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Results: 12

1.
Figure 1

Figure 1. From: Heterogeneous nanofluids: natural convection heat transfer enhancement.

Physical model and coordinate system.

Fakhreddine Segni Oueslati, et al. Nanoscale Res Lett. 2011;6(1):222-222.
2.
Figure 3

Figure 3. From: Heterogeneous nanofluids: natural convection heat transfer enhancement.

Specific heat capacity versus nanoparticle concentration (Al2O3).

Fakhreddine Segni Oueslati, et al. Nanoscale Res Lett. 2011;6(1):222-222.
3.
Figure 5

Figure 5. From: Heterogeneous nanofluids: natural convection heat transfer enhancement.

Nanoparticle fraction effect on heat transfer (a = 0, A = 1, RT = 105).

Fakhreddine Segni Oueslati, et al. Nanoscale Res Lett. 2011;6(1):222-222.
4.
Figure 12

Figure 12. From: Heterogeneous nanofluids: natural convection heat transfer enhancement.

Vertical velocity on the horizontal mid-plan (RT = 104, φ = 2%, Le = 3 and Sr = 2%).

Fakhreddine Segni Oueslati, et al. Nanoscale Res Lett. 2011;6(1):222-222.
5.
Figure 2

Figure 2. From: Heterogeneous nanofluids: natural convection heat transfer enhancement.

Dynamic and thermal fields in the case of classical natural convection (without particles and Soret effect, Pr = 0.71).

Fakhreddine Segni Oueslati, et al. Nanoscale Res Lett. 2011;6(1):222-222.
6.
Figure 11

Figure 11. From: Heterogeneous nanofluids: natural convection heat transfer enhancement.

Temperature (a) and concentration (b) on the horizontal mid-plan (RT = 104, φ = 2%, Le = 3 and Sr = 2%).

Fakhreddine Segni Oueslati, et al. Nanoscale Res Lett. 2011;6(1):222-222.
7.
Figure 9

Figure 9. From: Heterogeneous nanofluids: natural convection heat transfer enhancement.

Nanoparticle fraction effect on heat transfer for different kind of particle: homogeneous case (a = 0, A = 1, RT = 105).

Fakhreddine Segni Oueslati, et al. Nanoscale Res Lett. 2011;6(1):222-222.
8.
Figure 8

Figure 8. From: Heterogeneous nanofluids: natural convection heat transfer enhancement.

Dynamic, thermal and species fields for different nature of nanoparticle (RT = 104, φ = 2%, Pr = 6.2, Sr = 2% and Le = 3).

Fakhreddine Segni Oueslati, et al. Nanoscale Res Lett. 2011;6(1):222-222.
9.
Figure 7

Figure 7. From: Heterogeneous nanofluids: natural convection heat transfer enhancement.

Effect of nanofluid concentration on relative heat transfer for different RT (a = 1, A = 1, Sr = 2%, Pr = 6.2 and Le = 3).

Fakhreddine Segni Oueslati, et al. Nanoscale Res Lett. 2011;6(1):222-222.
10.
Figure 10

Figure 10. From: Heterogeneous nanofluids: natural convection heat transfer enhancement.

Effect of nature of nanoparticle on the nanofluid heat transfer: heterogeneous case (RT = 104, Pr = 6.2, Sr = 2% and Le = 3).

Fakhreddine Segni Oueslati, et al. Nanoscale Res Lett. 2011;6(1):222-222.
11.
Figure 4

Figure 4. From: Heterogeneous nanofluids: natural convection heat transfer enhancement.

Relative viscosity (a), thermal conductivity (b) and specific heat capacity (c) versus nanoparticle concentration for different kind of particles.

Fakhreddine Segni Oueslati, et al. Nanoscale Res Lett. 2011;6(1):222-222.
12.
Figure 6

Figure 6. From: Heterogeneous nanofluids: natural convection heat transfer enhancement.

Dynamic, thermal and concentration fields for homogeneous (plotted by dashed lines) and heterogeneous (plotted by solid lines) cases (RT = 104, Pr = 6.2, Le = 3, Sr = 0.5%, φ = 2%, N = 1.75).

Fakhreddine Segni Oueslati, et al. Nanoscale Res Lett. 2011;6(1):222-222.

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