ライフサイエンスコーパス: thick film

1 ontrast to three-dimensional precipitates in thick films).

2 he robust ferroelectricity for the sub-10 nm thick film.

3 to approximately 1.5 for the thinnest 9.5-nm-thick film.

4 h optical transmission through the optically thick film.

5 ace via one of its -NC groups to form a 2-nm-thick film.

6 ts as large as 35 muC cm(-2) across a 150 nm thick film.

7 employed to fabricate crack-free P(VDF-TrFE) thick films.

8 ed processing by spin-coating into nanometer-thick films.

9 nhanced electronic effects not realizable in thick films.

10 tated long-distance charge transport through thick films.

11 phase La2Ni2O5 (Ni(2+)) for a few unit-cell thick films.

12 rpotential of approximately 550 mV for 10 nm thick films.

13 beneficial for the multilayer deposition of thick films.

14 ty is observed at lower temperatures than in thick films.

15 itch the polarization of approximately 10 nm thick films.

16 h is otherwise difficult to characterize for thick films.

17 g the conductivity of over 0.1 S cm(-1) in a thick film after exposure to air for one week, to the be

18 10(-6) M for Fe3+ were obtained with 300 nm thick films after 30 min of exposure to a quiescent samp

19 overslips, yielding approximately 1.4 microm thick films after curing.

20 s are detected at the downstream gold-coated thick-film amperometric detector at different migration

21 chined capillary electrophoresis chip with a thick-film amperometric detector, is described.

22 lectrochemically at a downstream gold-coated thick-film amperometric detector.

23 ess conductivity detector with an end-column thick-film amperometric detector.

24 to the air/subphase interface to form a 20 A thick film and showed a critical micelle concentration o

25 new avenue for strain control in relatively thick films and also promises new forms of ordered nanos

26 luster nuclearity is greater in a relatively thick film ( approximately 40-50 nmol Co ions/cm(2)) dep

27 an be formed on BP, and that these monolayer-thick films can passivate the BP surface and inhibit oxi

28 indicated from comparison to a commonly used thick-film carbon detector.

29 ,4,6-trinitrotoluene (vs RSD of 10.8% at the thick-film carbon electrode).

30 nts of the dissolved metal tag at single-use thick-film carbon electrodes.

31 nsport in thin films to "lossy" transport in thick films confirms that electron hopping is involved i

32 ed to produce uniform, crack-free micrometer-thick films, CulnSe2 nanocrystals were tested in prototy

33 detected amperometrically at the end-column thick-film detector.

34 Tested as thick film electrode in a Li-ion battery half-cell, SiCN

35 n of the DNA-linked particle assembly onto a thick-film electrode transducer.

36 ti-HSA was immobilized onto the surface of a thick-film electrode, followed by a competition between

37 a number of polymer systems in monolayer and thick film forms are reported.

38 length of 500 nm, for example, 13- and 79-nm-thick films have transparencies of 47 and 10% and sheet

39 eter) interconnected in a mesoporous, 10 mum thick film immersed in Li(+)-containing CH(3)CN electrol

40 ylate and methyl methacrylate yielded 100 nm thick films in 10 and 60 min, respectively.

41 The pH-induced color change in a ~400 mum thick film is complete within 40 and 60 s.

42 ol; (iii) yields a 45-s response time (2-mum-thick film); (iv) is completely reversible (6% relative

43 zed by amalgamating several state-of-the-art thick film, laser printing, solid-state potentiometry, f

44 widely used as an adhesion layer in organic thick film metallization as well as a top metal contact

45 om an aqueous solution to create a monolayer-thick film of Ag nanoparticles.

46 efined as presence of asexual parasites on a thick film of blood and was treated with sulfadoxine/pyr

47 A 0.1-0.2-mum-thick film of dimethyl polysiloxane stationary phase is

48 Antibodies were immobilized onto a 10-nm-thick film of gold which had been previously deposited o

49 e-immobilized receptor across the micrometer-thick film of liquid crystal is fast (on the order of se

50 en change in the orientation of a micrometer-thick film of liquid crystal.

51 nsional hydrogenic levels above a micrometer-thick film of liquid helium, is proposed as an easily ma

52 g, 0.25-mm-i.d. capillary using a 0.5-microm-thick film of nonpolar dimethyl polysiloxane coupled in

53 is brought into contact with an 80-nanometer-thick film of poly(methylmethacrylate) supported on n-do

54 m metal capillary column coated with a 7 mum thick film of polydimethylsiloxane (PDMS).

55 An electropolymerized 60 nm thick film of POT coated with a plasticized PVC membrane

56 nd PbI(2) in gamma-butyrolactone on a 400 nm thick film of TiO(2) (anatase) nanosheets exposing (001)

57 0(4) Ohms cm and 3 x 10(4) Ohms cm for 35 nm thick films of 1 and 2, respectively.

58 on of vapor-deposited polycrystalline 188 nm thick films of 1 results in a 140 +/- 20% yield of tripl

59 The orientation and dynamics of two 40-nm thick films of 4-n-pentyl-4'-cyanobiphenyl (5CB), a nema

60 increase the Curie temperature of micrometre-thick films of BaTiO(3) to at least 330 degrees C, and t

61 zation of a photodetector based on optically-thick films of dense, aligned, and macroscopically long

62 Chemiresistor arrays comprised of 50 nm thick films of metallophthalocyanines (MPcs) are redox s

63 Electrochemical analysis of thick films of micrometer-sized, insulating niobia parti

64 (OER) electrocatalytic properties of ~2-3 nm thick films of NiO(x), CoO(x), Ni(y)Co(1-y)O(x), Ni(0.9)

65 ectricity in strain-free epitaxial nanometer-thick films of otherwise nonferroelectric strontium tita

66 The glass sample stick is composed of 20-nm-thick films of permalloy that have square or rectangular

67 When 0.18-5.34-microm-thick films of silicone block polyimide polymers were de

68 images of a substrate immersed in 70-microL-thick films of solution were obtained in the generator-c

69 s in the orientations of 1- to 20-micrometer-thick films of supported LCs, thus corresponding to a re

70 olve the thin film structure for 2 and 20 nm thick films of tetraceno[2,3-b]thiophene and detect only

71 Here, we synthesize one-atom-thick films of the radioactive isotope (125)I on gold th

72 ion of conductive nanoparticles in a polymer thick film on an organic substrate (PTFOS) that induces

73 nsors were fabricated by deposition of 50 nm thick films on interdigitated gold electrodes via organi

74 iencies up to 10.8%, fill factors up to 77%) thick-film polymer solar cells for multiple polymer:full

75 njugated polymer leading to high-performance thick-film polymer solar cells with a V(OC) of 0.88 V an

76 The 2 nm thick film possesses a polarization as high as the bulk

77 y to acquire IR spectral data from nanometer-thick films retained upon forced dewetting of a solid su

78 ode immunosensor system was fabricated using thick-film screen-printing technology.

79 ignificant mass transport limitations within thick-film sulfur cathodes.

80 For the 1.2 nm thick film, the polarization reaches approximately 50 mi

81 and ability to form deposits that range from thick films to submonolayer coatings, derive from the re

82 applied magnetic fields were achieved in the thick films via incorporation of a periodic array of ext

83 be further employed to fabricate micrometer-thick films with bifunctional luminescent and superhydro

84 and nanoscale substrates, and the growth of thick films with intermediate strain-relaxed buffer laye

85 This knowledge is used to produce thick films with remarkable Ic(H) and nearly isotropic a