ライフサイエンスコーパス: silicon chip

1 ht is demonstrated in silica waveguides on a silicon chip.

2 l etching process, which produced a flexible silicon chip.

3 by demagnetisation of thin-film copper on a silicon chip.

4 on top of a thin SiO(2) layer deposited on a silicon chip.

5 s can be combined in a scalable fashion on a silicon chip.

6 res arranged horizontally or vertically on a silicon chip.

7 nels, reagent chambers, and a DNA microarray silicon chip.

8 reagent storage chambers, and DNA microarray silicon chip.

9 t, all-silicon, waveguide cavity on a single silicon chip.

10 eflected light at the surface of an oxidized silicon chip.

11 nic explants or mimicked on a multielectrode silicon chip.

12 idually addressable sites on a micromachined silicon chip.

13 a mass spectrometry electrospray source on a silicon chip.

14 um microcomb in a silica microresonator on a silicon chip.

15 ssential components can be integrated into a silicon chip.

16 ld-effect transistors integrated on a single silicon chip.

17 econfiguration of optical functionalities on silicon chip.

18 bits distributed across a 5 x 5 x 0.35 mm(3) silicon chip.

19 ed via an Aharonov-Bohm type experiment on a silicon chip.

20 nd larger scale quantum photonic circuits on silicon chips.

21 he NMR spectrometer electronics into 4-mm(2) silicon chips.

22 optical devices so as to integrate them into silicon chips.

23 s were immobilized onto microtiter plates or silicon chips.

24 toelectronic components onto CMOS-compatible silicon chips.

25 d lipid bilayers and the surface of oxidized silicon chips.

26 are mixed in inexpensive and CMOS compatible silicon chips.

27 hown plenty of room inside a living cell for silicon chips.

28 of data transfer for future high-performance silicon chips.

29 antitative nucleic acid mass spectrometry on silicon chips.

30 and functional microelements directly inside silicon chips.

31 ent of a 4 x 4 coherent crossbar (Xbar) as a silicon chip and validate experimentally its theoretical

32 olayers on gold by multiplexed analysis with silicon chips and low-cost electrospun nanofibers.

33 ates (such as buried electronic devices in a silicon chip); and three-dimensional imaging of cryogeni

34 Silicon chips are coated with copoly(DMA-NAS-MAPS), a te

35 Individual donors in silicon chips are used as quantum bits with extremely lo

36 However, silicon chips are vulnerable to hazards such as counterf

37 abrication and characterization of a planar, silicon-chip-based optomechanical crystal capable of co-

38 rtz to megahertz frequencies in a microscale silicon-chip-based sensor with >120 dB dynamic range.

39 tion volumes of PCR chips (a microfabricated silicon chip bonded to a piece of flat glass to form a P

40 anufactured on a 30-microm-thick crystalline silicon chip by chemical etching process, which produced

41 h to roll out Li-ion battery components from silicon chips by a continuous and repeatable etch-infilt

42 nonclassical light; in fact, CMOS-compatible silicon chips can be used to generate pairs of single ph

43 photoionization detectors (muPIDs) based on silicon chips can rapidly and sensitively detect volatil

44 We applied the recently introduced silicon chip coated with a functional polymer named copo

45 nt of a multiplex SNP detection system using silicon chips coated to create a thin-film optical biose

46 he biocompatibility of a collection of diced silicon chips coated with a variety of metal thin films,

47 rom hen's egg and cow's milk were spotted on silicon chips coated with copoly(DMA-NAS-MAPS) along wit

48 The isolation process is carried out on a silicon chip containing a five-by-five array of microloc

49 The test device consisted of a silicon chip containing individually addressable microba

50 icrom-deep channel etched in a 3.2-cm-square silicon chip, covered with a Pyrex wafer, and coated wit

51 rom-deep channels, etched in a 1.9-cm square silicon chip, covered with a Pyrex wafer, and statically

52 Silicon chips cut or cleaved from commercially available

53 with three electrodes integrated on the same silicon chip dedicated to the detection of herbicides in

54 We have micromachined a silicon-chip device that transports DNA with a Brownian

55 construction of multifunctional high-rise 2D silicon chips, enabling enhanced performance by exploiti

56 we here demonstrate an optical isolator on a silicon chip enforced by phase-matched parametric amplif

57 eration and processing and implement it on a silicon chip fabricated in a semiconductor manufacturing

58 mentary metal-oxide-semiconductor compatible silicon chips for wide-ranging applications.

59 and recently, optical waveguide circuits on silicon chips have demonstrated high levels of miniaturi

60 es, are localized within wells etched into a silicon chip in a regular 5 x 7 array.

61 Using a micropatterned silicon chip in combination with the high-speed Roadrunn

62 ction in liquid-core optical waveguides on a silicon chip in under ten minutes.

63 we demonstrate the cointegration on a single silicon chip of the front-end electronics of NMR and ESR

64 cells with specificity and sensitivity on a silicon chip platform.

65 and synthetic reconstituted lipids using our silicon chip platform.

66 synergistic combination of 2D materials with silicon chips promises a heterogeneous platform to deliv

67 The TIP system incorporates silicon chips tailored to monitor cellular ionic current

68 gorithm on an integrated waveguide silica-on-silicon chip that guides four single-photon qubits throu

69 ation and emission light at the surface of a silicon chip that has been layered with oxidized silicon

70 h nanoscale roughness fabricated on top of a silicon chip that monolithically integrates 4,096 micros

71 are detected by probes arrayed on a modified silicon chip that permits visible detection of both RIF-

72 timode optical transmission between separate silicon chips throughout a multimode-matched fibre.

73 use semiconductor logic gates organized on a silicon chip to enable efficient inter-gate communicatio

74 The implants consisted of small silicon chips (used to mimic small medical devices) that

75 00-fold reduction of the group velocity on a silicon chip via an ultra-compact photonic integrated ci

76 e nonlinear process of four-wave mixing on a silicon chip, we demonstrate a waveform measurement tech

77 gold and nickel thermopile, integrated on a silicon chip which was back-etched to span a 800-nm-thic

78 phisticated photonic quantum circuits onto a silicon chip, which will be of benefit to future quantum

79 ultiple soft polymer layers patterned around silicon chips, which act as surrogates for conventional

80 multiplexing microring modulator array on a silicon chip with a full data rate of 1 Tb/s.

81 as 15 degrees C at the targeted region on a silicon chip with a high ( approximately 1,300 W cm-2) h

82 We report the use of silicon chips with 16 DNA-modified electrodes (DME chips

83 Silicon chips with immobilized target DNAs were used for

84 ing lipid bilayers formed on microfabricated silicon chips with micrometer-sized holes.

85 nanometers) were synthesized on multiwindow silicon chips with silicon nitride membranes.

86 of this pattern are probed by manufacturing silicon chips with terraces of oxide layers of different

87 cal nanoantennas are densely integrated on a silicon chip within a footprint of 576 mum x 576 mum wit

88 trophoresis as well as electronic lysis on a silicon chip would provide essential sample-processing s