20 Functional Organic Material

10-CDPA

10-CDPA

Self Assembled Monolayer Reagent

  • Product code
    C490  10-CDPA
  • CAS No.
    4494-24-0
  • Chemical name
    10-Carboxydecylphosphonic acid
  • MW
    C11H23O5P=266.27
Unit size --
10 mg Please inquire distributors about price.
100 mg Please inquire distributors about price.

Structural Formula

Product Description

Phosphonic acid derivatives are used for surface modification on oxidized metals such as Al2O31), TiO22), ZrO23), SiO24), Mica5), stainless(SS316L) 6), nitinol7), hydroxyapatite8), AgO9), ZnO10), ITO11,12).
For a long time, organosilanes have been used to form self assembled monolayer (SAM) on the metal oxide. However, it is not always adaptable in the applications due to the poor stability and polymerization of the reagent with each other. On the other hand, phosphonic acid derivatives equally form a SAM on the metal oxide despite being very stable compounds. Also, phosphonic acid derivatives have been reported to use formation of more stable and dense SAM than organosilanes. Klauk et. al. and Sekitani et. al. show alkyl phosphonate SAM on Al2O3 is more useful than the trichlorosilane derivatives SAM as an conductor film of an organic transistor13).
10-CDPA is an alkyl phosphonic acid derivative containing carboxylic acid termination. Zhang et al. have utilized a SAM of 10-CDPA on ZnO surface as a biosensor.

References

Open References

1) T. Hauffman, O. Blajiev, J. Snauwaert, C. van Haesendonck, A. Hubin, H. Terryn, "Study of the self-assembling of n-octylphosphonic acid layers on aluminum oxide", Langmuir, 2008, 24 (23), 13450.
2) P. Thissen, M. Valtiner, G. Grundmeier, "Stability of Phosphonic Acid Self-Assembled Monolayers on Amorphous and Single-Crystalline Aluminum Oxide Surfaces in Aqueous Solution", Langmuir, 2010, 26 (1), 156.
3) W. Gao, L. Reven, "Solid-state NMR-studies of self-assembled monolayers", Langmuir, 1995, 11 (6), 1860.
4) S. Marcinko, A. Y. Fadeev, "Hydrolytic Stability of Organic Monolayers Supported on TiO2 and ZrO2", Langmuir, 2004, 20 (6), 2270.
5) J. Schwartz, M. J. Avaltroni, M. P. Danahy, B. M. Silverman, E. L. Hanson, J. E. Schwarzbauer, K. S. Midwood, E. S. Gawalt, " Cell attachment and spreading on metal implant materials", J. Mat. Sci. Eng. C, 2003, 23, 395.
6) B. M. Silverman, K. A. Wieghaus, J. Schwartz, "Comparative properties of siloxane vs phosphonate monolayers on a key titanium alloy", Langmuir, 2005, 21 (1), 225. 
7) N. Adden, L. J. Gamble, D. G. Castner, A. Hoffmann, G. Gross, H. Menzel, "Phosphonic Acid Monolayers for Binding of Bioactive Molecules to Titanium Surfaces", Langmuir, 2006, 22, 8197.
8) E. L. Hanson, J. Schwartz, B. Nickel, N. Koch, M. F. Danisman, "Bonding self-assembled, compact organophosphonate monolayers to the native oxide surface of silicon", J. Am. Chem. Soc., 2003, 125 (51), 16074. 
9) M. Dubey, T. Weidner, L. J. Gamble, D. G. Castner, "Structure and Order of Phosphonic Acid-Based Self-Assembled Monolayers on Si(100)", Langmuir, 2010, 26 (18), 14747.
10) A. Vega, P. Thissen, Y. J. Chabal, "Environment-Controlled Tethering by Aggregation and Growth of Phosphonic Acid Monolayers on Silicon Oxide", Langmuir, 2012, 28, 8046.
11) P. Thissen, A. Vega, T. Peixoto, Y. J. Chabal, "Controlled, Low-Coverage Metal Oxide Activation of Silicon for Organic Functionalization: Unraveling the Phosphonate Bond", Langmuir, 2012, 28 (50), 17494.
12) J. T. Woodward, A. Ulman, D. K. Schwartz, "Self-assembled monolayer growth of octadecylphosphonic acid on mica", Langmuir, 1996, 12 (15), 3626.
13) A. Raman, M. Dubey, I. Gouzman and E. S. Gawalt, "Formation of self-assembled monolayers of alkylphosphonic acid on the netive oxide surface of SS316L", Langmuir, 2006, 22, 6469.
14) G. Zorn, R. Adadi, R. Brener, V. A. Yakovlev,| I. Gotman, E. Y. Gutmanas, C. N. Sukenik, "Tailoring the Surface of NiTi Alloy Using PIRAC Nitriding Followed by Anodization and Phosphonate Monolayer Deposition", Chem. Mater.2008, 20, 5368.
15) R. Quinones and E. S. Gawalt, "Polystyrene formation on monolayer-modified nitinol effectively controls corrosion", Langmuir, 2008, 24, 10858.
16) S. C. D’Andrea and Al. Y. Fadeev, "Covalent surface modification of calcium hydroxyapatite using n-alkyl- and n-fluoroalkylphosphonic acids", Langmuir, 2003, 19, 7904.
17) B. Zhang, T. Kong, W. Xu, R. Su, Y. Gao and G. Cheng, "Surface functionalization of zinc oxide by carboxyalkylphosphonic acid self-assembled monolayers", Langmuir, 2010, 26(6), 4514.
18) A. Sharma, B. Kippelen, P. J. Hotchkiss and S. R. Marder, "Stabilization of the work function of indium tin oxide using organic surface modifiers in organic light-emitting diodes", Appl. Phys. Lett., 2008, 93, 163308.

Handling and storage condition

Specification
Appearance: White to slightly yellow powder or crystalline powder
Solubility in Methyl alcohol: To pass test (clear, colorless)
NMR spectrum: Authentic
Handling and storage condition
Ambient temperature
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Product Classification

Product Classification

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