JCDSA  Vol.4 No.3 , June 2014
Nano-Patterning of Diffraction Gratings on Human Hair for Cosmetic Purposes
Abstract: A method is presented for nano-patterning a diffraction grating on human hair with a focused ion beam. Strands of brown hair are patterned with hyperbolas and Archimedean spirals whose pitches range from 540 nm to 1040 nm. Exposure of the hair strands to white light at various incident angles demonstrates that light of varying wavelengths is diffracted by the diffraction gratings. The diffraction causes the brown strands of hair to reflect light from the entire range of visible light.
Cite this paper: Abbas, K. , Goettler, D. , Lamartine, B. and Leseman, Z. (2014) Nano-Patterning of Diffraction Gratings on Human Hair for Cosmetic Purposes. Journal of Cosmetics, Dermatological Sciences and Applications, 4, 173-178. doi: 10.4236/jcdsa.2014.43024.

[1]   Walter, P., Welcomme, E., Hallegot, P., Zaluzec, N.J., Deeb, C., Castaing, J., Veyssiere, P., Breniaux, R., Leveque, J.-L. and Tsoucaris, G. (2006) Early Use of Pbs Nanotechnology for an Ancient Hair Dyeing Formula. Nano Letters, 6, 2215-2219.

[2]   Swift, J.A. and Brown, A.C. (1972) The Critical Determination of Fine Changes in the Surface Architecture of Human Hair Due to Cosmetic Treatment. Journal of the Society of Cosmetic Chemists, 23, 695-670.

[3]   Nohyneka, G.J., Fautzb, R., Benech-Kiefferc, F. and Toutaina, H. (2004) Review: Toxicity and Human Health Risk of Hair Dyes. Food and Chemical Toxicology, 42, 517-543.

[4]   Thun, M.J., Altekruse, S.F., Namboodiri, M.M., Calle, E.E., Myers, D.G. and Heath, C.W. (1994) Hair Dye Use and Risk of Fatal Cancers in U.S. Women. Journal of the National Cancer Institute, 86, 164-165.

[5]   Sun, C.-H., Jiang, P. and Jiang, B. (2008) Broadband Moth-Eye Antireflection Coatings on Silicon. Applied Physics Letters, 92, Article ID: 061112.

[6]   Wilson, S.J. and Hutley, M.C. (1982) The Optical Properties of “Moth Eye” Antireflection Surfaces. Journal of Modern Optics, 29, 993-1009.

[7]   Lamartine, B.C. and Orler, E.B. (2011) Hair Treatment Process Providing Dispersed Colors by Light Diffraction. Los Alamos National Laboratory Patent.

[8]   Hecht, E. (2002) Optics. 4th Edition.

[9]   Goettler, D.F., Su, M.F., Reinke, C.M., Alaie, S., Hopkins, P.E., Olsson, R.H.I., El-Kady, I. and Leseman, Z.C. (2011) Realization of a 33 GHz Phononic Crystal Fabricated in a Freestanding Membrane. AIP Advances, 1, Article ID: 042001.

[10]   Edinger, K. and Kraus, T. (2001) Modeling of Focused Ion Beam Induced Chemistry and Comparison with Experimental Data. Microelectronic Engineering, 57-58, 263-268.

[11]   Nassar, R., Vasile, M. and Zhang, W. (1998) Mathematical Modeling of Focused Ion Beam Microfabrication. Journal of Vacuum Science & Technology B, 16, 109-115.

[12]   (2007) Quanta 3D FEG Datasheet. FEI Company.

[13]   Giannuzzi, L.A. and Stevie, F.A. (1999) A Review of Focused Ion Beam Milling Techniques for Tem Specimen Preparation. Micron, 30, 197-204.

[14]   Lamartine, B.C. (2003) Reflective Diffraction Grating. US 6583933.

[15]   Lamartine, B.C. and Stutz, R.A. (1995) Ultrahigh Vacuum Focused Ion Beam Micromill and Articles Therefrom. US 5721687.

[16]   Lamartine, B.C. and Stutz, R.A. (1998) Focused Ion Beam Milling and Article Therefrom. US 5773116.

[17]   Lamartine, B.C. Direction Aggregate Element Diffraction Patent (daedp). Pending.

[18]   Lamartine, B.C. (2010) Angarclen1.Xmcd, an Unpublished MathCAD Program.