ライフサイエンスコーパス: optical device

1 ace exposed to the observation system of the optical device.

2 r quantum information processing and quantum optical device.

3 al nanospectroscopic imaging based on a nano-optical device.

4 l materials to create nanoelectronic or nano-optical devices.

5 ed from free space, making it functional for optical devices.

6 re hole-transport layer materials in electro-optical devices.

7 ties may lead to applications in sensors and optical devices.

8 of miniaturized electrical, nanofluidic and optical devices.

9 elts with quantum effects for electronic and optical devices.

10 ities for miniaturization and integration of optical devices.

11 new generation of electronics, sensors, and optical devices.

12 ug delivery to catalysis to micrometer-scale optical devices.

13 tals promising for application in a range of optical devices.

14 ed to create next generation agile microwave-optical devices.

15 reproducible manufacturing of advanced nano-optical devices.

16 nic states, offering potential for nonlinear optical devices.

17 films hold much promise for use in advanced optical devices.

18 imaging and in the design of many other new optical devices.

19 ocity fundamentally limit the integration of optical devices.

20 es for miniaturized high-performance magneto-optical devices.

21 veloping arbitrarily shaped multi-functional optical devices.

22 to enable compactness and miniaturisation of optical devices.

23 solar cells, and also toward applications as optical devices.

24 ts for flexible light emitter or on-chip all-optical devices.

25 ged to form lithium-niobate based integrated optical devices.

26 waveguide- or nanostructure-based nonlinear optical devices.

27 it attractive for flexible, biopolymer-based optical devices.

28 e applications with functionality switchable optical devices.

29 by gating which allows one to realize active optical devices.

30 ls brings the development of vast variety of optical devices.

31 he [2]catenane attractive for use in electro-optical devices.

32 efractive index gradients for transformation optical devices.

33 operations are difficult to perform with all-optical devices.

34 alysis of light manipulation with individual optical devices.

35 w the direct electronic control of nonlinear optical devices.

36 ultra-small, ultra-fast and power-efficient optical devices.

37 t, from solar cell coatings to self-cleaning optical devices.

38 n agents and quantum dots for electronic and optical devices.

39 e offer new approaches to implement advanced optical devices.

40 or infrared metamaterials and transformation optical devices.

41 great potential for applications in quantum optical devices.

42 nsformation optics to achieve a new class of optical devices.

43 nufacturing processes and include only a few optical devices alongside simple circuits.

44 transducers, ranging from nanogravimetric to optical devices, also enabling the realization of multif

45 ability of materials for the applications in optical devices, analysis, biosensing, and fluorescence

46 integrated in a range of microelectronic or optical devices and applications.

47 o chemical and electrical stimuli in electro-optical devices and chemical sensors.

48 rtant ultra thin film materials for sensors, optical devices and magnetic storage media.

49 troduce functionality into soft matter-based optical devices and may enable novel data storage scheme

50 r lasers combine the advantages of nonlinear optical devices and of semiconductor injection lasers, a

51 provide the possibility to develop synthetic optical devices and structures with enhanced functionali

52 further miniaturization of high-performance optical devices and systems.

53 uides is a common requirement for integrated optical devices, and is typically achieved by end-fire o

54 ctromechanical systems, thin-film metrology, optical devices, and others.

55 ultidimensional architectures for functional optical devices are covered and the next steps for this

56 However, applications of metasurfaces to optical devices are rare due to fabrication difficulties

57 ising technology platform for terahertz- to- optical devices as well as radio-frequency acoustic devi

58 ay offer a convenient template for producing optical devices based on biomimicry or direct dielectric

59 be considered when designing and fabricating optical devices based on GaAsBi alloys.

60 new acousto-optic platform can lead to novel optical devices based on nonlinear Brillouin processes a

61 the road towards tunable terahertz nonlinear optical devices based on topological insulator materials

62 r chip-scale, electrically tunable nonlinear optical devices based on two-dimensional semiconductors.

63 lation (SLIM) represent a novel class of ion optical devices based upon electrodes patterned on plana

64 use in catalyst, adsorption, polymer filler, optical devices, bio-imaging, drug delivery, and biomedi

65 The mammalian eye is a remarkable optical device, but its design is not perfect.

66 devise strategies through which miniaturized optical devices can be monolithically fabricated on ligh

67 , such as for energy conversion and storage, optical devices, catalysts, and various important nanoce

68 road maps to future innovations in nanoscale optical devices, components, and more intricate nanoscal

69 An optical device configuration allowing efficient electric

70 An optical device configuration allowing efficient electric

71 he traditional notion of what constitutes an optical device continues to evolve.

72 levant for the design of novel electronic or optical devices controllable by temperature.

73 olecules could prove useful in terahertz and optical devices controlled by pure spin currents.

74 les offer unparalleled potential for THz and optical devices controlled by pure spin currents: a low-

75 er, it is challenging to scale the nonlinear optical devices down to the nanoscale dimension due to r

76 onolayer WS2 offers great promise for use in optical devices due to its direct bandgap and high photo

77 ual field is brought into view by the use of optical devices; eye movement-based therapies, in which

78 ted in the nanometer scale using a nonlinear optical device for the first time.

79 se of electrostatic gates to define electron-optical devices in graphene.

80 he widespread adoption of plasmonic and nano-optical devices in real-life applications is the difficu

81 d that the time is ripe for considering many optical devices in the seismic and geophysical context.

82 hene-based materials, a basic ingredient for optical devices, induced by quantum confinement.

83 ic crystals that are particularly suited for optical device integration using a lithographic layer-by

84 Conventional design of all-optical devices is based on photon propagation and inter

85 In addition, metamaterial-based optical devices lend themselves to considerable miniatur

86 nhancing light-matter interaction in quantum optical devices, low-threshold lasers with minimal power

87 In quantum optical devices, microcavities can coax atoms or quantum

88 The optical device mimics the design of the crystalline lens

89 ynthetic applications from photocatalysis to optical devices need to demonstrate increased ability to

90 ics provides a route to develop ultracompact optical devices on a chip by using extreme light concent

91 ssipative two-photon regime in silicon-based optical devices, or possess small nonlinearities.

92 By using optical devices, originally developed for astronomy, who

93 Numerous optical technologies and quantum optical devices rely on the controlled coupling of a loc

94 ace structures, biomedical devices, adaptive optical devices, smart dry adhesives and fasteners.

95 akes it possible to dramatically miniaturize optical devices so as to integrate them into silicon chi

96 evelopment and study of solid-state electron-optical devices such as beam splitters and quantum point

97 room-temperature 'prototype' PNLC-based all-optical devices such as optical diode, optical transisto

98 microwave circuits with planar acoustic and optical devices such as phononic and photonic crystals.

99 this design concept by showing how important optical devices such as quantum memory and optical filte

100 dings may pave the way for low-power quantum optical devices, surpassing quantum limits on position a

101 rm demonstrates a path towards an integrated optical device that can be utilized for a wide variety o

102 nnections relies on the development of micro-optical devices that are integrated with the microelectr

103 ght on the nanoscale, enabling ultra-compact optical devices that exhibit strong light-matter interac

104 tegy for realizing a wide range of broadband optical devices that exploit the unique properties of me

105 ng resonators are refractive index-sensitive optical devices that feature good sensitivity and tremen

106 hough they can serve as the basis for unique optical devices that mould the flow of light in unconven

107 ing principles for the generalized design of optical devices that operate from the mid- to far-infrar

108 Flat optical devices thinner than a wavelength promise to rep

109 ave recently been proven to provide superior optical devices to those on conventional c-plane substra

110 ical states of light and sound.Nonreciprocal optical devices traditionally rely on magnetic fields an

111 namics motivate the invention of a series of optical devices triggered by moisture, including anticou

112 at large scale and at high yield, we design optical devices using a standard microelectronics foundr

113 Theoretical considerations show that all-optical devices using photonic crystal designs promise t

114 an unconventional route for engineering all-optical devices using the photon's internal degrees of f

115 pproach toward development of transformation optical devices where active all-optical control of the

116 ctors and other metal or semiconductor based optical devices where resistive losses and power consump

117 cture thereby producing a broadband low-loss optical device with a desired response.

118 rier types to create electronic analogues of optical devices with both positive and negative indices

119 Metamaterials have the potential to create optical devices with new and diverse functionalities bas

120 hitectures have enabled a panoply of tunable optical devices with the ability to perform useful funct

121 rest due to its potential for future magneto-optical devices with ultra-high sensitivity and ultra-fa

122 -are poised to form the platform for tunable optical devices with unprecedented functionality and per

123 be processed directly by metamaterial-based optical devices without any additional coupling componen