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    Abroad: 97

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1. Tunable rigidity of (polymeric core)-(lipid shell) nanoparticles f.. [1535]
2. The nature of strength enhancement and weakening by pentagon-hepta.. [1464]
3. Mechanics of rolling of nanoribbon on tube and sphere [866]
4. Cell entry of one-dimensional nanomaterials occurs by tip recognit.. [827]
5. Cellular entry of graphene nanosheets: The role of thickness, oxid.. [806]
6. 碳纳米管的力学行为 [770]
7. A theoretical analysis of the surface dependent binding, peeling a.. [765]
8. Tunable band structures of polycrystalline graphene by external an.. [717]
9. A microfluidic tubing method and its application for controlled sy.. [660]
10. Mechenical behaviors of Carbon Nanotubes [643]
11. Cooperative entry of nanoparticles into the cell [627]
12. Molecular Dynamics Simulation of Peeling a DNA Molecule on Substra.. [589]
13. Nonlinear softening and hardening nonlocal bending stiffness of an.. [580]
14. Physicochemical properties of nanoparticles regulate translocation.. [578]
15. Stretch-induced softening of bending rigidity in graphene [555]
16. Stretch-induced softening of bending rigidity in graphene (vol 100.. [552]
17. Molecular analysis of interactions between dendrimers and asymmetr.. [514]
18. Generalization of Response Number for Dynamic Plastic Response of .. [509]
19. 五七环缺陷对多晶石墨烯强度的影响 [457]
20. Comparison of Various Adhesion Contact Theories and the Influence .. [452]
21. 生物单分子与基底粘附的MD模拟和力学分析 [448]
22. A generalization of the Coulomb's friction law: From graphene to m.. [439]
23. Tunable Mechanical Behavior of Carbon Nanoscroll Crystals Under Un.. [432]
24. Energy barrier for configurational transformation of graphene nano.. [423]
25. Reformation Capability of Short-Range Order and Their Medium-Range.. [411]
26. A Universal Law for Cell Uptake of One-Dimensional Nanomaterials [385]
27. Microfluidic Synthesis of Rigid Nanovesicles for Hydrophilic Reage.. [367]
28. Surface Energy-Controlled Self-Collapse of Carbon Nanotube Bundles.. [361]
29. Effect of Work of Adhesion on Nanoindentation [356]
30. Mechanics of rolling of nanoribbon on tube and sphere [255]
31. Notch strengthening or weakening governed by transition of shear f.. [238]
32. Cell entry of one-dimensional nanomaterials [230]
33. A molecular dynamics investigation of the deformation mechanism an.. [205]
34. A molecular dynamics study of bond exchange reactions in covalent .. [165]
35. Microfluidic Synthesis of Hybrid Nanoparticles with Controlled Lip.. [161]
36. 纳米颗粒与细胞的交互作用 [156]
37. Coarse-grained molecular dynamics studies of the translocation mec.. [150]
38. Nonspecific Organelle-Targeting Strategy with Core-Shell Nanoparti.. [144]
39. Grain boundary and curvature enhanced lithium adsorption on carbon [141]
40. Rotation-Facilitated Rapid Transport of Nanorods in Mucosal Tissue.. [136]
41. Lipid rafts enhance the binding constant of membrane-anchored rece.. [136]
42. c-axis preferential orientation of hydroxyapatite accounts for the.. [130]
43. 纳米颗粒形状对其在肠胃道黏液中扩散的影响 [117]
44. 肿瘤及其微环境的力学问题 [90]
45. 纳米颗粒形状对其在肠胃道黏液中扩散的影响 [82]
46. Targeting Endothelial Cell Junctions with Negatively Charged Gold .. [80]
47. Effects of graphene oxide nanosheets on the ultrastructure and bio.. [71]
48. 纳米颗粒作为细胞内药物载体的实验研究 [67]
49. Core-Satellite Nanomedicines for in Vivo Real-Time Monitoring of E.. [43]
50. Molecular dynamics simulation of diffusion of nanoparticles in muc.. [42]
51. Rapid transport of deformation-tuned nanoparticles across biologic.. [35]
52. Diffusion of rod-like nanoparticles in non-adhesive and adhesive p.. [20]

Downloads

1. The nature of strength enhancement and weakening by pentagon-hepta.. [471]
2. Tunable rigidity of (polymeric core)-(lipid shell) nanoparticles f.. [321]
3. Mechenical behaviors of Carbon Nanotubes [320]
4. Mechanics of rolling of nanoribbon on tube and sphere [311]
5. 碳纳米管的力学行为 [292]
6. A theoretical analysis of the surface dependent binding, peeling a.. [287]
7. A microfluidic tubing method and its application for controlled sy.. [277]
8. Cell entry of one-dimensional nanomaterials occurs by tip recognit.. [229]
9. Stretch-induced softening of bending rigidity in graphene (vol 100.. [200]
10. Tunable band structures of polycrystalline graphene by external an.. [195]
11. Cellular entry of graphene nanosheets: The role of thickness, oxid.. [185]
12. Molecular Dynamics Simulation of Peeling a DNA Molecule on Substra.. [179]
13. Physicochemical properties of nanoparticles regulate translocation.. [168]
14. Tunable Mechanical Behavior of Carbon Nanoscroll Crystals Under Un.. [156]
15. Cooperative entry of nanoparticles into the cell [152]
16. 五七环缺陷对多晶石墨烯强度的影响 [150]
17. Stretch-induced softening of bending rigidity in graphene [146]
18. Molecular analysis of interactions between dendrimers and asymmetr.. [146]
19. Energy barrier for configurational transformation of graphene nano.. [146]
20. A generalization of the Coulomb's friction law: From graphene to m.. [142]
21. Nonlinear softening and hardening nonlocal bending stiffness of an.. [141]
22. Surface Energy-Controlled Self-Collapse of Carbon Nanotube Bundles.. [137]
23. Microfluidic Synthesis of Rigid Nanovesicles for Hydrophilic Reage.. [119]
24. Comparison of Various Adhesion Contact Theories and the Influence .. [111]
25. Generalization of Response Number for Dynamic Plastic Response of .. [108]
26. A Universal Law for Cell Uptake of One-Dimensional Nanomaterials [88]
27. Mechanics of rolling of nanoribbon on tube and sphere [82]
28. A molecular dynamics investigation of the deformation mechanism an.. [78]
29. 纳米颗粒与细胞的交互作用 [62]
30. Cell entry of one-dimensional nanomaterials [52]
31. Reformation Capability of Short-Range Order and Their Medium-Range.. [52]
32. Effect of Work of Adhesion on Nanoindentation [44]
33. Microfluidic Synthesis of Hybrid Nanoparticles with Controlled Lip.. [43]
34. Lipid rafts enhance the binding constant of membrane-anchored rece.. [43]
35. 纳米颗粒形状对其在肠胃道黏液中扩散的影响 [40]
36. Notch strengthening or weakening governed by transition of shear f.. [36]
37. A molecular dynamics study of bond exchange reactions in covalent .. [33]
38. Rotation-Facilitated Rapid Transport of Nanorods in Mucosal Tissue.. [33]
39. Coarse-grained molecular dynamics studies of the translocation mec.. [31]
40. Grain boundary and curvature enhanced lithium adsorption on carbon [30]
41. Nonspecific Organelle-Targeting Strategy with Core-Shell Nanoparti.. [25]
42. Effects of graphene oxide nanosheets on the ultrastructure and bio.. [17]
43. 纳米颗粒作为细胞内药物载体的实验研究 [16]
44. Molecular dynamics simulation of diffusion of nanoparticles in muc.. [16]
45. 纳米颗粒形状对其在肠胃道黏液中扩散的影响 [12]
46. c-axis preferential orientation of hydroxyapatite accounts for the.. [11]
47. Targeting Endothelial Cell Junctions with Negatively Charged Gold .. [8]
48. 肿瘤及其微环境的力学问题 [8]
49. 生物单分子与基底粘附的MD模拟和力学分析 [5]
50. Diffusion of rod-like nanoparticles in non-adhesive and adhesive p.. [5]
51. Rapid transport of deformation-tuned nanoparticles across biologic.. [4]