ライフサイエンスコーパス: ultramicroelectrode

1 clic voltammetry and chronoamperometry at an ultramicroelectrode.

2 y application using a reusable iridium array ultramicroelectrode.

3 ning ferrocene upon each collision onto a Pt ultramicroelectrode.

4 dsorbing partly on the glass surrounding the ultramicroelectrode.

5 on of single femtoliter water droplets on an ultramicroelectrode.

6 dox enzyme molecule when it collides with an ultramicroelectrode.

7 tration of approximately 100 muM on a 25 mum ultramicroelectrode.

8 ells were measured by oxygen reduction at an ultramicroelectrode.

9 tic reduction of water at both disk and ring ultramicroelectrodes.

10 lectrodes that were previously restricted to ultramicroelectrodes.

11 centimeter) electric pulse delivered across ultramicroelectrodes.

12 and can be conveniently detected on Au and C ultramicroelectrodes.

13 symmetric single graphene nanoplatelets onto ultramicroelectrodes.

14 imilarly during voltammetric measurements on ultramicroelectrodes.

15 n array containing roughly 1000 carbon fiber ultramicroelectrodes.

16 -based MEAs consist of 16 4-mum-width square ultramicroelectrodes, 25 3-mum-width square ultramicroel

17 ity of a gold-plated iridium Nano-Band array ultramicroelectrode (6 microm by 0.2 microm, 64-microm i

18 tramicroelectrodes, or 36 2-mum-width square ultramicroelectrodes, all inside a 40 x 40 mum square SU

19 ed by chronoamperometric experiments with an ultramicroelectrode and digital simulations.

20 ed by chronoamperometric experiments with an ultramicroelectrode and digital simulations.

21 voltage signal is continuously scanned on an ultramicroelectrode and its faradaic signal is recorded.

22 containing a single faradic electrode (a Pt ultramicroelectrode) and a blocked (polarized) electrode

23 the electrode size (from macroelectrodes to ultramicroelectrodes) and shape (spherical and disc).

24 impacts of single nanoparticles (NPs) on an ultramicroelectrode are coupled with optics to identify

25 t in conjunction with a microfabricated gold ultramicroelectrode array (Au-UMEA).

26 monstrate that the amorphous silicon carbide ultramicroelectrode arrays (a-SiC UMEAs) provide selecti

27 First, opaque carbon ultramicroelectrode arrays (CUAs) were characterized for

28 Thin-film platinum ultramicroelectrode arrays (MEAs) with subcellular micro

29 Transparent carbon ultramicroelectrode arrays (T-CUAs) were made using a pr

30 ox-active pyocyanin using transparent carbon ultramicroelectrode arrays (T-CUAs), which were made usi

31 using recently developed transparent carbon ultramicroelectrode arrays (T-CUAs).

32 e SECM diffusion problem with a pair of disk ultramicroelectrodes as a tip and a substrate is solved

33 have been investigated using an immobilized ultramicroelectrode assembly.

34 oluene droplet irreversibly collides with an ultramicroelectrode biased sufficiently positive for con

35 hydroquinone from the tip to a carbon fiber ultramicroelectrode (CF UME) provides a means of quantif

36 collisions to the surface of a carbon fiber ultramicroelectrode (CFUME).

37 for cobalt, nickel, and lead ions on carbon ultramicroelectrodes (CUMEs), ca. 500 nm radii.

38 However, decreasing the size of the ultramicroelectrode decreases the range of values that s

39 aracterizing nanoelectrode (NE) ensembles of ultramicroelectrode dimensions (UME-NEEs) as a function

40 The toluene droplet wetting the ultramicroelectrode effectively creates a microgap, wher

41 to glass, which is often used to encapsulate ultramicroelectrodes employed in SECM, is also found to

42 Pt Black ultramicroelectrodes exhibited the greatest sensitivity

43 nsitive for pH measurement compared to W/WO3 ultramicroelectrodes for pH measurement.

44 y recorded from eight independent 2-mum-wide ultramicroelectrodes from a single PC12 cell showing tha

45 n the amperometric current-time trace if the ultramicroelectrode generates the enzyme cofactor.

46 of the NP when it contacts a Hg-modified Pt ultramicroelectrode (Hg/Pt UME).

47 Mercury-capped platinum ultramicroelectrodes (Hg/Pt UMEs) were tested as probes

48 oltammetry and transient amperometry on a Pt ultramicroelectrode in aqueous solutions containing vari

49 The ultramicroelectrodes in each MEA are tightly defined in

50 the adsorption energy of nanoparticles at an ultramicroelectrode interface.

51 al reflectance cell containing a 25 mum gold ultramicroelectrode is employed to achieve an electroche

52 we show that electrochemistry performed with ultramicroelectrodes is perfectly suitable to monitor an

53 o nanoplatelets coming into contact with the ultramicroelectrode, making an electrical connection, an

54 Ultramicroelectrode measurements, with high mass transfe

55 nalysis of voltammetry experiments involving ultramicroelectrodes modified with thin, insulating oxid

56 Cyclic voltammograms for these ultramicroelectrodes obtained in perchloric acid show si

57 narrower distribution than at a conventional ultramicroelectrode of equal diameter.

58 ultramicroelectrodes, 25 3-mum-width square ultramicroelectrodes, or 36 2-mum-width square ultramicr

59 usional broadening, is demonstrated using an ultramicroelectrode probe to map the convective flux of

60 Thanks to ultramicroelectrodes protected against the high electric

61 his was fulfilled by using dedicated working ultramicroelectrodes (Pt-black UMEs) and protecting them

62 drolysis of tetramethoxysilane along with an ultramicroelectrode (r = 13 microns) and a Ag/AgCl refer

63 tion of aptamer-based sensors to planar disk ultramicroelectrodes (r ~ 5-10 mum).

64 a microdroplet placed on the surface of a Au ultramicroelectrode (radius ~ 6.25 mum).

65 An ultramicroelectrode sensitive to H(2)O(2) (black platinu

66 ght of Ag electrodeposited on a 25 microm Pt ultramicroelectrode, showed a fastest uptake in the pres

67 ueous, aptamer-containing microdroplet on an ultramicroelectrode submerged in an organic continuous p

68 ic responses of n-type Si(100) semiconductor ultramicroelectrodes (SUMEs) immersed in air- and water-

69 en a microdroplet irreversibly adsorbs to an ultramicroelectrode surface (radius ~ 5 um).

70 lisions between insulating microbeads and an ultramicroelectrode surface are correlated to electroche

71 gle nanodroplets irreversibly adsorb onto an ultramicroelectrode surface, enzymatic activity is appar

72 ly blocking flux of ferrocenemethanol to the ultramicroelectrode surface.

73 ingle nanoscale entities one-at-a-time on an ultramicroelectrode surface.

74 conductive graphene nanoplatelets on biased ultramicroelectrode surfaces can be observed in an amper

75 An organic droplet is placed on an ultramicroelectrode surrounded by an aqueous solution of

76 yclic voltammetry and chronoamperometry with ultramicroelectrodes the current response to electrolyte

77 ret the effects of substrate shielding on an ultramicroelectrode tip during a recording of iT versus

78 by examining the amperometric response of an ultramicroelectrode tip near a substrate.

79 An ultramicroelectrode tip placed close to the substrate el

80 esence of glucose was measured using a Clark ultramicroelectrode to determine the oxygen concentratio

81 rochemical measurements on microparticles at ultramicroelectrodes to explore this effect.

82 ng and growing a single Pt NP on a tunneling ultramicroelectrode (TUME) that produces 1-40 nm or grea

83 articles (NPs) undergoing collisions at a Au ultramicroelectrode (UME) (5 mum radius) using electroca

84 of colloidal ZnO nanoparticles (NPs) on a Hg ultramicroelectrode (UME) and its application to determi

85 to a lithographically fabricated addressable ultramicroelectrode (UME) array patterned with 25 regula

86 M KCl solution using a 3.5 mum radius carbon ultramicroelectrode (UME) as the SECM tip and a 25 mum r

87 lectrochemical measurements using a platinum ultramicroelectrode (UME) as the working electrode on a

88 We have developed glucose and lactate ultramicroelectrode (UME) biosensors based on glucose ox

89 Under these conditions, voltammetry with an ultramicroelectrode (UME) can measure copper concentrati

90 en circuit potential (OCP) of a measuring Au ultramicroelectrode (UME) changes when Pt NPs collide wi

91 itude compared to SECM based on conventional ultramicroelectrode (UME) disk electrodes.

92 activities, which is based on a transparent ultramicroelectrode (UME) fabricated by using two-step p

93 tion of a nanopipet probe with an integrated ultramicroelectrode (UME) for concurrent SICM and scanni

94 a method of precisely positioning a Hg-based ultramicroelectrode (UME) for scanning electrochemical m

95 of single Pt nanoparticles (NPs) on a carbon ultramicroelectrode (UME) in a hydrazine (N(2)H(4)) solu

96 g current (ac) waveform is applied to a disk ultramicroelectrode (UME) in an electrochemical cell, on

97 x imaging is also carried out over a Pt-disk ultramicroelectrode (UME) in the feedback mode and subst

98 of collisions of nanoparticles (NPs) with an ultramicroelectrode (UME) is a measure of the solution c

99 An ultramicroelectrode (UME) is placed closely above the su

100 CO2 was reduced at a hemisphere-shaped Hg/Pt ultramicroelectrode (UME) or a Hg/Au film UME, which wer

101 k acid (producing hydrogen) at a "submarine" ultramicroelectrode (UME) placed in the aqueous subphase

102 Formic acid was generated at a Hg on Au ultramicroelectrode (UME) tip by reduction of CO(2) in a

103 osition modulation (TPM) involves moving the ultramicroelectrode (UME) tip of a scanning electrochemi

104 provided by multiple feedback curves of the ultramicroelectrode (UME) tip.

105 Boron-doped diamond (BDD) ultramicroelectrode (UME) tips were fabricated by the gr

106 deposited on the conducting Pt surface of an ultramicroelectrode (UME) to block electron transfer (ET

107 ) droplets that are dispersed in water on an ultramicroelectrode (UME) to probe the ion transfer acro

108 We detected single living bacterial cells on ultramicroelectrode (UME) using a single-particle collis

109 An inert carbon fiber ultramicroelectrode (UME) was held at a potential where

110 First, voltammograms were recorded at a Pt ultramicroelectrode (UME) with a variable of free chlori

111 py (SECM) in order to map pH over a platinum ultramicroelectrode (UME), generating hydroxide ions (OH

112 By ejecting NPs onto a closely positioned ultramicroelectrode (UME), one can study single-particle

113 dation in aqueous solution at a carbon fiber ultramicroelectrode (UME), used as the substrate, illust

114 num electrode and a 25 mum diameter platinum ultramicroelectrode (UME), we captured the rapid kinetic

115 r small cluster, up to 9 atoms, on a bismuth ultramicroelectrode (UME).

116 ied via emulsion droplet reactor (EDR) on an ultramicroelectrode (UME).

117 th selective electrochemical reduction on an ultramicroelectrode (UME).

118 chronoamperometry during a collision with an ultramicroelectrode (UME).

119 electrochemical (PEC) current measured at an ultramicroelectrode (UME).

120 ed by optical tweezers in the vicinity of an ultramicroelectrode (UME).

121 ced localized surface modifications using an ultramicroelectrode (UME).

122 ia feedback mode SECM using a 25 mum Pt disk ultramicroelectrode (UME).

123 rO(x) NP) collisions on a NaBH(4)-treated Pt ultramicroelectrode (UME).

124 oncentration of potassium ferrocyanide on an ultramicroelectrode (UME, radius </=150 nm), time-resolv

125 murine cytomegalovirus (MCMV) on a platinum ultramicroelectrode (UME, radius of 1 mum).

126 Hg/Pt hemispherical ultramicroelectrodes (UMEs) (25-microm diameter) were pr

127 a technique to rapidly and directly examine ultramicroelectrodes (UMEs) by white light vertical scan

128 rogeneous electrochemical kinetic study with ultramicroelectrodes (UMEs) even for fast redox systems,

129 Ultramicroelectrodes (UMEs) fabricated from networks of

130 simple method of preparation of carbon paste ultramicroelectrodes (UMEs) for use as probe tips in sca

131 and use of a massive array of closed bipolar ultramicroelectrodes (UMEs) in electrochemical imaging a

132 collisions at 10 mum diameter carbon and Pt ultramicroelectrodes (UMEs) is reported.

133 epared an individual Pt deposit on Bi and Pb ultramicroelectrodes (UMEs) such as a single isolated at

134 The OCP of platinum ultramicroelectrodes (UMEs) was determined in solutions

135 ingle Lactococcus lactis bacteria at Pt disk ultramicroelectrodes (UMEs) were characterized using ele

136 Platinum ultramicroelectrodes (UMEs) were polarized sufficiently

137 roducible method for the fabrication of disk ultramicroelectrodes (UMEs) with controlled geometry is

138 llisions of murine cytomegalovirus (MCMV) on ultramicroelectrodes (UMEs), extending the observation o

139 novel fabrication protocol for Hg disc-well ultramicroelectrodes (UMEs), which retain access to stri

140 method was developed for the preparation of ultramicroelectrodes (UMEs).

141 xperiment was performed using amperometry on ultramicroelectrodes (UMEs).

142 ayers electrodeposited on 25 mum diameter Pt ultramicroelectrodes (UMEs).

143 ation profiles of redox species generated on ultramicroelectrodes (UMEs).

144 ve pH 6.5, to map the pH adjacent to various ultramicroelectrodes undergoing electrochemical processe

145 nning electrochemical microscopy (SECM) with ultramicroelectrodes using the tip generation/substrate

146 Ultramicroelectrode voltammetry reveals facile electron

147 ng, ECL of a single nanobelt deposited on an ultramicroelectrode was observed.

148 (W/WO3) and iridium oxide (Pt/IrO2) working ultramicroelectrodes were developed.

149 Fabricated ultramicroelectrodes were electrochemically characterize

150 The ultramicroelectrodes were employed for the detection of

151 egarding O2 and H2O2 detection while Pt/IrO2 ultramicroelectrodes were more sensitive for pH measurem

152 A micrometer-sized Au ultramicroelectrode, when connected in parallel to a Pt

153 Ring ultramicroelectrodes, which are of particular interest a

154 g a 1,2-dichloroethane microdroplet onto the ultramicroelectrode with a microinjector, we are able to

155 be was synthesized by functionalizing a gold ultramicroelectrode with a self-assembled monolayer of 4

156 MEAs consisting of 16, 25, and 36 square ultramicroelectrodes with respective widths of 4, 3, and

157 tional electrodes, was extended for use with ultramicroelectrodes, with a focus on its application in

158 ed sensor fabrication and miniaturization on ultramicroelectrodes without the need for electrode surf