图 1  Maxwell黏弹模型示意图　(a) 弹簧单元; (b) 活塞单元; (c) 标准线性固体模型

Fig. 1.  A sketch of the Maxwell viscoelastic model: (a) Spring unit; (b) piston unit; (c) standard linear solid model.

图 2  狭缝中LJ流体的局域弛豫模量的分布. 图中实线为$ {K}_{2}\left(z\right) $的结果, 虚线为$ {K}_{\infty }^{{\mathrm{b}}}\left(\bar{\rho }\left(z\right)\right)-{K}_{0}^{{\mathrm{b}}}\left(\bar{\rho }\left(z\right)\right) $的结果. 计算中的参数取为$ {T}^{*}=1.5 $, $ {H}^{*}=6.0 $. 此外, 约化模量$ {K}_{2}^{*}={K}_{2}{\sigma }^{3}/\varepsilon $

Fig. 2.  Profiles of the local relaxation modulus of LJ fluid in slits. In the figure, the solid and dashed lines stand for the results of $ {K}_{2}\left(z\right) $ and $ {K}_{\infty }^{{\mathrm{b}}}\left(\bar{\rho }\left(z\right)\right)-{K}_{0}^{{\mathrm{b}}}\left(\bar{\rho }\left(z\right)\right) $, respectively. In the calculations, the parameters are set as $ {T}^{*}=1.5 $, $ {H}^{*}=6.0 $. In addition, the modulus is reduced as $ {K}_{2}^{*}={K}_{2}{\sigma }^{3}/\varepsilon $.

图 3  狭缝中LJ流体的剪切黏度分布. 计算中的流体参数取为$ {\rho }_{{\mathrm{b}}}^{*}=0.291 $, $ {T}^{*}=2.0 $

Fig. 3.  Profiles of shear viscosity of LJ fluid in slits. In the calculations, the fluid parameters are set as $ {\rho }_{{\mathrm{b}}}^{*}=0.291 $ and $ {T}^{*}=2.0 $.

图 4  狭缝中LJ流体的平均体积黏度随缝宽$ {H}^{*} $的变化. 其中, 实线、虚线和点分别为本文结果、LADM结果和基于GK的解析结果

Fig. 4.  Dependence of the averaged volume viscosity of LJ fluid on the pore width $ H $. In each figure, the solid lines, dashed lines and symbols stand for the results from this work, LADM and GK-based method, respectively.

图 5  在$ {H}^{*}=6.0 $情况下, 体积黏度$ {\eta }_{{\mathrm{v}}}^{*}\left({z}^{*}\right) $随体密度的变化　(a) $ {T}^{*}=2.0 $; (b) $ {T}^{*}=1.0 $

Fig. 5.  Influence of bulk density on the volume viscosity $ {\eta }_{{\mathrm{v}}}^{*}\left({z}^{*}\right) $ under the condition of $ {H}^{*}=6.0 $: (a) $ {T}^{*}=2.0; $ (b) $ {T}^{*}=1.0 $.

图 6  在$ {H}^{*}=6.0 $情况下, 受限流体中比值$ {R}_{\eta }^{{\mathrm{p}}{\mathrm{o}}{\mathrm{r}}{\mathrm{e}}} $随体密度的变化

Fig. 6.  Influence of bulk density on the ratio $ {R}_{\eta }^{{\mathrm{p}}{\mathrm{o}}{\mathrm{r}}{\mathrm{e}}} $ of the confined fluids, under the condition of $ {H}^{*}=6.0 $.

图 7  在$ {H}^{*}=6.0 $情况下, 体积黏度$ {\eta }_{{\mathrm{v}}}^{*}\left({z}^{*}\right) $随温度的变化　(a) $ {\rho }_{{\mathrm{b}}}^{*}=0.01; $ (b) $ {\rho }_{{\mathrm{b}}}^{*}=0.6 $.

Fig. 7.  Influence of temperature on the volume viscosity $ {\eta }_{{\mathrm{v}}}^{*}\left({z}^{*}\right) $ under the condition of $ {H}^{*}=6.0: $ (a) $ {\rho }_{{\mathrm{b}}}^{*}=0.01 $; (b) $ {\rho }_{{\mathrm{b}}}^{*}=0.6 $.

图 8  在$ {H}^{*}=6.0 $情况下, 受限流体中比值$ {R}_{\eta }^{{\mathrm{p}}{\mathrm{o}}{\mathrm{r}}{\mathrm{e}}} $随温度的变化

Fig. 8.  Influence of temperature on the ratio $ {R}_{\eta }^{{\mathrm{p}}{\mathrm{o}}{\mathrm{r}}{\mathrm{e}}} $ of the confined fluids, under the condition of $ {H}^{*}=6.0 $.

图 9  在$ {T}^{*}=1.5 $和$ {\rho }_{{\mathrm{b}}}^{*}=0.8 $条件下, (a) 体积黏度$ {\eta }_{{\mathrm{v}}}^{*}\left({z}^{*}\right) $随缝宽的变化; (b) 比值$ {R}_{\eta }^{{\mathrm{p}}{\mathrm{o}}{\mathrm{r}}{\mathrm{e}}} $随缝宽的变化. 图(b)中虚线为同一条件下体相液态的实验结果^[40]

Fig. 9.  Influence of pore width on (a) the volume viscosity $ {\eta }_{{\mathrm{v}}}^{*}\left({z}^{*}\right) $ and (b) the ratio $ {R}_{\eta }^{{\mathrm{p}}{\mathrm{o}}{\mathrm{r}}{\mathrm{e}}} $, under the conditions of $ {T}^{*}=1.5 $ and $ {\rho }_{{\mathrm{b}}}^{*}=0.8 $. The dashed line in panel (b) denotes the experimental result^[40] under the same conditions.

图 10  在$ {H}^{*}=6.0 $情况下, 体积黏度$ {\eta }_{{\mathrm{v}}}^{*}\left({z}^{*}\right) $随吸附势强度的变化　(a) $ {\rho }_{{\mathrm{b}}}^{*}=0.1 $; (b) $ {\rho }_{{\mathrm{b}}}^{*}=0.6 $

Fig. 10.  Influence of adsorption strength on the volume viscosity $ {\eta }_{{\mathrm{v}}}^{*}\left({z}^{*}\right) $ under the condition of $ {H}^{*}=6.0 $: (a) $ {\rho }_{{\mathrm{b}}}^{*}= $$ 0.1 $; (b) $ {\rho }_{{\mathrm{b}}}^{*}=0.6 $.

图 11  在$ {H}^{*}=6.0 $情况下, 受限流体中比值$ {R}_{\eta }^{{\mathrm{p}}{\mathrm{o}}{\mathrm{r}}{\mathrm{e}}} $随吸附势强度的变化

Fig. 11.  Influence of adsorption strength on the ratio $ {R}_{\eta }^{{\mathrm{p}}{\mathrm{o}}{\mathrm{r}}{\mathrm{e}}} $ of the confined fluids, under the condition of $ {H}^{*}=6.0 $.