ライフサイエンスコーパス: nanolithography

1 ized microscale arrays fabricated by dip-pen nanolithography.

2 hermal, in addition to conventional, dip-pen nanolithography.

3 ts using nanoshaving, an AFM-based method of nanolithography.

4 s such as real-time biomolecular imaging and nanolithography.

5 microfluidics, capillary chromatography, and nanolithography.

6 ies and thereby patterns produced in dip-pen nanolithography.

7 e exploited to enhance patterning using soft nanolithography.

8 ducting polymers deposited within by dip-pen nanolithography.

9 tures within libraries generated via dip-pen nanolithography.

10 atomic force microscopy technique of dip-pen nanolithography.

11 r, often relies on complicated and expensive nanolithography.

12 ment, establishes a new paradigm for polymer nanolithography, allowing rapid (of the order of millise

13 tics of polymer crystal growth using dip-pen nanolithography and an atomic force microscope tip coate

14 Fabricated using three-dimensional colloidal nanolithography and atomic layer deposition, the process

15 d technology, from molecular spectroscopy to nanolithography and biomedical procedures.

16 e of silk film as a biofunctional medium for nanolithography and data storage.

17 But writing methods such as dip-pen nanolithography and ink-jet printing are either confined

18 wever, existing technologies such as dip-pen nanolithography and inkjet printing are currently unsuit

19 rocontact printing, inkjet printing, dip-pen nanolithography and microfluidic probes.

20 d to combine scanning probe microscopy (SPM) nanolithography and modified SPM break junction techniqu

21 th common patterning methods such as dip-pen nanolithography and multichannel microfluidic delivery d

22 chemical syringe include fluid dispensing in nanolithography and pumping in microfluidic systems.

23 rs using atomic force microscopy (AFM)-based nanolithography and subsequent selective immobilization

24 escribe a protocol that combines solid-state nanolithography and supported lipid membrane techniques

25 ncluding excitation of plasmonic waveguides, nanolithography, and optical sensing.

26 fully patterned on gold surfaces via dip-pen nanolithography, and the predicted molecular orientation

27 patial-frequency template, will be useful in nanolithography applications such as the formation of hi

28 ta storage, noncontact sensing, imaging, and nanolithography applications.

29 ity and self-assembly that will guide future nanolithography applications.

30 n nanowire was fabricated using the top-down nanolithography approach, through nanostructuring of sil

31 ion bombardment, electron beam drilling, and nanolithography, are worthy of a critical review.

32 micron-scale focal spots for high-throughput nanolithography, as they uniquely feature large numerica

33 m of the inks most typically used in dip-pen nanolithography by patterning both 16-mercaptohexadecano

34 d shallow compartments produced by STM-based nanolithography carried out on a graphite surface with a

35 transmission efficiency with applications to nanolithography, data storage, and bio-chemical sensing.

36 A direct-write "dip-pen" nanolithography (DPN) has been developed to deliver coll

37 Dip pen nanolithography (DPN) involves the direct transfer of an

38 Dip-pen nanolithography (DPN) is a scanning probe microscopy-bas

39 Dip-pen nanolithography (DPN) is becoming a popular nano-pattern

40 Dip-pen nanolithography (DPN) is becoming a popular technique to

41 anoplotter capable of doing parallel dip-pen nanolithography (DPN) is reported.

42 this paper, we demonstrate that the dip pen nanolithography (DPN) method can be used to precisely fu

43 This technique relies on either dip-pen nanolithography (DPN) or polymer pen lithography (PPL) t

44 We demonstrate the use of dip-pen nanolithography (DPN) to crystallize proteins on surface

45 The use of direct-write dip-pen nanolithography (DPN) to generate covalently anchored, n

46 es and use microcontact printing and Dip-Pen Nanolithography (DPN) to pattern alkanethiols with both

47 Dip-Pen Nanolithography (DPN) uses an AFM tip to deposit organic

48 A scanning probe method, dip-pen nanolithography (DPN), can be used to pattern monolayers

49 as microcontact printing (muCP) and dip-pen nanolithography (DPN).

50 surfaces has been demonstrated with dip pen nanolithography (DPN).

51 were patterned onto gold surfaces by dip-pen nanolithography (DPN).

52 terostructures using electrochemical dip-pen nanolithography (E-DPN).

53 This DNA nanolithography enables wafer-scale patterning of two-di

54 We introduce Electro Pen Nanolithography (EPN), a nanoscale chemical patterning t

55 that TERS is promising to be plasmon-induced nanolithography for organic 2D materials.

56 organosilane MNLs are used as lubricants, in nanolithography, for corrosion protection and in the cry

57 The nanolithography-free nanopatterned device should facilit

58 The precise and versatile nanolithography in a ferroic material and the stability

59 Using atomic force microscopy-based nanolithography, in conjunction with chosen surface chem

60 Maskless nanolithography, including electron-beam and scanning-pr

61 Dip-pen nanolithography is employed to directly pattern monolaye

62 atterned metasurfaces, which require complex nanolithography, limiting their practical applications,

63 eous-acid clusters are relevant to inorganic nanolithography, metal-organic frameworks (MOFs), cataly

64 The material can be patterned using standard nanolithography methods.

65 ons and can be processed by the conventional nanolithography methods.

66 ains in the solid state with applications in nanolithography, nanotemplating, and nanocatalysis.

67 state three-terminal platforms created using nanolithography, or aqueous media.

68 we demonstrate that a novel form of dip-pen nanolithography provides an effective means to pattern t

69 One approach to visible-light nanolithography (resolution augmentation through photo-i

70 -tip, soft-spring lithography is a versatile nanolithography strategy that should be widely adopted b

71 This extension of the dip-pen nanolithography technique provides an easy methodology t

72 ting, an atomic force microscopy (AFM)-based nanolithography technique, to fabricate thiolated DNA na

73 canning probe and large-area cantilever free nanolithography techniques, resulting in a library of de

74 ensive and time consuming using conventional nanolithography techniques.

75 Current nanolithography technologies are unable to recreate 4D n

76 Here we develop a metallized DNA nanolithography that allows transfer of spatial informat

77 However, many of the approaches to nanolithography that are used to pattern inorganic mater

78 w-cost, high-throughput approach to maskless nanolithography that uses an array of plasmonic lenses t

79 These studies demonstrate that biomolecular nanolithography (the arrangement of nanoscale building b

80 In the context of nanolithography, this behavior allows the high spatial s

81 In light of the scalability limitations of nanolithography, this work presents an important step an

82 ly used in laser-assisted nanopatterning and nanolithography to pattern nanoscale features on a large

83 Such particles are made by (i) using dip-pen nanolithography to prepare nanoreactors consisting of me

84 This work demonstrates the potential of 3D nanolithography towards wafer-scale production, showing

85 d novel lithography technique--electrostatic nanolithography using atomic force microscopy--that gene

86 Dip-pen nanolithography was used to construct arrays of proteins

87 Electron beam nanolithography was used to fabricate 20 x 20 arrays of

88 Using tip-enhanced near-field infrared nanolithography, we demonstrate versatile manipulation a

89 NFP combines the high-resolution of dip-pen nanolithography with the efficient continuous liquid fee

90 y merges the feature size control of dip-pen nanolithography with the large-area capability of contac