Hydrophobic and Superhydrophobic surfaces are promising technology for the surface finishing of metallic materials due to its water-repellency. Realization of highly water-repellent surface on aluminum and its alloys provides various functionalities for real application fields. In order to realize the hydrophobic/superhydrophobic surfaces on aluminum and its alloys, various technologies have been demonstrated. Especially, traditional anodic oxidation for aluminum has been widely employed for the morphological texturing of surfaces, which is essential to enhance the hydrophobic efficiency. De-wetting superhydrophobic surface on aluminum provides various exceptional properties, such as anti-corrosion, anti-/de-icing, anti-biofouling, drag reduction, self-cleaning and liquid separation. Nevertheless, the durability and stability of superhydrophobic surfaces still remain challenges for their actual applications in engineering systems and industry. In this review, the theoretical/ experimental studies and current technical limitations on the hydrophobic and superhydrophobic surface using anodic oxidation of aluminum have been summarized.

• Abstract
• 1. 서론
• 2. 초발수 및 발수성
• 3. 양극산화를 이용한 알루미늄의 초발수 및 발수성 표면처리
• 4. 결론
• References

1 L. J. Chen, 255 : 3459-3462, 2008

2 X. Feng, 18 : 3063-3078, 2006

3 L. Li, 4 : 4549-4556, 2012

4 Y. Wang, 256 : 3837-3840, 2010

5 Y. C. Sheen, 46 : 1984-1990, 2008

6 A. Steele, 9 : 501-505, 2008

7 B. P. Singh, 232 : 475-481, 2013

8 D. Prasai, 6 : 1102-1108, 2012

9 K.-C. Chang, 66 : 144-153, 2014

10 J. O. Iroh, 46 : 15-24, 2000

11 E. Hermelin, 20 : 4447-4456, 2008

12 T. Song, 355 : 495-501, 2015

13 Y. Yin, 255 : 2978-2984, 2008

14 T. He, 51 : 1757-1761, 2009

15 A. V. Rao, 257 : 5772-5776, 2011

16 S. Zheng, 54 : 174-187, 2010

17 R. T. Foley, 42 : 277-288, 1986

18 Y. Liu, 49 : 1624-1629, 2014

19 L. B. Boinovich, 7 : 19500-19508, 2015

20 B. Zhang, 5 : 100000-100010, 2015

21 Y. Liu, 466 : 125-131, 2015

22 A. M. Md Jani, 58 : 636-704, 2013

23 W. Lee, 3 : 234-239, 2008

24 W. Lee, 5 : 741-747, 2006

25 C. Jeong, 4 : 842-848, 2012

26 J. Lee, 27 : 1606040-, 2017

27 J. Lee, 243 : 34-38, 2014

28 J. Lee, 283 : 941-946, 2013

29 F. Mansfeld, 135 : 828-833, 1988

30 Y. Zuo, 166 : 237-242, 2003

31 H. Zhang, 141 : 238-242, 2015

32 Z. Lu, 91 : 287-296, 2015

33 J. Ou, 5 : 3101-3107, 2013

34 D. Quere, 2 : 457-460, 2003

35 P. Wang, 8 : 1120-1127, 2016

36 P. Vengatesh, 7 : 1516-1526, 2015

37 Y. C. Jung, 229 : 127-140, 2008

38 M. Cao, 8 : 3615-3623, 2015

39 W. Barthlott, 202 : 1-8, 1997

40 S. Farhadi, 257 : 6264-6269, 2011

41 M. A. Sarshar, 291 : 427-435, 2013

42 O. Parent, 65 : 88-96, 2011

43 L. Feng, 43 : 2012-2014, 2004

44 W. Zhang, 25 : 2071-2076, 2013

45 N. Desbiens, 44 : 5310-5313, 2005

46 R. Narhe, 75 : 98-, 2006

47 N. Adam, 180 : 809-810, 1957

48 R. N. Wenzel, 28 : 988-994, 1936

49 A. B. D. Cassie, 40 : 546-551, 1944

50 W. Xu, 109 : 024504-, 2012

51 A. T. Paxson, 4 : 1492-, 2013

52 R. Raj, 28 : 15777-15788, 2012

53 L. Cao, 24 : 1640-1643, 2008

54 C. Zhilei, 17 : 2661-2669, 2013

55 G. Thompson, 55 : 1052-1061, 1999

56 B. Yin, 44 : 439-444, 2012

57 W. Lee, 26 : 1412-1415, 2009

58 D. Zang, 83 : 86-93, 2014

59 Y. Huang, 356 : 1012-1024, 2015

60 P. Roach, 4 : 224-240, 2008

61 A. Tuteja, 105 : 18200-18205, 2008

62 R. Hensel, 26 : 2029-2033, 2014

63 T. Liu, 346 : 2014

64 J. Ou, 16 : 4635-4643, 2004

65 C.-H. Choi, 18 : 087105-, 2006

66 C.-H. Choi, 96 : 066001-, 2006

67 F. Hizal, 9 : 12118-12129, 2017

68 G. Bruinsma, 22 : 3217-3224, 2001

69 C. Jeong, 31 : 11040-11050, 2015

70 L. Boinovich, 55 : 238-245, 2012

71 A. Carre, "Superhydrophobic Surfaces" CRC Press 2009

72 G. Wang, "Scientific Reports, 6" 20933-, 2016