Frequency controlled agglomeration of pt-nanoparticles in sonochemical synthesis

Optimizing the surface area of nanoparticles is key to achieving high catalytic activities for electrochemical energy conversion devices. In this work, the frequency range (200 kHz-500 kHz) for maximum sonochemical radical formation was investigated for the sonochemical synthesis of Pt-nanoparticles to assess whether an optimum frequency exists or if the entire range provides reproducible particle properties. Through physical and electrochemical characterization, it was found that the frequency dependent mechanical effects of ultrasound resulted in smaller, more open agglomerates at lower frequencies with agglomerate sizes of (238 +/- 4) nm at 210 kHz compared to (274 +/- 2) nm at 326 kHz, and electrochemical surface areas of (12.4 +/- 0.9) m(2)g(-1) at 210 kHz compared to (3.4 +/- 0.5) m(2)g(-1) at 326 kHz. However, the primary particle size (2.1 nm) and the catalytic activity towards hydrogen evolution, (19 +/- 2) mV at 10mA cm(2),remained unchanged over the entire frequency range. Highly reproducible Pt-nanoparticles are therefore easily attainable within a broad range of ultrasonic frequencies for the sonochemical synthesis route.

Automated summary

Optimizing the surface area of nanoparticles is crucial for the catalytic performance of electrochemical energy conversion devices. This study investigated the effect of different frequencies on the sonochemical synthesis of Pt nanoparticles and found that lower frequencies resulted in smaller agglomerates and higher electrochemical surface areas, while the primary particle size and catalytic activity remained constant across the entire frequency range.