Substitutional-interstitial structural transition in Cu-Pt nano-alloys

Luke D Geoffrion; Miguel José-Yacaman; Alexander Lehr; Shi-Ze Yang; John Sanchez; J Jesus Velazquez-Salazar; Grégory Guisbiers

doi:10.1039/d1na00204j

Substitutional-interstitial structural transition in Cu-Pt nano-alloys

Nanoscale Adv. 2021 May 27;3(13):3746-3751. doi: 10.1039/d1na00204j. eCollection 2021 Jun 30.

Authors

Luke D Geoffrion¹, Miguel José-Yacaman², Alexander Lehr², Shi-Ze Yang³, John Sanchez², J Jesus Velazquez-Salazar², Grégory Guisbiers¹

Affiliations

¹ Department of Physics & Astronomy, University of Arkansas at Little Rock 2801 South University Avenue Little Rock AR 72204 USA gxguisbiers@ualr.edu.
² Department of Applied Physics & Materials Science, Northern Arizona University 624 S. Knowles Drive Flagstaff AZ 86011 USA.
³ Eyring Materials Center, Arizona State University 300 E University Drive Tempe AZ 85287 USA.

Abstract

Copper-platinum alloys are important binary alloys in catalysis. In this communication, we demonstrate that it is possible to preserve the thermal properties of platinum with a copper-platinum alloy by converting the substitutional alloy into an interstitial one. This conversion occurs when the size of the copper-platinum system is reduced down to the nanoscale. The size-dependent phase diagram of Cu-Pt for a spherical nanoparticle is calculated at various sizes (50, 10 and 5 nm) demonstrating that Cu-Pt alloyed nanoparticles can be formed all over the composition range. Experimentally, the electron microscopy characterization of copper-platinum alloyed nanoparticles synthesized by wet chemistry supports the predicted structural transition.