Superhydrophobic Aluminum Surfaces by Deposition of Micelles of Fluorinated Block Copolymers

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Overview

Reference:

  • [1] Superhydrophobic Aluminum Surfaces by Deposition of Micelles of Fluorinated Block Copolymers Desbief, S., Grignard, B., Detrembleur, C., Rioboo, R., Vaillant, A., Seveno, D., Voue, M., De Coninck, J., Jonas, A.M., Jerome, C., Damman, P., and Lazzaroni, R. Langmuir (2009). doi: 10.1021/la902565y.

Keywords: Hydrophobic, Block Copolymer, Micelle, Fluorination, Wenzel Roughness

Summary

UNDER CONSTRUCTION

The authors' goal in this study was to develop a technique for making large hydrophobic surfaces. While many methods of making hydrophobic surfaces existed previously, the authors saw a need for a method which could be used at large scales. The solution presented in this paper involves changing the surface roughness and surface free energy of aluminum. Developing such a technique required two steps: first, the development of a sythesis routine for making a polymer and attaching it to a surface, and second, testing the hydrophobicity of the surface.

Figure 1 from [1].

To make an aluminum surface superhydrophobic, the researchers decided to change both the surface roughness and the surface free energy. The scientists synthesized a block copolymer and deposited micelles of it onto the aluminum. The block co-polymer has a polyacrylonitrile (PAN) block and a fluorinated block. The researchers used H NMR to characterize the polymers they synthesized. The four polymers described in this paper vary by the molecular weights of the two polymers making up the block copolymer, as seen in figure 1 (PAN is the N block, the flourinated block is F).

DMF (dimethylformamide), TFT (trifluorotoluene) Because the PAN block is (...) phobic, while the fluorinated block is (...._ philic), the polymer forms micelles with a core of PAN and an outer layer (corona) of fluorinated blocks. Depositing these micelles onto the aluminum surface gives the surface a bumpy surface on the scale of the size of the micelles (bump diameters= 17nm to 32nm depending on the molecular wight of the polymer). The surface was imaged using AFM as a verification that the process carried out as expected.

Figure 3 from [1].

Having modified the surface, the next step in the experiment was to test its hydrophobicity to see if the surface treatment was a success. They used two methods of testing hydrophobicity: the sliding test and the drop test.

Soft Matter Details

  • Experimental Methods:

This experiment makes use of many techniques which I imagine are widely used in soft matter:

-Atomic Force Microscopy (AFM) was used to analyze the roughness of the surface. Figure 3 shows the AFM images which the authors used in their calculation of the Wenzel roughness. The authors also used AFM to verify that micelles attached to the surface as anticipated.

-Proton Nuclear Magnetic Resonance (<math>^1</math>H NMR) was used to determine the molecular weights of the two components of the diblock copolymer. Desbief et. al. created four different diblock copolymers simply by varying the lengths of the the PAN block and the fluorinated block. Using <math>^1</math>H NMR) allowed the scientists to determine the structure of the polymers they created.

-Drop Impact Analysis is one way to test a surface's hydrophobicity. The test requires dropping different sized drops of water onto the surface at different speeds and recording the event with a high-speed camera. Figure 7 shows the fascinating shapes one water drop takes on as it bounces off the hydrophobic aluminum.

Figure 7 from [1].

-The Sliding Method is an alternate way to test hydrophobicity.

The polymer synthesis described in the article is also an important and complex method from polymer chemistry.

  • Scalable solutions:

The inspiration for this research was finding a hydrophobic treatment that could be scaled up for larger projects. I find this interesting because soft-matter research is often stuck at small scales where energies (energy on the scale of kT, lengths on the scale of capillary lengths for example). Creating micelles of polymers is certainly a soft-matter topic, but worrying about the application on a much larger scale is seeing the broader picture. It seems difficult to both control the surface roughness on a small scale while working on a very large surface. Self-assembling micelles of uniform size is a great solution.

  • Difficult synthesis, really easier than other methods?

The polymer chemistry described in the paper seems very complex. Would this be a stumbling block in scaling up this method and making it commericially viable?