100 Examples of sentences containing the noun "adiabatic"

Definition

Adiabatic refers to a process in thermodynamics where no heat is transferred to or from the system to its surroundings. It is often used in the context of gas processes where changes occur without heat exchange, meaning any change in internal energy is solely due to work done on or by the system.

Synonyms

• Thermally insulated
• Isolated
• Non-heat transfer

Antonyms

• Isothermal
• Heat-exchanging
• Non-adiabatic

Examples

1. The gas adiabatically expanded in the insulated container.
2. During the process, the system adiabatically cooled down.
3. When a piston moves quickly, the air can adiabatically compress.
4. The temperature of the gas adiabatically increased as it was compressed.
5. An adiabatic process can be modeled using the ideal gas law.
6. The turbine worked efficiently in the adiabatic cycle.
7. As the balloon rises, the air inside adiabatically expands.
8. The adiabatic process is fundamental in understanding thermodynamic cycles.
9. Engineers designed the system to operate under adiabatic conditions.
10. The adiabatic assumption simplifies the calculations significantly.
11. The steam engine operates using an adiabatic expansion process.
12. In meteorology, adiabatic cooling is essential for cloud formation.
13. The scientist noted that any heat transfer would disrupt the adiabatic nature of the experiment.
14. The adiabatic lapse rate describes the rate of temperature change with altitude.
15. The ideal gas law applies well to adiabatic processes when no heat is exchanged.
16. During the experiment, the gas adiabatically lost energy.
17. The compressor adiabatically raised the air pressure.
18. Adiabatic heating occurs when a gas is compressed without heat loss.
19. The process was designed to remain adiabatic throughout its operation.
20. The researchers measured the adiabatic temperature changes carefully.
21. In a adiabatic system, the work done is equal to the change in internal energy.
22. The cooling effect of an adiabatic expansion is often used in refrigeration.
23. The adiabatic curve on a PV diagram shows the relationship between pressure and volume.
24. As air rises, it expands adiabatically, leading to cooling.
25. The adiabatic condition is critical for accurate thermodynamic calculations.
26. The engine operated under adiabatic conditions to maximize efficiency.
27. The balloon adiabatically filled with gas as it was heated.
28. The gas adiabatically adjusted its pressure in the chamber.
29. The concept of adiabatic processes is crucial for understanding heat engines.
30. The adiabatic efficiency of the cycle was analyzed in detail.
31. Adiabatic processes are frequently applied in thermodynamic studies.
32. The transition was almost adiabatic, with minimal heat loss.
33. The adiabatic nature of the reaction allowed for rapid cooling.
34. In an adiabatic process, the total energy remains constant.
35. The air adiabatically cooled as it ascended into the atmosphere.
36. The experiment confirmed that the system remained adiabatic throughout.
37. The adiabatic expansion of the gas resulted in a drop in temperature.
38. The understanding of adiabatic processes is fundamental in physics.
39. The turbine blades were designed for optimal adiabatic efficiency.
40. He explained how the adiabatic process affects the climate.
41. The adiabatic assumption helped simplify the equations.
42. The gas adiabatically transitioned between states during the cycle.
43. They observed the effects of adiabatic cooling in their experiments.
44. The calorimeter maintained an adiabatic environment for accurate measurements.
45. The adiabatic process was modeled using advanced simulations.
46. The adiabatic nature of the fluid dynamics was key to their research.
47. The principles of adiabatic processes govern many natural phenomena.
48. The ascent of the balloon involved adiabatic expansion of the helium.
49. The adiabatic nature of the reaction prevented energy loss.
50. The scientist concluded that the process was nearly adiabatic.
51. The pressure in the chamber adiabatically decreased as the gas expanded.
52. The adiabatic model helped illustrate the thermodynamic principles.
53. The heat engine operated efficiently under adiabatic conditions.
54. The adiabatic process was a key factor in their experimental design.
55. The researchers calculated the adiabatic coefficients for the gases involved.
56. The adiabatic flow in the pipe was essential for the experiment.
57. The cooling tower utilized adiabatic principles to dissipate heat.
58. The adiabatic changes in pressure were measured precisely.
59. The team studied how the air adiabatically expanded in different conditions.
60. The adiabatic approximation is a common assumption in thermodynamics.
61. The gas adiabatically reacted to the sudden drop in pressure.
62. The adiabatic compression process was carefully monitored.
63. The engineers designed the system to maintain adiabatic efficiency.
64. The adiabatic process allowed for rapid energy transfer.
65. The adiabatic nature of the reaction was confirmed through testing.
66. The system adiabatically adjusted to the new environmental conditions.
67. The adiabatic characteristics of the gas were analyzed thoroughly.
68. The experiment illustrated how the gas adiabatically changed state.
69. The adiabatic theory provided insight into the system's behavior.
70. The adiabatic process was essential for the success of the project.
71. The team analyzed the adiabatic effects on the material properties.
72. The adiabatic process was a crucial part of their findings.
73. The researchers calculated how the gas adiabatically responded to pressure changes.
74. The adiabatic efficiencies of the two designs were compared.
75. The adiabatic conditions ensured accurate results in the experiment.
76. The compressor operated under adiabatic principles for maximum efficiency.
77. The air adiabatically cooled as it passed through the turbine.
78. Understanding adiabatic processes is vital for climate modeling.
79. The adiabatic expansion resulted in a significant temperature drop.
80. The team focused on the adiabatic behavior of the gases involved.
81. The adiabatic process can be observed in natural phenomena.
82. The laboratory was equipped to conduct adiabatic experiments.
83. The adiabatic cycle was diagrammed for better understanding.
84. The gas adiabatically adjusted its temperature and pressure.
85. The principles of adiabatic processes were fundamental to their research.
86. The adiabatic nature of the experiment limited heat exchange.
87. The team observed how the gas adiabatically interacted with its environment.
88. The adiabatic curves on the graph represented the experimental data.
89. The adiabatic behavior of the system was critical to their analysis.
90. The gas adiabatically reached equilibrium after the expansion.
91. The researchers noted the significance of adiabatic processes in thermodynamics.
92. The adiabatic equation was derived from first principles.
93. The team designed an experiment to test adiabatic theories.
94. The adiabatic nature of the reaction prevented loss of energy.
95. The gas adiabatically adjusted its properties in response to external changes.
96. The adiabatic assumptions were validated through experiments.
97. The effects of adiabatic expansion were studied in detail.
98. The adiabatic calculations were crucial for their model.
99. The lab conducted a study on adiabatic processes in various substances.
100. The findings supported the theory of adiabatic behavior in gases.