ライフサイエンスコーパス: self-cleaning

1 in anti-fouling, anti-smudge, anti-fog, and self-cleaning.

2 drophobic surface for applications involving self-cleaning.

3 orientation dependence, wear resistance, and self-cleaning.

4 t imbue cuticle with antiwetting properties, self-cleaning abilities, antireflection, enhanced color,

5 marker when exposed to UV as a result of the self-cleaning ability of this schottky junction photocat

6 study, we demonstrate that gecko setae are a self-cleaning adhesive.

7 ld open the door to the development of novel self-cleaning adhesives, smart surfaces, microelectromec

8 portation, optical sensing, medicine, and as self-cleaning and anti-fouling materials operating in ex

9 Our substrates are also easy to fabricate, self-cleaning and reusable.

10 Because their self-cleaning and water resistant properties prohibit ba

11 iety of applications including anti-fouling, self-cleaning, anti-smudge, and low-drag.

12 for anti-fouling, anti-fogging, anti-icing, self-cleaning, anti-smudge, and oil-water separation app

13 c surfaces are of interest for anti-fouling, self-cleaning, anti-smudge, low-drag, anti-fog, and oil-

14 hes, paper, glass, and steel for a myriad of self-cleaning applications.

15 istry and roughness could be of interest for self-cleaning applications.

16 ces, lab-on-a-chip, sensor, microreactor and self-cleaning are presented.

17 Although self-cleaning by water droplets occurs in plant and anim

18 Along with their durability and self-cleaning capabilities, we have demonstrated drag re

19 design, we prepared a material surface with self-cleaning capability when subjected to standardized

20 -particle dynamic response leads to a robust self-cleaning capability, allowing geckos to efficiently

21 development of superhydrophobic surfaces for self-cleaning, condensation heat transfer enhancement an

22 ucturing strategy is presented that involves self-cleaning Cu catalyst electrodes with unprecedented

23 tals are further purified by exploiting the "self-cleaning" effect which results from the "colloidal

24 applications of this technology also include self-cleaning fabrics, water purification and protein fu

25 tric nanogenerator with superhydrophobic and self-cleaning features is invented to harvest water drop

26 The self-cleaning function of superhydrophobic surfaces is c

27 c ones do not, the former surfaces can yield self-cleaning garments and ice-repellent materials where

28 ocomposites with varying surface texture and self-cleaning hydrophobicity properties.

29 We propose that the property of self-cleaning is intrinsic to the setal nanostructure an

30 nderpins most current examples of commercial self-cleaning materials, such as: glass, tiles, concrete

31 ndings offer insights for the development of self-cleaning materials.

32 Here we report a unique self-cleaning mechanism possessed by the nano-pads of ge

33 Here, we demonstrate a unique self-cleaning mechanism whereby the contaminated superhy

34 s ion geometries and causes ion losses by a "self-cleaning" mechanism and thus should be suppressed a

35 Understanding gecko adhesion and self-cleaning mechanisms is essential for elucidating an

36 vent bio-fouling by developing a killing and self-cleaning membrane surface incorporating antibacteri

37 Self-cleaning occurred in arrays of setae isolated from

38 Contact mechanical models suggest that self-cleaning occurs by an energetic disequilibrium betw

39 Muscular motion and dynamic self-cleaning of gecko toe pads are mimicked via this me

40 d medical tools, textiles, water harvesting, self-cleaning, oil spill removal and microfluidic device

41 ological impact, from solar cell coatings to self-cleaning optical devices.

42 s, including energy storage, surface wetting/self-cleaning, photocatalysis and sensors.

43 l properties of thin-films, by analyzing the self-cleaning properties of tungsten doped anatase as an

44 e also known to exhibit some antifogging and self-cleaning properties.

45 Our approach shows a way to manufacture self-cleaning, re-attachable dry adhesives, although pro

46 o use superomniphobic surfaces, which can be self-cleaning, stain-proof, anti-bio-fouling, drag-reduc

47 nto both hard and soft materials to create a self-cleaning surface that functions even upon emersion

48 mportant in microfluidic liquid handling, on self-cleaning surfaces and in heat transfer.

49 Superhydrophobic self-cleaning surfaces are based on the surface micro/na

50 es based on superhydrophobicity, such as the self-cleaning surfaces on plant leaves and trapped air o

51 oactive films in light-driven locomotion and self-cleaning surfaces, and anticipate further applicati

52 tions ranging from photonic security tags to self-cleaning surfaces, gas separators, protective cloth

53 such as photonic inks, colorimetric sensors, self-cleaning surfaces, water purification systems, or b

54 Applications include the design of 'self-cleaning' surfaces and hydrophilic spots to automat

55 hydrophobic photocatalytic surfaces that are self-cleaning through light-induced photodegradation and

56 gy, where it finds applications ranging from self-cleaning to icephobicity and to condensation system

57 Synthesis of self-cleaning ultrafiltration membrane with long lasting

58 ons including microfluidics, drag reduction, self-cleaning, water harvesting, anti-corrosion, anti-fo