100 Examples of sentences containing the adjective "athermal"

Definition

Athermal is an adjective used primarily in scientific contexts to describe a condition or process that is not influenced by temperature. It refers to phenomena that occur without the involvement of thermal energy or heat transfer. In some contexts, it may also describe materials or systems that do not absorb or emit thermal radiation.

Synonyms

• Non-thermal
• Isothermal (in specific contexts)
• Temperature-insensitive

Antonyms

• Thermal
• Heat-related
• Temperature-dependent

Examples

1. The athermal nature of the experiment ensured that external temperatures did not affect the results.
2. In a vacuum, many processes can be considered athermal due to the absence of heat exchange.
3. The athermal properties of the material make it ideal for use in sensitive electronic devices.
4. Researchers studied athermal states in quantum systems to better understand their behavior.
5. The athermal conditions in the laboratory allowed for precise measurements without thermal interference.
6. In astrophysics, athermal radiation contributes to the understanding of cosmic background radiation.
7. The athermal phase of the reaction was critical for maintaining sample integrity.
8. Engineers designed athermal components to ensure consistent performance in varying environments.
9. The athermal response of the sensor was crucial for accurate temperature readings.
10. Observations indicated that the process remained athermal despite changes in the surrounding environment.
11. The athermal behavior of the laser proved advantageous for high-speed applications.
12. In some cases, athermal transitions can occur at extremely low temperatures.
13. The study focused on the athermal dynamics of the molecular system.
14. The athermal characteristics of the device prevented overheating during operation.
15. Scientists are exploring athermal methods for energy transfer in nanoscale systems.
16. The athermal effect was evident in the results of the controlled experiments.
17. Their findings highlighted the significance of athermal regions in the material's structure.
18. The athermal regime of the process was essential for achieving desired outcomes.
19. Due to its athermal nature, the compound is suitable for high-temperature applications.
20. The athermal limits of the system were tested under various experimental conditions.
21. Understanding the athermal aspects can lead to breakthroughs in material science.
22. The athermal interaction between particles was studied for potential applications in nanotechnology.
23. The design focused on achieving athermal stability in extreme environments.
24. The athermal model provided a new perspective on energy conservation.
25. In a laboratory setting, the athermal approach yielded consistent results across trials.
26. The athermal process was carefully monitored to prevent any thermal fluctuations.
27. Their research emphasized the role of athermal dynamics in biological systems.
28. The athermal state was crucial for the functioning of the newly developed device.
29. By eliminating thermal effects, the researchers could focus on athermal phenomena.
30. The athermal condition helped to isolate the variable being tested.
31. The athermal nature of the simulation provided clarity in the data analysis.
32. The athermal regime is critical for certain types of chemical reactions.
33. The laboratory maintained an athermal environment to ensure sample viability.
34. The athermal characteristics of the laser system enhanced its precision.
35. An athermal approach can simplify complex thermal management challenges.
36. The athermal transition observed in the experiment was surprising to the researchers.
37. The material's athermal properties were tested under various stress conditions.
38. The athermal behavior of the system was a key focus of the research.
39. Engineers are developing athermal materials for use in aerospace applications.
40. The findings suggest that athermal dynamics can influence large-scale phenomena.
41. The researchers documented the athermal effects of light on the samples.
42. The athermal conditions enabled a more accurate assessment of the variables involved.
43. The athermal nature of the reaction allowed for extended observation periods.
44. The implications of the athermal findings could revolutionize several fields.
45. The athermal characteristics of the solution were crucial for successful outcomes.
46. In this context, the athermal model accurately predicted the system's behavior.
47. The team was excited to discover an athermal pathway in the reaction mechanism.
48. The athermal environment played a vital role in the experiment's success.
49. The athermal phenomena were observed even at high pressures.
50. Researchers noted the significance of athermal interactions in their conclusions.
51. An athermal system can provide advantages in energy efficiency.
52. The study illustrated how athermal processes affect reaction rates.
53. The athermal condition is often sought in high-performance computing systems.
54. The findings challenge previous assumptions about athermal states.
55. The athermal regime was essential for achieving the desired material properties.
56. The athermal approach reduces the risk of sample degradation.
57. The researchers developed a model to simulate athermal processes.
58. The athermal characteristics of the experiment were highlighted in the report.
59. The system's athermal nature allowed for flexible operational parameters.
60. The athermal analysis revealed unexpected trends in the data.
61. The findings underscore the importance of athermal conditions in experiments.
62. The athermal phase of the study provided insights into the underlying mechanisms.
63. The researchers utilized athermal techniques to enhance precision.
64. Understanding athermal dynamics can lead to new insights in thermodynamics.
65. The significance of athermal processes is increasingly recognized in multiple fields.
66. The athermal nature of the phenomenon raised questions about previous theories.
67. Advances in technology enable the exploration of athermal interactions.
68. The project focused on developing athermal systems for energy applications.
69. The athermal model provided a simplified view of complex interactions.
70. The experiments were designed to be athermal in nature to avoid bias.
71. The athermal dynamics observed were consistent with theoretical predictions.
72. The research group specializes in studying athermal states in materials.
73. The athermal properties of the compound were verified through rigorous testing.
74. Their work highlighted the role of athermal conditions in enhancing performance.
75. The implications of athermal findings extend to various scientific disciplines.
76. The athermal approach can minimize errors in experimental measurements.
77. The athermal nature of the reactions surprised many in the field.
78. The study provided a comprehensive overview of athermal phenomena.
79. The athermal behavior was crucial for understanding the system's functionality.
80. The research focused on the athermal characteristics of the new materials.
81. The athermal effects were analyzed in relation to temperature variations.
82. The implications of athermal properties are significant for future research.
83. The athermal nature of the environment allowed for extended experiments.
84. The findings emphasized the importance of athermal conditions in precision work.
85. The athermal characteristics of the chemical process were thoroughly investigated.
86. The team was intrigued by the athermal transitions observed in the study.
87. The athermal experiment yielded consistent results across multiple trials.
88. The researchers focused on understanding the athermal properties of the compound.
89. The athermal dynamics provided new insights into the molecular interactions.
90. The athermal characteristics of the environment contributed to the experiment's success.
91. The research delved into the athermal aspects of energy transfer.
92. The athermal response of the sample was critical for accurate analysis.
93. The findings about athermal phenomena could reshape existing theories.
94. The athermal phase of the experiment was especially challenging to achieve.
95. The study on athermal interactions opened new avenues for exploration.
96. The athermal nature of the reaction led to unexpected results.
97. The athermal model was validated through extensive testing.
98. The researchers documented the athermal conditions necessary for their experiments.
99. The athermal properties of the material make it ideal for a range of applications.
100. The implications of understanding athermal processes are vast and varied.