ライフサイエンスコーパス: active electrode

1 een the Riboflavin (vitamin B2) and the SERS active electrode.

2 e):poly(styrenesulfonate) (PEDOT:PSS) as the active electrode.

3 morphous SiC/Si as device layer and Cu as an active electrode.

4 and the standard electrode potentials of the active electrodes.

5 trode or via a bipolar mode that employs two active electrodes.

6 ) that causes the fluid to rotate around the active electrodes.

7 g of the metrics identified distinct sets of active electrodes across different subjects.

8 ioned over both the embedded tubing and SERS active electrode (aligned approximately 200 mum from eac

9 ively, via a monopolar mode that utilizes an active electrode and a grounded electrode or via a bipol

10 electrocatalysis approach that integrates an active electrode and aminoxyl radical to enhance the per

11 The active electrode and its cord emit radiofrequency energy

12 few nanoseconds for devices consisting of Cu active electrodes and amorphous silica dielectrics and w

13 electrode-array balloon catheter that has 64 active electrodes and ring electrodes for emitting a loc

14 e transformed in a ring maintaining the same active electrode area than the summation of the closest

15 was fabricated with a lithographic process; active electrode area was defined by a photosensitive po

16 nt on a nanoelectrode by the increase in the active electrode area.

17 ut several sessions, comparing somatotopy of active electrodes, as well as neural signals both at the

18 e same session in 12 normal subjects with an active electrode at Oz referenced to the inion (Oz-In) o

19 cholecystectomy were randomized to separated active electrode/camera cords or parallel oriented activ

20 We hypothesized that separating the active electrode/camera cords would reduce thermal injur

21 incision in comparison to parallel oriented active electrode/camera cords.

22 electrode/camera cords or parallel oriented active electrode/camera cords.

23 We show that an active particle-active electrode can provide mechanistic insight into el

24 ion of the laparoscopic camera cord from the active electrode cord decreases thermal injury from ante

25 This phenomenon is increased when the active electrode cord is oriented parallel to another wi

26 ter angle and with greater separation to the active electrode cord, or lowering the generator power s

27 issue temperature when lying parallel to the active electrode cord: EKG pad 2.4 degrees C +/- 1.2 deg

28 The 64-channel EEG was recorded using active electrodes during a constant stimulation procedur

29 Antenna coupling occurs when the "bovie" active electrode (electrically active transmitting anten

30 that the basal plane of HOPG is a much more active electrode for many classes of electrode reactions

31 e development of fully compatible and highly active electrodes for solid oxide fuel cells.

32 electrocatalytically and photocatalytically active electrodes for water oxidation is described.

33 talyst adsorbs to the surface of a partially active electrode, further reduction of electrode-produce

34 tchability as both the current collector and active electrode, high-performance transparent and stret

35 y-stacked layers was grown and applied as an active electrode in rechargeable batteries.

36 ealing significantly greater distribution of active electrodes in brain regions that support verbal m

37 far prevented the use of these materials as active electrodes in EDLCs.

38 Ultrathin manganite films are widely used as active electrodes in organic spintronic devices.

39 Individual VTA models of the 42 active electrodes included in the study demonstrated a m

40 ional standards specify at a minimum that an active electrode is placed on the occiput at Oz, but we

41 ctive, transparent, and electrocatalytically active electrode material for studying nanobubbles gener

42 represented a linear combination of the two active electrode material systems.

43 g us to distinguish the contribution of each active electrode material.

44 rvice life have predominantly focused on the active electrode materials and electrolytes.

45 Subsequently, we select silicon and sulfur active electrode materials as examples to discuss the de

46 of a new generation of supercapacitors whose active electrode materials can be tuned rationally, at t

47 ons of nanostructured conductive polymers as active electrode materials for electrochemical capacitor

48 holey graphenes are used exclusively as the active electrode materials in EDLCs.

49 ns of different structures with vacancies as active electrode materials of lithium or sodium ion batt

50 First, seeding from active electrodes of 4 OCD patient cohorts (N = 50) rece

51 The active electrodes of the aptasensors were synthesized vi

52 In 1 M KOH and with the most active electrode, overpotentials as low as 240 and 270 m

53 rvised, fully automated approach to classify active electrodes showing event-related intracranial EEG

54 tributed to (i) substantial increases in the active electrode surface area, and (ii) improved electro

55 en limited by substrate accessibility to the active electrode surface.

56 Identification of active electrodes that record task-relevant neurophysiol

57 Instead, the "active" electrode that forms upon cycling is a nanocompo

58 ique transports charged biomolecules between active electrodes upon application of a small potential

59 colloidal nanoparticles are used as the SERS-active electrode, which exhibit long-term stability once