Molecular Electronic Junctions Achieved High Thermal Switch Ratios in Atomistic Simulations.

The development of devices that improve thermal energy management requires thermal regulation with efficiency comparable to the ratios R ∼ 10 5 in electric regulation. Unfortunately, current materials and devices in thermal regulators have only been reported to achieve R ∼ 10. We use atomistic simulations to demonstrate that Ferrocenyl (Fc) molecules under applied external electric fields can alter charge states and achieve high thermal switch ratios R = G q / G 0 , where G q and G 0 are the high and low limiting conductances. When an electric field is applied, Fc molecules are positively charged, and the SAM-Au interfacial interaction is strong, leading to high heat conductance G q . On the other hand, with no electric field, the Fc molecules are charge neutral and the SAM-Au interfacial interaction is weak, leading to low heat conductance G 0 . We optimized various design parameters for the device performance, including the Au-to-Au gap distance L , the system operation temperature T , the net charge on Fc molecules q , the Au surface charge number Z , and the SAM number N . We find that G q can be very large and increases with increasing q , Z , or N , while G 0 is near 0 at L > 3.0 nm. As a result, R > 100 was achieved for selected parameter ranges reported here.