ライフサイエンスコーパス: electrowetting

1 ulated upon an electrode array by the use of electrowetting.

2 ores and limiting solvent penetration during electrowetting.

3 lament, as is demonstrated in the context of electrowetting.

4 luids throughout the drying process using AC-electrowetting.

5 used as references to engineer task-specific electrowetting agents (ILs) for future electrowetting-ba

6 he alternative use of ionic liquids (ILs) as electrowetting agents in EWOD-based applications or devi

7 ray ionization for use in mass spectrometry, electrowetting and lab-on-a-chip manipulations.

8 Here, we demonstrate that electrowetting-assisted drying of solutions of common MA

9 cific electrowetting agents (ILs) for future electrowetting-based applications.

10 ere we show that liquid dielectrophoresis or electrowetting can produce wetting on normally non-wetti

11 with exceptionally low power consumption by electrowetting/deelectrowetting at the metal surface.

12 and more homogeneous sample spots on special electrowetting-functionalized e-MALDI target plates.

13 ric field experienced by the lipid membrane, electrowetting has been used to determine the point of z

14 bination of nanofilament silicon and dynamic electrowetting is shown to provide routine detection lim

15 The use of electrowetting is shown to result in enhanced interactio

16 An electrowetting model describing the measured relationshi

17 We have developed an integrated electrowetting nanoinjector (INENI) to transfect single

18 Here, we report the electrowetting of graphene-coated metal meshes for use a

19 ndence; and (iii) a systematic comparison of electrowetting of ILs using AC vs DC voltage fields.

20 estigation of AC frequency dependence on the electrowetting of ILs; (ii) obtaining theoretical relati

21 This paper presents a study of electrowetting of ionic liquids (ILs) under AC voltages,

22 All tested ILs showed electrowetting of various magnitudes on an amorphous flo

23 s are performed in 64 nL droplets handled by electrowetting on dielectric (EWOD) actuation.

24 electrolytes are the dominant components in electrowetting on dielectric (EWOD)-based microfluidic d

25 hod combines previously demonstrated reverse electrowetting on dielectric (REWOD) phenomenon with the

26 The enhanced stability of ILs in electrowetting on dielectric at higher voltages was stud

27 Dynamic electrowetting on nanostructured silicon surfaces is dem

28 Localized heating of droplets on an electrowetting-on-dielectric (EWOD) chip has been implem

29 othymidine ((18)F-FLT) with high yield on an electrowetting-on-dielectric (EWOD) microfluidic radiosy

30 The technique relies on electrowetting-on-dielectric (EWOD) to move droplets con

31 ion method for MALDI-MS, which relies on the electrowetting-on-dielectric (EWOD)-based technique for

32 l synthesis in organic solvents, operated by electrowetting-on-dielectric (EWOD).

33 ng example is the tunable liquid lens, where electrowetting or external pressure manipulates the shap

34 nergy conversion method based on the reverse electrowetting phenomenon.

35 Therefore electrowetting properties of 19 different ionic liquids,

36 In this regard, a fundamental study on the electrowetting properties of ILs is essential.

37 The electrowetting properties of ILs under AC voltages were

38 Finally, the physical properties and AC electrowetting properties of ILs were measured and tabul

39 re, functionality, and charge density on the electrowetting properties were studied.

40 The physical properties of ILs and their electrowetting properties were tabulated.

41 Electrowetting reversibility under AC voltage conditions

42 boelectric nanogeneration (TENG) and reverse electrowetting (REWOD), are reported in more detail.

43 Without electrowetting, silicon surfaces comprising dense fields

44 rophobic surfaces, 'fakir' droplets, tunable electrowetting, slip in the presence of surface heteroge

45 w approach is also the first of its kind for electrowetting-style displays by allowing non-aligned la

46 tal role in electron transport energetics by electrowetting the cofactors in the chain upon arrival o

47 Deviations from classical electrowetting theory were confirmed.

48 nofilaments can be dynamically controlled by electrowetting, thereby allowing aqueous buffer to penet

49 tivated fluidic valves that operate based on electrowetting through textiles.