100 Examples of sentences containing the common noun "plasmoid"

Definition

Plasmoid refers to a coherent structure of plasma, often appearing as a cloud of ionized gas or a magnetic entity in space or laboratory settings. In certain scientific contexts, it can also pertain to a specific phenomenon involving the formation of plasma under specific conditions, such as in fusion research or astrophysical events.

Synonyms

• Plasma formation
• Plasma entity
• Plasma structure

Antonyms

• Solid
• Liquid
• Gas (in a non-ionized state)

Examples

1. The researchers were eager to observe how the plasmoid interacted with the surrounding magnetic field.
2. Scientists believe that the plasmoid could hold the key to understanding fusion processes.
3. During the experiment, the team managed to create a stable plasmoid in the laboratory.
4. The plasmoid emitted light as it moved through the vacuum chamber.
5. Astronomers captured images of a massive plasmoid erupting from the sun.
6. The plasmoid generated by the device was unlike anything seen before.
7. They aimed to measure the energy output of the plasmoid during the trial.
8. The formation of a plasmoid can lead to unexpected results in plasma physics.
9. The plasmoid was ejected at high speeds, demonstrating its dynamic nature.
10. Understanding the behavior of the plasmoid is crucial for advances in plasma technology.
11. The team hypothesized that the plasmoid played a role in the observed anomalies.
12. By analyzing the plasmoid, scientists could gain insights into cosmic phenomena.
13. The laboratory's new equipment allowed for the creation of a controlled plasmoid.
14. Researchers noted that the plasmoid could influence surrounding particles.
15. The energy contained within the plasmoid was measured in terajoules.
16. A plasmoid can appear during solar flares, impacting space weather.
17. The stability of the plasmoid was a significant factor in the experiment's success.
18. The dynamics of the plasmoid are still not fully understood by scientists.
19. A variety of methods exist to generate a plasmoid in laboratory conditions.
20. The plasmoid formed rapidly, catching the attention of all the observers.
21. The characteristics of the plasmoid changed as the temperature increased.
22. The researchers were thrilled to document the behavior of the plasmoid.
23. Various simulations were run to predict the life cycle of the plasmoid.
24. The energy transfer within the plasmoid was a focal point of their study.
25. The plasmoid was observed to collapse under certain pressures.
26. Understanding how to control a plasmoid could revolutionize energy production.
27. The team successfully visualized the plasmoid using high-speed cameras.
28. They compared the laboratory plasmoid to natural occurrences in space.
29. The plasmoid was theorized to be a potential source of renewable energy.
30. The interaction between the plasmoid and magnetic fields was complex.
31. Scientists used advanced sensors to analyze the plasmoid in real-time.
32. The plasmoid exhibited behaviors similar to those of a liquid in motion.
33. Their findings on the plasmoid were published in a leading scientific journal.
34. The team was determined to understand the mechanics of the plasmoid.
35. The plasmoid released energy in pulses, which were carefully measured.
36. The formation process of the plasmoid was documented step by step.
37. Observers noted a bright flash when the plasmoid was created.
38. The research on plasmoid stability has practical applications for space travel.
39. The plasmoid was the focus of an international conference on plasma physics.
40. It was crucial to maintain the temperature to stabilize the plasmoid.
41. The plasmoid was recreated multiple times to verify the results.
42. The energy density of the plasmoid was astonishingly high.
43. The plasmoid formation was triggered by a sudden influx of energy.
44. The scientists aimed to harness the plasmoid for new technologies.
45. They studied how the plasmoid interacted with other plasma structures.
46. The research group was awarded for their work on the plasmoid.
47. The plasmoid flickered as it reached the boundaries of its containment.
48. The team speculated about the implications of the plasmoid for astrophysics.
49. The plasmoid was visualized using advanced plasma diagnostics.
50. They aimed to replicate the conditions that created the natural plasmoid.
51. The plasmoid was theorized to exist in various astrophysical environments.
52. Observations of the plasmoid provided data for further analysis.
53. The plasmoid generated during the experiment was unstable but intriguing.
54. The research on the plasmoid could influence future space missions.
55. The scientists recorded the frequency of the plasmoid's oscillations.
56. The plasmoid was observed to change shape under varying conditions.
57. The breakthrough came when they successfully contained the plasmoid.
58. The plasmoid can be influenced by external magnetic fields.
59. They hypothesized that the plasmoid might be linked to dark matter.
60. The plasmoid's behavior challenged existing theories in plasma physics.
61. The creation of the plasmoid was a significant milestone in their research.
62. The researchers were excited to share their findings on the plasmoid.
63. The plasmoid was generated using a high-energy laser.
64. The interaction of the plasmoid with its environment was complex.
65. The plasmoid was used in experiments to test electromagnetic theories.
66. They recorded the energy levels produced by the plasmoid.
67. The plasmoid was theorized to be a common feature in cosmic events.
68. Their work on the plasmoid expanded the understanding of plasma dynamics.
69. The plasmoid exhibited unique properties that warranted further study.
70. The stability of the plasmoid was a key factor in its potential applications.
71. The plasmoid was generated in a controlled environment for analysis.
72. The team published a detailed study on their observations of the plasmoid.
73. The plasmoid collapsed spectacularly during the experimental phase.
74. Understanding the plasmoid could lead to advancements in energy storage.
75. The plasmoid emitted radiation that was carefully monitored.
76. The potential of the plasmoid for practical use was explored in depth.
77. The plasmoid was a focal point in discussions about future technologies.
78. Scientists debated the implications of their findings on the plasmoid.
79. The plasmoid was theorized to behave similarly to a liquid under certain conditions.
80. The interaction between the plasmoid and other particles was examined.
81. A detailed analysis of the plasmoid provided new insights into plasma behavior.
82. The plasmoid was created using a novel technique developed by the team.
83. Observations of the plasmoid have implications for astrophysical research.
84. The plasmoid was theorized to exist in the atmospheres of distant planets.
85. The researchers aimed to create a long-lasting plasmoid for experimentation.
86. The plasmoid demonstrated properties that could be harnessed for energy.
87. The team was eager to publish their findings on the plasmoid phenomenon.
88. The plasmoid was monitored for changes in its energy output.
89. They were able to stabilize the plasmoid for extended periods.
90. The plasmoid was identified as a significant factor in their research.
91. The implications of the plasmoid for understanding the universe were profound.
92. The plasmoid was a critical component in their experimental setup.
93. The researchers were excited to explore the potential applications of the plasmoid.
94. The plasmoid was created using a combination of heat and pressure.
95. The dynamics of the plasmoid were observed to be highly variable.
96. They aimed to replicate the conditions that led to the formation of the plasmoid.
97. The plasmoid was theorized to play a role in solar phenomena.
98. Their hypothesis regarding the plasmoid was supported by experimental data.
99. The plasmoid was of particular interest to researchers studying fusion energy.
100. The study of the plasmoid has opened new avenues in plasma research.