ライフサイエンスコーパス: electropolymerization

1 Au-glass slides by oxidative potentiodynamic electropolymerization.

2 d and subjecting it to 13 cycles of dopamine electropolymerization.

3 ubsequently coupled to the sensor surface by electropolymerization.

4 crystal resonator of EQCM by potentiodynamic electropolymerization.

5 been synthesized and used as substrates for electropolymerization.

6 d-casting, and increased reproducibility for electropolymerization.

7 For this purpose, we prepared by electropolymerization a conductive polymer poly-(aniline

8 e influenced by the applied potential during electropolymerization and by film thickness, both of whi

9 tructure is fabricated by thermal oxidation, electropolymerization and electrodeposition.

10 We report here electropolymerization as a strategy for increasing inter

11 ic receptor was deposited by potentiodynamic electropolymerization as a thin film on an Au film elect

12 osphoryl-n-alkyl)pyrrole film established by electropolymerization at the previously formed polypyrro

13 phenol monolayer-modified Au electrode by co-electropolymerization by repetitive cyclic voltammetry s

14 The electropolymerization conditions for obtaining almost id

15 the gold sensing platform where the optimal electropolymerization conditions were determined.

16 tio of monomer and template ratio, number of electropolymerization cycles, mass deposited in each cyc

17 A general electropolymerization/electro-oligomerization strategy i

18 quartz crystal resonators by potentiodynamic electropolymerization from solution of FU, Ade-BTM, and

19 concentration, scan number and scan rate of electropolymerization) have been optimized.

20 Immobilization of DNA probes during pyrrole electropolymerization is a simple and efficient strategy

21 tion of monomer concentration and potential, electropolymerization leads either to solid nanowires or

22 The electropolymerization method we studied here forms a cas

23 ypyrrole on a platin electrode surface using electropolymerization method.

24 th the working surface modified in course of electropolymerization of 3-aminophenylboronic acid (3-AP

25 icrorocket is prepared by membrane-templated electropolymerization of 3-aminophenylboronic acid monom

26 rtz crystal microbalance (EQCM) electrode by electropolymerization of 3-TAA in presence of mel templa

27 quinone(PQ)-modified electrodes, prepared by electropolymerization of a phenanthrenequinone-pyrrole d

28 acid) (PAA) were formed by Zn(II)-catalyzed electropolymerization of acrylic acid (AA) in the presen

29 I increases the electrode surface area while electropolymerization of aniline increases the number of

30 immunosensor platform, produced via in situ electropolymerization of aniline onto a screen-printed g

31 ical strategy adopted involves deposition by electropolymerization of biotinylated polythiophene film

32 Electropolymerization of bithiophene-substituted cadmium

33 adsorption of Ru complex and enzyme and then electropolymerization of coatings.

34 A new methodology for selective electropolymerization of conducting polymer films using

35 We show, for the first time, that electropolymerization of derivatized phenols can functio

36 Formed in situ via electropolymerization of functional imidazolium-type ion

37 s, the coatings are attributed to the direct electropolymerization of graphene oxide sheets via oxida

38 he sensing surfaces of SAW chip by oxidative electropolymerization of m-phenylenediamine (mPD) in the

39 8-OHdG assembled on a gold electrode through electropolymerization of monomer combined with the templ

40 lectrochemical immunosensor was developed by electropolymerization of N-(3-(4-(2-(4-hydroxyphenyl)pro

41 Electropolymerization of phenol was then employed to for

42 t the integration of a biosensor made by the electropolymerization of poly(toluidine blue O) (PTB) an

43 tive electrochemical sensor was developed by electropolymerization of pyrrole (PY) and molecularly im

44 zation steps for hybridization procedure and electropolymerization of pyrrole as well as detection fr

45 ix on a 245-microm graphite electrode during electropolymerization of pyrrole in the presence of PQQ.

46 n a glassy carbon electrode substrate by the electropolymerization of pyrrole in the presence of PQQ.

47 des fully made of Parylene-C, followed by an electropolymerization of the active area with the conduc

48 n the surface of electrodes (Au on glass) by electropolymerization of the aniline moiety.

49 Electropolymerization of the catalyst Ru(II)(bda)(4-viny

50 pencil graphite electrode (PGE) via one-step electropolymerization of the imprinted polymer composed

51 talytic microtubular engines are prepared by electropolymerization of the outer polymeric layer in th

52 The first involved entrapment of APSA during electropolymerization of the polyaniline.

53 Electropolymerization of thionine on a "preanodized" scr

54 MIP films were prepared by potentiodynamic electropolymerization of this complex with the imprintin

55 Oxidative electropolymerization of this monomer afforded the desir

56 polymers have been synthesized via oxidative electropolymerization of various bis(bithiophene)-substi

57 reated thin films by cyclic voltammetry (CV) electropolymerizations of the following phenolic functio

58 (MIP) film was deposited by potentiodynamic electropolymerization on a Pt disk electrode as well as

59 TAA) as functional monomer was fabricated by electropolymerization on gold surface.

60 Devices fabricated by polyphenol electropolymerization on one set of electrodes and Pd el

61 present in both compounds, undergo oxidative electropolymerization on platinum electrodes.

62 The films were deposited by potentiodynamic electropolymerization on the 10 MHz quartz resonators of

63 -NT) films were deposited by potentiodynamic electropolymerization on the Au-coated quartz crystal re

64 the o-phenylenediamine network via one-step electropolymerization on the surface of the modified pen

65 h enzymes immobilized onto Pt UMEs by either electropolymerization or casting) for scanning electroch

66 The electropolymerization parameters were optimized to get s

67 distinct potentials for the duration of the electropolymerization process, thereby generating a time

68 three functional groups: hydroxyl group for electropolymerization, quinone group for its transductio

69 Overlayer electropolymerization results in up to 30-fold enhanceme

70 A key role of the electrolyte used in electropolymerization (tetrabuthylammonium perchlorate a

71 an Au electrode by oxidative potentiodynamic electropolymerization to fabricate an electrochemical ch

72 The use of electropolymerization to prepare electrocatalytically an

73 along the fibre axis that is obtained during electropolymerization using nanoscale templates.

74 Consecutive electropolymerization using two different monomers furni

75 All other films continued to form by electropolymerization with successive CV cycles out to t