Spherocylinder example sentences

"Spherocylinder" Example Sentences

1. The spherocylinder model accurately predicted the particle's behavior in the simulation.
2. His research focused on the optical properties of a spherocylinder.
3. We used a spherocylinder-shaped probe to investigate the surface morphology.
4. The spherocylinder's elongated shape influenced its sedimentation rate.
5. Unlike a sphere, a spherocylinder exhibits anisotropic properties.
6. The software allowed for the creation of custom spherocylinder geometries.
7. Determining the precise volume of a spherocylinder requires careful calculation.
8. They modeled the virus particle as a spherocylinder for their hydrodynamic simulations.
9. The experiment involved aligning many spherocylinders in a magnetic field.
10. Its spherocylinder shape is crucial to its function in the cell.
11. A novel method for measuring the length of a spherocylinder was developed.
12. The spherocylinders were dispersed randomly throughout the solution.
13. This spherocylinder has a unique aspect ratio, unlike those previously studied.
14. We observed interesting self-assembly behavior in the spherocylinders.
15. The spherocylinder rotated slowly under the applied torque.
16. Simulations using spherocylinders provided valuable insights into liquid crystal behavior.
17. The spherocylinder's surface was modified to enhance its interaction with the substrate.
18. The study compared the flow behavior of spheres and spherocylinders.
19. The spherocylinder acted as a nanoscale template for material synthesis.
20. The team successfully synthesized monodisperse spherocylinders of controlled dimensions.
21. Imagine a spherocylinder: part sphere, part cylinder.
22. The orientation of the spherocylinders affected the optical properties of the material.
23. Modeling the spherocylinder as a rigid body simplified the calculations.
24. The spherocylinders aggregated to form complex structures.
25. He meticulously measured the dimensions of each spherocylinder.
26. The spherocylinder's unique shape allowed for efficient packing.
27. Understanding the dynamics of spherocylinders is crucial in many fields.
28. The spherocylinder was carefully positioned within the microfluidic channel.
29. The researchers developed a new algorithm for simulating spherocylinders.
30. Unexpected results arose from the interactions between the spherocylinders.
31. This particular spherocylinder design is patented.
32. The spherocylinder curvature played a significant role in its behavior.
33. The spherocylinders were suspended in a viscous fluid.
34. Surprisingly, the spherocylinders exhibited self-propulsion.
35. The experiment demonstrated the importance of spherocylinder aspect ratio.
36. The spherocylinder served as a model for various biological structures.
37. They used advanced microscopy techniques to image the spherocylinders.
38. Further research is needed to understand the complex behavior of spherocylinders under shear flow.
39. The spherocylinder exhibited unusual birefringence.
40. The article detailed a new method for fabricating spherocylinders.
41. The spherocylinder’s properties were carefully characterized.
42. It was a spherocylinder, not a cylinder, that they used in the test.
43. The computer model accurately predicted the tumbling of the spherocylinder.
44. The size of the spherocylinder was crucial to its function.
45. The spherocylinders were used as building blocks in a novel metamaterial.
46. The experiment involved manipulating individual spherocylinders with optical tweezers.
47. The spherocylinder design improved the efficiency of the device.
48. This type of spherocylinder is rarely found in nature.
49. The spherocylinder's symmetry was broken by an applied electric field.
50. A spherocylinder is a useful model in many scientific simulations.

Common Phases

1. Spherocylinder lens technology is revolutionizing the industry.
2. The spherocylinder's unique geometry allows for precise optical control.
3. Modeling the light scattering from a spherocylinder is computationally intensive.
4. The spherocylinder's surface area is crucial in determining its behavior.
5. Understanding spherocylinder packing is important for material science.
6. Spherocylinders are frequently used in simulations of biological systems.
7. The use of spherocylinders in this context simplifies the model significantly.
8. This novel method accurately predicts spherocylinder orientation.
9. The spherocylinder's aspect ratio is a key parameter to consider.
10. Spherocylinder aggregates exhibit unique optical properties.
11. The spherocylinder's curved surface interacts differently with light.
12. Many studies have investigated the hydrodynamic properties of spherocylinders.
13. Accurate measurement of spherocylinder dimensions is challenging.
14. The spherocylinder's rotational diffusion is slower than that of a sphere.
15. We propose a new algorithm for simulating spherocylinder dynamics.
16. The spherocylinder remains a useful model for various applications.
17. Advances in spherocylinder research are driving innovation.
18. Spherocylinders provide a good approximation for certain biological shapes.
19. Characterizing the interactions between multiple spherocylinders is difficult.
20. The spherocylinder's shape plays a critical role in its behavior.