ライフサイエンスコーパス: clean energy

1 efficiently utilize terrestrial emission for clean energy.

2 ly increasing due to the surging demands for clean energy.

3 as bioengineering, flexible electronics, and clean energy.

4 purred the search for alternative sources of clean energy.

5 layer) has been investigated as a source of clean energy.

6 overpotentials holds tremendous promise for clean energy.

7 -gases of high importance in the contexts of clean energy and climate alteration, respectively--in ex

8 itting is a promising avenue to sustainable, clean energy and fuel production.

9 The absence of reliable access to clean energy and the services it provides imposes a larg

10 sing water oxidation catalysts for practical clean energy application.

11 torage is in high demand for next-generation clean energy applications.

12 Adoption studies of ICSs or clean energy are scarce, scattered, and of differential

13 pulation, disadvantaged by lack of access to clean energy, are exposed to high levels of indoor air p

14 To make clean energy available to all people is the long-term go

15 ugh electrocatalysis holds great promise for clean energy, but its large-scale application relies on

16 onal design of new electrocatalysts for both clean energy conversion and green oxidizer production.

17 ign and synthesis of COF-based catalysts for clean energy conversion and storage are presented.

18 sis of noble-metal-free electrocatalysts for clean energy conversion applications; however, there are

19 rd a better understanding of a series of key clean energy conversion reactions including oxygen reduc

20 Electrocatalysis plays a central role in clean energy conversion, enabling a number of sustainabl

21 major applications to organic reactions and clean energy-conversion systems.

22 c viability of low temperature fuel cells as clean energy devices is enhanced by the development of i

23 regenerative fuel cells, and other important clean energy devices.

24 regenerative fuel cells, and other important clean energy devices.

25 Efficient and practical clean-energy devices for electrochemical or photoelectro

26 orld's all-purpose power from wind in a 2030 clean-energy economy.

27 reen technologies to provide clean water and clean energy from abundantly available renewable resourc

28 obes provide a platform for the synthesis of clean energy from renewable resources.

29 hemical performance, aiming at an affordable clean energy future.

30 In the transition to a clean-energy future, CO2 separations will play a critica

31 oaches in support of DOE missions related to clean energy generation and environmental characterizati

32 actively pursued owing to its importance in clean energy generation and storage.

33 A LIFE-based fleet of power plants promises clean energy generation with no greenhouse gas emissions

34 ogress towards a sustainable future based on clean energy generation, transmission and distribution,

35 lements (REEs) are critical to high-tech and clean-energy industries; however, their bioavailability

36 rodes are essential for many devices used in clean energy production and consumer electronics.

37 ations, as wastewater treatment coupled with clean energy production and power supply systems for iso

38 fossil-fuel technologies has revolutionized clean energy production using fuel cells.

39 lude by extending this framework to emerging clean energy reactions such as hydrogen peroxide product

40 arbon products is an important challenge for clean energy research.

41 A comprehensive programme for clean energy should optimise mitigation and, simultaneou

42 value added that is held by the co-produced clean energy source (syngas).

43 Harnessing solar power as a clean energy source requires the continuous development

44 change mitigation effects when combined with clean energy sources.

45 an urgent task to develop the renewable and clean energy sources.

46 Although they hold the promise of clean energy, state-of-the-art fuel cells based on polym

47 n electrochemistry, thus boosting the entire clean energy system.

48 to meet many analytical challenges in future clean energy systems and environmental management.

49 oxide materials, ranging from catalysts and clean energy systems to emerging multifunctional devices

50 Electrocatalysts are required for clean energy technologies (for example, water-splitting

51 ed that deployment of a diverse portfolio of clean energy technologies makes a transition to a low-ca

52 ic-electronic conducting (MIEC) membranes in clean energy technologies, i.e., oxyfuel combustion, cle

53 rare earth elements (REEs) in many emerging clean energy technologies, there is an urgent need for t

54 recious Pt catalysts holds great promise for clean energy technologies.

55 e to cope with the significant challenges of clean energy technologies.

56 tteries limit the commercialization of these clean-energy technologies.

57 These proposals include separately targeting clean energy uptake and demand-side efficiency in indivi

58 Rivers provide unrivaled opportunity for clean energy via hydropower, but little is known about t