Spherulite example sentences

"Spherulite" Example Sentences

1. The microscopic image revealed a complex array of spherulites.
2. Analysis showed the polymer sample contained numerous small spherulites.
3. Spherulite size directly impacts the material's mechanical properties.
4. He meticulously documented the growth patterns of each spherulite.
5. The researchers observed a significant increase in spherulite density.
6. Rapid cooling led to the formation of fine spherulites.
7. Slow cooling resulted in fewer, larger spherulites.
8. This particular polymer exhibits distinctive spherulite morphology.
9. The spherulite structure is crucial to the material's strength.
10. Their study focused on the nucleation and growth of spherulites.
11. Crystallization kinetics influence the size and distribution of spherulites.
12. Identifying the spherulite structure is vital for quality control.
13. We observed unusual spherulite shapes under polarized light.
14. The presence of impurities affected spherulite development.
15. The team developed a model to predict spherulite growth.
16. Controlling spherulite size is key to optimizing performance.
17. Each spherulite acted as a separate crystalline domain.
18. Their research paper detailed the unique spherulite formations.
19. The sample showed a radial pattern characteristic of spherulites.
20. Microscopic analysis confirmed the presence of spherulites in the sample.
21. A single spherulite can be surprisingly complex.
22. The spherulite radius varied significantly across the sample.
23. Understanding spherulite growth is essential for materials science.
24. The experiment demonstrated the effects of additives on spherulite formation.
25. Variations in spherulite size reflected processing conditions.
26. They measured the average spherulite diameter.
27. Spherulite morphology provides insights into crystallization behavior.
28. The optical properties were directly influenced by spherulite orientation.
29. The texture was noticeably changed by the presence of large spherulites.
30. Polymer chains arranged radially within each spherulite.
31. The spherulites exhibited a Maltese cross pattern under crossed polars.
32. The study aimed to correlate spherulite size to tensile strength.
33. Improved processing techniques yielded smaller, more uniform spherulites.
34. The research highlighted the impact of temperature on spherulite size.
35. Nucleation density was directly related to the number of spherulites formed.
36. Crystal imperfections frequently occur at spherulite boundaries.
37. They investigated the relationship between crystallization time and spherulite growth rate.
38. This spherulite appears to be abnormally large.
39. Small angle X-ray scattering revealed internal structure within spherulites.
40. The spherulite's crystalline structure was confirmed by diffraction analysis.
41. Controlling the rate of cooling can affect spherulite formation.
42. The researchers used polarized light microscopy to study spherulites.
43. Spherulites, in this context, are crucial for understanding the material.
44. The material's opacity is partially attributed to the presence of numerous spherulites.
45. We observed a clear correlation between processing parameters and spherulite size distribution.
46. The formation of spherulites is a complex process involving multiple factors.
47. Diffraction patterns from individual spherulites were analyzed separately.
48. The observed spherulite morphology suggests a specific crystallization pathway.
49. In conclusion, spherulite characteristics significantly influence material properties.
50. Further research into spherulite formation is warranted.

Common Phases

1. Spherulite growth kinetics significantly impact material properties.
2. The spherulite size distribution affects the overall mechanical strength.
3. Crystallization conditions heavily influence spherulite morphology.
4. Spherulite formation is a complex process involving nucleation and growth.
5. Controlling spherulite size is crucial for optimal performance.
6. The presence of impurities can alter spherulite development.
7. Microscopic analysis reveals the intricate structure of spherulites.
8. Spherulite density is a key parameter in material characterization.
9. Variations in spherulite orientation lead to anisotropic properties.
10. Understanding spherulite structure enhances polymer processing techniques.
11. Spherulitic crystallization is a common feature in many polymers.
12. The radial structure of spherulites is readily observable.
13. Precise control over spherulite size remains a challenge.
14. Spherulite morphology can be tailored for specific applications.
15. Advanced imaging techniques are employed to study spherulites.
16. The optical properties are often influenced by spherulite arrangement.
17. Spherulite-based materials exhibit unique mechanical behavior.
18. The thermal history affects the resulting spherulite structure.
19. Nucleating agents promote controlled spherulite formation.
20. Modeling spherulite growth requires sophisticated simulation techniques.