Publications Details

In-plane thermal conductivity and the applicability of the Wiedemann-Franz law in dilute AlCu thin films

Makarem, Sara; Gowda, Shivashree; Mohan, Ramya; Zare, Saman; Sadat, Nazmun S.; Brummel, Ian A.; Ma, Chung T.; Bin Hoque, Md S.; Hirt, Daniel; Islam, Md R.; Poon, Joseph; Ihlefeld, Jon F.; Esteves, Giovanni; Scott, Ethan A.; Hopkins, Patrick E.

The Wiedemann-Franz (WF) law correlates heat and charge transport in metals. However, the validity of this correlation remains an open-ended question, especially in the context of inelastic scattering at room temperature. To address this gap in knowledge, we perform independent measurements of the in-plane thermal and electrical conductivities across four AlCu (0.5% Cu) films [thickness ( h ) ≈ 174, 98, 53, and 24 nm] using optical pump-probe metrologies and four-point probe techniques, respectively. For in-plane thermal conductivity measurements, we utilize time-domain thermoreflectance, in both concentric and beam-offset configurations, and the time-resolved magneto-optic Kerr effect. Our results show that the WF law overpredicts the thermal conductivity by at least ∼10% in all films, thus demonstrating modest deviations in predicted thermal conductivity when applying the WF law to dilute AlCu films. Using infrared variable angle spectroscopic ellipsometry, we demonstrate increased electron scattering rates in the thinnest film ( h ≈ 24 nm), indicating electron-boundary scattering drives the reduction in in-plane thermal conductivity. This is generally an elastic scattering process, which is supported by our thermal conductivity measurements and analysis.