Chemical and Electrochemical Oxidation of Silicon Surfaces Functionalized with APTES: The Role of Surface Roughness in the AuNPs Anchoring Kinetics

JOAQUÍN KLUG; LUIS A. PÉREZ; EDUARDO A. CORONADO*; GABRIELA I. LACCONI*

JOURNAL OF PHYSICAL CHEMISTRY C

AMER CHEMICAL SOC

Lugar: Washington; Año: 2013 vol. 117 p. 11317 - 11327

1932-7447

Oxidation of Si(111) surfaces is a procedure widely used for their further functionalization with 3-aminopropyltriethoxysilane (APTES). In the present work, the formation of silicon oxide is carried out by chemical and electrochemical oxidation of the hydrogenated-silicon surfaces, giving rise to Si-OxChem and Si-OxEchem surfaces, respectively. Both surfaces are then functionalized with APTES solution to form an aminopropylsilane (APS) film, using two quite different concentrations of APTES (0.001 % v/v and 0.1 % v/v), in order to compare two limiting situations. At the lowest APTES concentration, the comparison of the kinetics of gold nanoparticles (AuNPs) anchoring process on both surfaces is found to be quite different, not only in the initial rate of NPs anchoring but also in the maximum percentage of coverage. In contrast, the kinetics behavior is almost the same when the surfaces are modified with the highest APTES concentration, reaching the same value of surface coverage. The different or similar behavior of both surfaces is analyzed by a careful characterization of Si-OxChem and Si-OxEchem surfaces using XP spectroscopy and AFM measurements, before and after APS functionalization. The significant differences in the surface roughness of the Si-Ox samples, together with the determination of the number of -NH3+ moieties after silanization at both APTES concentrations, leads to the conclusion that the availability of -NH3+ moieties is dependent on two factors: the roughness of the Si-OxChem and SiOxEchem surfaces as well as the concentration of the APTES solutions. When the APS layer is formed at the lowest APTES concentration, surface roughness controls the number of the different type of nitrogen functional groups. In contrast, at the highest APTES concentration, the surface roughness does not have any significant role in the number of -NH3+ moieties present on both surfaces. As the kinetics of AuNPs anchoring depends mainly on the probability to interact with the -NH3+ groups, the above characterization allow us to explain in a consistent way, the kinetics behavior observed for each particular condition of surface preparation.