.
文摘Trehalose is a disaccharide with many applications in cosmetics,refrigeration,and food.Trehalose synthase is a significant enzyme in trehalose production.Escherichia coli is usually used to express this enzyme heterologously.Since E.coli is a pathogenic strain,we chose Corynebacterium glutamicum ATCC13032 as an engineering strain in this study for food safety reasons.Because of its poor permeability,we constructed two recombinant C.glutamicum strains using two anchor proteins,PorH,and short-length NCgl1337,to anchor trehalose synthase from Streptomyces coelicolor on the cell surface and synthesize trehalose directly from maltose.Studies on enzymatic properties indicated that NCgl1337S–ScTreSK246A had better enzyme activity and thermal stability than the free enzyme.After optimizing the whole-cell transformation,the optimal transformation condition was 35°C,pH 7.0,and OD600 of 30.Under this condition,the conversion rate of 300 g/L maltose reached 69.5%in a 5 L fermentor.The relative conversion rate was still above 75%after repeated five times.
基金supported by the 111 Project(No.111-2-06)National Natural Science Foundation of China(32001064)+2 种基金Key Research and Development Program of China(2021YFC2100102-03)China Postdoctoral Science Foundation(2020M671331)Postgraduate Research and Practice Innovation Program of Jiangsu Province(No.KYCX20-1807).
文摘The purpose of this study was to assess the potential application of cell surface display in Candida tropicalis.Surface display gene cassettes were constructed using five anchoring proteins from Saccharomyces cerevisiae,three of which[(suppression of exponential defect protein,SED1),(cell wall protein 2,CWP2)and(delayed anaerobic protein 4,DAN4)]were reported to show higher activity of heterologous proteins thanα-agglutinin(AGα1).The performance of yeast-enhanced green fluorescent protein(yeGFP)was evaluated using laser scanning confocal microscopy and flow cytometry.The results showed that the three anchoring regions(SED1,CWP2 and AGα1)successfully displayed yeGFP on the cell wall.To investigate the effect of the three anchoring proteins on the surface display of Rhizopus oryzaeα-amylase(ROA1)and Aspergillus aculeatusβ-glucosidase(BGL1)in C.tropicalis,we constructed surface display gene cassettes for ROA1 and BGL1,respectively.The strains containing the anchoring proteins SED1 and CWP2 showed higher activity of ROA1 and BGL1 than the strains containing the anchoring protein AGα1.The highest ROA1 and BGL1 activities of strains with SED1 were 6.37 U/g CDW and 7.93 U/g CDW,respectively,which were sixfold and eightfold higher than those of strain with AGα1.In addition,we also optimized signal peptides.The results indicated that signal peptides have an impact on enzyme activity.
基金supported by the Ministry of Science and Technology of the People's Republic of China(MOST)(2022YFA1203001,2022YFA1203002)National Natural Science Foundation of China(NSFC)(T2321003,22335003,T2222005,22175042)Science and Technology Commission of Shanghai Municipality(STCSM)(21511104900)。
文摘Smart electronic textiles with electronic functions like displaying can provide transformative opportunities for wearable devices that traditional rigid devices are hard to realize.A general strategy of enabling textiles to display is weaving light-emitting fibers into textiles and designing control circuits.However,it remains challenging for the current electronic textiles to display full-color images and videos.Here,we demonstrate a large-area integrated electronic textile system(with a size of 72 cm×50 cm)by weaving light-emitting diode(LED)fibers,touch-sensing fibers and polyester fibers,which could display full-color images(with a gamut of 117.6%NTSC)and continuous videos(with a refresh rate of 11.7 Hz)by designing low-voltage supply mode and parallelly transmitting circuits.After integration of touch-sensing fibers,such textile system could achieve various touch display and interactive functions like smart phones or computers,including hand input of text,hand painting,computing and playing games.The stability and durability of textile system withstanding 5000 bending cycles was also demonstrated for wearable applications.The integrated electronic textile system shows similar flexibility and breathability with regular textiles,which is promising to serve as new human-machine interface to change the way in which people interact with electronics.
