ライフサイエンスコーパス: counter electrode

1 otentiostat, with the bioanode acting as the counter electrode.

2 only 206 mV overpotential using a carbon-rod counter electrode.

3 exclusion anion-exchanger membrane reference/counter electrode.

4 by 15.8% compared to standard platinum (Pt) counter electrode.

5 to the reaction flask without separating the counter electrode.

6 silver pseudo-reference electrode and a gold counter electrode.

7 red in human whole blood using an IEDEM as a counter electrode.

8 A lithium sheet was used as the counter electrode.

9 ing the membrane as both the working and the counter electrode.

10 r even when it is completely shadowed by the counter electrode.

11 cell without generation of any products at a counter electrode.

12 ing SiO(2) film) that served as a capacitive counter electrode.

13 ode (r = 13 microns) and a Ag/AgCl reference/counter electrode.

14 electrode, and charge neutralization at the counter electrode.

15 charge separation process, the gap, and the counter electrode.

16 th electrolyte solution, and quasi-reference counter electrodes.

17 sitivity similar to an array with integrated counter electrodes.

18 ting nanospray interfaces with funnel shaped counter electrodes.

19 ted gold film working, pseudo-reference, and counter electrodes.

20 After optimization of the photo-anode and counter electrode, a photoelectric conversion efficiency

21 ration with physically separated working and counter electrodes, allowing true potentiometric titrati

22 nd growth of silver nanoparticles in the ITO counter-electrode, altering the optical extinction respo

23 m gaps, interspersed with an 800 microm wide counter electrode and 400 microm wide passive conductor,

24 alternating current (ac) waveform between a counter electrode and a working disk microelectrode.

25 microfluidic chamber with a steel metal shim counter electrode and Ag/AgCl reference electrode for el

26 ical sensing system that included a platinum counter electrode and enzymatic glutamate sensing electr

27 ighly concentrated pomegranate dye, graphite counter electrode and TiCl4 treatment of the photo-anode

28 ode arrays, each consist of shared reference/counter electrodes and 3 working electrodes has been use

29 working electrode, in conjunction with a Pt counter-electrode and Ag/AgCl reference electrode, movin

30 ing electrodes (0.78 mm(2) each), an iridium counter electrode, and a Ag/AgCl reference electrode pat

31 ap between the spray needle aperture and the counter electrode, and charge neutralization at the coun

32 The micropipet contains a reference-counter electrode, and the sample is connected as the wo

33 esigned using two bare pins as reference and counter electrodes, and a carbon-ink coated pin as worki

34 The working electrode and the counter electrode are placed in two separate channels to

35 magnitude at longer distances away from the counter electrode, but these same solutions show lower p

36 g electrode that was separated from a porous counter electrode by a Nafion membrane.

37 Required oxygen was produced at a Pt counter electrode by water electrolysis.

38 ile the platform that includes reference and counter electrodes can be reused.

39 tructure near the working electrode (WE) and counter electrode (CE) was higher than at other location

40 WE) and SERS substrate, a microfabricated Pt counter electrode (CE), and an external Ag/AgCl referenc

41 The working electrode and counter electrode consist of platinum and are functional

42 ong the channel (between the working and the counter electrodes) contribute, in part, to the lack of

43 the relative placement of the reference and counter electrodes (e.g., placed at the same or the oppo

44 that any polarization of the quasi reference counter electrodes, electro-osmotic effects, and perturb

45 ocatalytic applications, i.e., as a low-cost counter electrode for I(3)(-) reduction in dye-sensitize

46 ce electrode and the use of shared reference/counter electrodes for the array, in order to obtain a s

47 tal wires that act as reusable reference and counter electrodes has been developed.

48 rement system consists of three electrodes-a counter electrode held at highly negative potential that

49 analyte concentration on a silver (Ag) band counter electrode in a microchannel.

50 aphy, voltages of 0.0 to 0.3 volts (versus a counter electrode in a two-electrode cell) can drive cha

51 -GSH NCs is used as the photoanode with a Pt counter electrode in aqueous buffer solution (pH = 7), w

52 on of a bias applied between quasi-reference counter electrodes in the nanopipette and bulk solution,

53 enced by the presence of the working and the counter electrode inserted in the droplet.

54 The Ag band counter electrode is arranged longitudinally in a microc

55 e, coated with a silver film, serving as the counter electrode, is wrapped around the first wire.

56 er the tip and the substrate, or the tip and counter electrodes, is shown to increase proportionally

57 working electrodes inside the channel and a counter electrode located in the channel outlet reservoi

58 s as both an optical filter and a conductive counter-electrode of the rear dye-sensitized solar cell.

59 tential of 1.5 V was applied to the membrane/counter electrode pair, the percent of dead bacteria was

60 hich the potential between a quasi-reference counter electrode (QRCE) in an electrolyte-filled nanopi

61 by an applied bias between a quasi-reference counter electrode (QRCE) in the nanopipette and a second

62 n oscillating bias between a quasi-reference counter electrode (QRCE) in the SICM nanopipet probe and

63 ing electrolyte solution and quasi-reference counter electrodes (QRCE) in each barrel.

64 illed barrels, equipped with quasi-reference counter electrodes (QRCEs), in the end of a tapered micr

65 We found that the counter electrode reaction competes with the collector r

66 such a system, we studied the effect of the counter electrode reaction on the recorded generator cur

67 ilms (serving as the working, reference, and counter electrode, respectively) deposited by sputtering

68 nd shields serving as integrated working and counter electrodes, respectively, each with a nanoscale

69 uter shields serve as integrated working and counter electrodes, respectively, exhibiting a nanoscale

70 y connected to a potentiostat as working and counter electrodes, respectively.

71 ctrode, the arrays with shared reference and counter electrodes result in faster electron transfer ki

72 of the electrospray current collected by the counter electrode shows close correlation to the cone de

73 , we introduced an on top array of immersive counter electrodes that are individually addressed by a

74 ly integrated internal Ag film served as the counter electrode, the redox couple species were regener

75 ode by diazonium electroreduction, while the counter electrode was directly evaporated on top of the

76 microelectrodes and integrated reference and counter electrodes was developed and validated.

77 entials, versus Ag/AgCl reference and carbon counter electrodes, was facilitated by hydroquinone-medi

78 microm) together with on-chip reference and counter electrodes were fabricated using standard photol

79 r, and the same Ag/AgCl reference and carbon counter electrodes were shared with another piece of squ

80 ntial difference between the working and the counter electrodes, which in galvanic mode would provide

81 e function are demonstrated by modifying its counter electrode with a poly (vinylidene fluoride)/ZnO