ライフサイエンスコーパス: solid oxide fuel cell

1 l-cell technology, a prime example being the solid-oxide fuel cell.

2 as ceria and zirconia, with application for solid oxide fuel cells.

3 catalysts, oxygen permeation membranes, and solid oxide fuel cells.

4 ications in catalysis, emissions control and solid-oxide fuel cells.

5 eeded to reduce the operating temperature of solid-oxide fuel cells.

6 temperature (400-700 ( composite function)C) solid-oxide fuel cells.

7 e able to operate at lower temperatures than solid oxide fuel cells (250 degrees to 550 degrees C ver

8 evices required a layered structure, such as solid oxide fuel cells and lithium ion battery.

9 nologies, ranging from ionic gating to micro-solid oxide fuel cells and neuromorphics.

10 s and are currently used as electrolytes for solid oxide fuel cells and solid oxide electrolyzer cell

11 d dynamics directly control the operation of solid-oxide fuel cells and are intrinsically coupled wit

12 c conductors, such as lithium-ion batteries, solid-oxide fuel cells and water-splitting membranes.

13 Doped ceria is an important electrolyte for solid oxide fuel cell applications.

14 In contrast, solid oxide fuel cells are capable of operating on conve

15 ane, 1-butene, n-butane and toluene) using a solid-oxide fuel cell at 973 and 1,073 K with a composit

16 The observation that a solid-oxide fuel cell can be operated on dry hydrocarbon

17 oherent interfaces of the composite produces solid oxide fuel cell cathode performance superior to th

18 as the properties necessary to function as a solid oxide fuel-cell cathode.

19 ogically important materials, used widely as solid oxide fuel cell cathodes; they have also been show

20 2Fe1.5Mo0.5O6 (SFMO) perovskite under anodic solid oxide fuel cell conditions.

21 mentally and theoretically the promising new solid oxide fuel cell electrode material Sr(2)Fe(1.5)Mo(

22 mplete three-dimensional reconstruction of a solid-oxide fuel-cell electrode.

23 nversion materials for metal-air battery and solid-oxide fuel-cell electrodes owing to their unique p

24 ovskite-type oxides are increasingly used in solid oxide fuel cells, electrolysis and catalysis, it i

25 Extensive efforts to develop a solid-oxide fuel cell for transportation, the bottoming

26 to lower their operating temperatures, in a solid oxide fuel cell, for example, from Top > 800 degre

27 xide fuel cells (O-SOFCs), proton conducting solid oxide fuel cells (H-SOFCs), batteries, solar cells

28 ation of fuel gas streams for the anode of a solid oxide fuel cell have been developed.

29 his property is of considerable relevance to solid oxide fuel cells in which fast O(2-) diffusion red

30 age and oxygen splitting such as fuel cells (solid-oxide fuel cells in particular) and for catalytic

31 Z may have on the chemistry occurring within solid oxide fuel cells is discussed briefly.

32 The main issue for solid oxide fuel cells is high operating temperature (ab

33 id electrolytes for intermediate-temperature solid oxide fuel cells (IT-SOFCs).

34 ic devices that include oxide ion conducting solid oxide fuel cells (O-SOFCs), proton conducting soli

35 te electrolytes for intermediate-temperature solid oxide fuel cells or for other applications of oxid

36 cular have exhibited excellent properties as solid oxide fuel cell oxygen electrodes.

37 es determine the temperature of operation of solid oxide fuel cells, oxygen separation membranes, and

38 Recent solid oxide fuel cells results have demonstrated extreme

39 ow-temperature (<500 degrees C) operation of solid oxide fuel cells, sensors and other ionotronic dev

40 demonstrate quantitative phase imaging of a solid oxide fuel cell (SOFC) anode by multilayer Laue le

41 Carbon formation or "coking" on solid oxide fuel cell (SOFC) anodes adversely affects pe

42 id-state NMR spectra of the mixed-conducting solid oxide fuel cell (SOFC) cathode material La2NiO4+de

43 e oxygen reduction activity and stability of solid oxide fuel cell (SOFC) cathodes.

44 ments of relevant chemical species formed on solid oxide fuel cell (SOFC) cermet anodes operating wit

45 ors, we demonstrated real-time monitoring of solid oxide fuel cell (SOFC) operations with 5-mm spatia

46 Zr0.84 O1.92 (YSZ) cathodes and exceptional solid oxide fuel cell (SOFC) performance of >2 W cm(-2)

47 ultaneously oxidized using a low-temperature solid oxide fuel cell (SOFC).

48 ures that show potential as electrolytes for solid oxide fuel cells (SOFC) due to their high ionic co

49 The solid-oxide fuel cell (SOFC) is one of the most exciting

50 rotonic-defect-conducting oxides find use in solid oxide fuel cells (SOFCs) and oxygen-deficient high

51 reducing atmospheres are in high demand for solid oxide fuel cells (SOFCs) and solid oxide electroly

52 Solid oxide fuel cells (SOFCs) are a rapidly emerging en

53 anode materials that have been developed for solid oxide fuel cells (SOFCs) are vulnerable to deactiv

54 nd implement via a case study of residential solid oxide fuel cells (SOFCs) for combined heating and

55 ctrodes development has been challenging for solid oxide fuel cells (SOFCs) owing to many reasons inc

56 ting Ni-yttria-stabilized zirconia anodes in solid oxide fuel cells (SOFCs) perform poorly in carbon-

57 with the most potential as an electrolyte in solid oxide fuel cells (SOFCs), owing to its stability a

58 terials is a key step for direct hydrocarbon solid oxide fuel cells (SOFCs).

59 Of the various fuel cell types, solid-oxide fuel cells (SOFCs) combine the benefits of e

60 Solid-oxide fuel cells (SOFCs) enable direct use of high

61 Solid-oxide fuel cells (SOFCs) promise high efficiencies

62 Fuel cells, and in particular solid-oxide fuel cells (SOFCs), enable high-efficiency c

63 lications in electrochemical devices such as solid-oxide fuel cells (SOFCs), oxygen separation membra

64 Here, we describe a solid oxide fuel cell that combines a catalyst layer wit

65 ured dense oxide cathode to make a thin-film solid-oxide fuel cell that can achieve a power density o

66 Thermal stability of composite cathodes for solid oxide fuel cells, the mixtures of (La0.8Sr0.2)0.95

67 es hold promise in applications ranging from solid oxide fuel cells to catalysts, their surface chemi