图 1  (a) 基于三量子点耦合的四端制冷机的示意图; (b) (a)中装置的等效电路图

Fig. 1.  (a) Schematic diagram of a four terminal refrigerator based on three coupled quantum dots, and (b) is the equivalent circuit diagram of the device in (a).

图 2  图1描述的八种量子态的跃迁过程

Fig. 2.  The transition processes of eight quantum states described in Fig. 1.

图 3  当耗散系数为$ \lambda = 0 $时,　(a) 输入功率$ P $以及(b)—(d)各量子点与对应库之间的热流J_H, J_C, J_LR随温差$ \Delta T $和偏置电压$ e\Delta V $变化的三维投影图

Fig. 3.  The three-dimensional projection graphs for (a) input power $ P $ and (b)–(d) the heat flow J_H, J_C, J_LR varying with the temperature difference $ \Delta T $ and the bias voltage $ e\Delta V $ under the dissipation factor $ \lambda = 0 $.

图 4  当耗散系数为$ \lambda = 0 $和$ \lambda = 0.26 $时, 装置A和装置B各自对应的工作区域

Fig. 4.  The corresponding working areas of device A and device B when the dissipation factor is (a) $ \lambda = 0 $ and (b) $ \lambda = 0.26 $, respectively.

图 5  在不同耗散系数下, 装置作为混合驱动制冷机时的总熵产率随温差$ \Delta T $和偏置电压$ e\Delta V $变化的三维曲线

Fig. 5.  The three-dimensional curves of total entropy production rate varying with temperature difference $ \Delta T $ and bias voltage $ e\Delta V $ when the device is used as a hybrid-driven refrigerator under different dissipation factor.

图 6  在不同耗散系数下, 制冷率和制冷系数随充电能$ {U_{{\text{MH}}}} $和$ {U_{{\text{MC}}}} $变化的三维图

Fig. 6.  The three-dimensional diagrams of the cooling rate and the COP varying with charging energy $ {U_{{\text{MH}}}} $ and $ {U_{{\text{MC}}}} $ under different dissipation factor.

图 7  在不同的耗散系数下, 制冷率和制冷系数随充电能$ {U_{{\text{MH}}}} $和偏置电压$ eV $变化的三维图

Fig. 7.  The three-dimensional diagrams of the cooling rate and the COP varying with charging energy $ {U_{{\text{MH}}}} $ and bias voltage $ e\Delta V $ under different dissipation factor.

图 8  在给定条件$ \Delta T = 2\gamma /{k_{\text{B}}} $下,　(a) 优化的制冷率$ {J_{{\text{Copt}}}} $和(b)优化制冷率对应的制冷系数以及(c)对应的充电能$ {U_{{\text{MC}}}} $随耗散系数$ \lambda $的变化曲线

Fig. 8.  The curves of (a) the optimized cooling rate $ {J_{{\text{Copt}}}} $ and (b) the COP corresponding to optimized cooling rate and (c) the corresponding charging energy $ {U_{{\text{MC}}}} $ as a function of dissipation factor $ \lambda $ under the given condition $ \Delta T = 2\gamma /{k_{\text{B}}} $.

图 9  (a) 最大制冷率$ {J_{{\text{C}}\max }} $和最大制冷率对应的COP$ {\eta _{\text{J}}} $; (b) 最佳充电能量$ {U_{{\text{MC}}}} $随温差$ \Delta T $的变化曲线

Fig. 9.  The curves of (a) the maximum cooling rate $ {J_{{\text{C}}\max }} $ and the COP corresponding to maximum cooling rate $ {\eta _{\text{J}}} $ and (b) the optimal charging energy $ {U_{{\text{MC}}}} $ as a function of temperature difference $ \Delta T $.

图 10  在强耦合$ {U_{{\text{HC}}}} $的情况下, 当$ \lambda = 0 $时,　(a) 制冷率$ {J_{\text{C}}} $和(b)制冷系数$ {\eta _{{\text{COP}}}} $随着$ {U_{{\text{MH}}}} $和$ {U_{{\text{MC}}}} $变化的三维图

Fig. 10.  In the case of strong coupling $ {U_{{\text{HC}}}} $, when $ \lambda = 0 $, the three-dimensional diagrams for (a) cooling rate $ {J_{\text{C}}} $ and (b) the COP varying with $ {U_{{\text{MH}}}} $ and $ {U_{{\text{MC}}}} $.