100 Examples of sentences containing the common noun "supernovae"

Definition

A supernova is a powerful and luminous explosion of a star, marking the end of its life cycle. The term "supernovae" refers to the plural form of supernova, indicating multiple occurrences of this astronomical event. Supernovae can result in the formation of neutron stars or black holes and play a critical role in dispersing elements into space, contributing to the chemical enrichment of the universe.

Synonyms

• Stellar explosion
• Starburst
• Cosmic explosion

Antonyms

• Star formation
• Stellar birth

Examples

1. The scientists observed how supernovae supernovae in distant galaxies.
2. Astronomers study the light emitted by supernovae supernovae to understand the universe's evolution.
3. The discovery of new supernovae supernovae has led to advances in astrophysics.
4. Supernovae supernovae every few decades in our galaxy.
5. The remnants of supernovae supernovae can form beautiful nebulae.
6. Researchers are excited to see how supernovae supernovae influence the formation of new stars.
7. The energy released by supernovae supernovae is staggering.
8. Some supernovae supernovae are visible to the naked eye from Earth.
9. The study of supernovae supernovae provides insights into the life cycle of stars.
10. When stars reach the end of their life, they often supernovae spectacularly.
11. The light curves of supernovae supernovae reveal their distance from Earth.
12. Astronomers use telescopes to monitor supernovae supernovae in real-time.
13. The remnants of ancient supernovae supernovae can be found throughout the Milky Way.
14. Gamma-ray bursts may be linked to the collapse of supernovae supernovae.
15. The chemical elements produced by supernovae supernovae are vital for planetary formation.
16. Some supernovae supernovae produce shock waves that can trigger new star formation.
17. The phenomenon of supernovae supernovae has fascinated scientists for centuries.
18. The supernovae supernovae that occurred in the early universe were crucial for its evolution.
19. Certain types of supernovae supernovae can be used to measure cosmic distances.
20. The explosion of supernovae supernovae can outshine entire galaxies for a short time.
21. Every year, astronomers discover numerous supernovae supernovae across the cosmos.
22. The research team tracked supernovae supernovae to understand their origins.
23. Supernovae supernovae can leave behind pulsars that emit regular signals.
24. The aftermath of supernovae supernovae can be observed for thousands of years.
25. When a massive star runs out of fuel, it supernovae dramatically.
26. The light from distant supernovae supernovae helps measure the expansion of the universe.
27. Observing how supernovae supernovae impacts surrounding matter is critical for astrophysical studies.
28. Some theorists suggest that dark energy might be linked to supernovae supernovae.
29. The study of supernovae supernovae has led to discoveries about neutron stars.
30. The brightness of supernovae supernovae can vary greatly depending on their type.
31. Supernovae supernovae are classified into different categories based on their characteristics.
32. The role of supernovae supernovae in dispersing heavy elements is well-documented.
33. Some supernovae supernovae are the result of binary star systems.
34. The energy released during supernovae supernovae can affect nearby celestial bodies.
35. A supernova supernovae can be a significant event in the lifecycle of a galaxy.
36. The patterns of supernovae supernovae can shed light on star formation rates.
37. Supernovae supernovae can trigger the creation of new stars in dense regions of space.
38. The remnants of supernovae supernovae can be studied for clues about their progenitors.
39. The energy from supernovae supernovae can influence the interstellar medium.
40. Observations of supernovae supernovae have helped refine models of cosmic evolution.
41. The light emitted from supernovae supernovae can travel billions of years to reach us.
42. The diversity of supernovae supernovae challenges our understanding of stellar evolution.
43. Some theories propose that supernovae supernovae may be the source of cosmic rays.
44. The explosion of supernovae supernovae can create vast clouds of gas and dust.
45. Supernovae supernovae are essential for creating heavy elements like gold and silver.
46. The observation of supernovae supernovae has increased with advanced telescopes.
47. Astronomical surveys often focus on identifying new supernovae supernovae.
48. The frequency of supernovae supernovae can vary between different types of galaxies.
49. The end stages of a star's life often culminate in a supernovae event.
50. The gravitational waves produced by supernovae supernovae can be detected on Earth.
51. Learning how supernovae supernovae affect their surroundings is an ongoing area of research.
52. The timing of supernovae supernovae can provide a history of star formation.
53. The behavior of supernovae supernovae is influenced by their mass and composition.
54. Supernovae supernovae can lead to the formation of black holes.
55. The explosive force of supernovae supernovae can change the dynamics of a galaxy.
56. Some supernovae supernovae are so bright they can be seen from millions of light-years away.
57. The decay of radioactive elements from supernovae supernovae can be measured over time.
58. The remnants of supernovae supernovae serve as laboratories for studying high-energy physics.
59. The light from supernovae supernovae can provide information about the star's mass.
60. The discovery of a new supernova supernovae can excite the scientific community.
61. Some supernovae supernovae are more energetic than others, creating different phenomena.
62. Supernovae supernovae can leave behind an expanding shell of gas and dust.
63. The study of supernovae supernovae is crucial for our understanding of the universe's fate.
64. Supernovae supernovae can release more energy than the Sun will emit in its entire life.
65. The remnants of supernovae supernovae can be observed for thousands of years.
66. Astronomers have developed models to predict when stars will supernovae.
67. Observing supernovae supernovae helps refine our understanding of cosmology.
68. The shockwaves from supernovae supernovae can trigger star formation in nearby clouds.
69. The study of supernovae supernovae can help scientists understand dark matter.
70. Some ancient cultures observed supernovae supernovae and recorded them in their history.
71. The light emitted from supernovae supernovae can be used to measure distances in space.
72. The chemical signatures of supernovae supernovae can reveal the history of the universe.
73. Supernovae supernovae are a key factor in the life cycle of a galaxy.
74. The explosive nature of supernovae supernovae can create new elements through nucleosynthesis.
75. The study of supernovae supernovae often involves collaboration between multiple observatories.
76. The glow from supernovae supernovae can be detected across vast distances.
77. The remnants of supernovae supernovae can provide insights into the conditions of the early universe.
78. New technologies are helping to track and analyze supernovae supernovae more efficiently.
79. Some supernovae supernovae can be predicted based on their progenitor stars' characteristics.
80. The light from supernovae supernovae can help calibrate distance measurements in the cosmos.
81. The processes that lead to a supernova supernovae are still an area of active research.
82. The impact of supernovae supernovae on their host galaxies can be dramatic.
83. Supernovae supernovae are essential for understanding the balance of elements in the universe.
84. The remnants of supernovae supernovae can eventually form new stars and planets.
85. Researchers are studying how supernovae supernovae affect cosmic microwave background radiation.
86. The study of supernovae supernovae involves both observational and theoretical approaches.
87. Supernovae supernovae can provide critical clues about the structure of the universe.
88. The energy from supernovae supernovae can have implications for galaxy formation.
89. The diversity in supernovae supernovae types can tell us about different stellar evolution pathways.
90. Supernovae supernovae are one of the universe's most spectacular events.
91. The light from supernovae supernovae can reveal details about their explosion mechanisms.
92. Scientists are using supernovae supernovae to probe the mysteries of dark energy.
93. The end stages of a massive star often lead to a dramatic supernovae explosion.
94. Observations of supernovae supernovae have led to significant advancements in astrophysics.
95. The aftermath of supernovae supernovae can create conditions for new star systems to form.
96. The study of supernovae supernovae is critical for understanding the evolution of galaxies.
97. Some supernovae supernovae are used as standard candles in measuring cosmic distances.
98. The remnants of supernovae supernovae can be rich in heavy elements formed during the explosion.
99. Understanding how supernovae supernovae contribute to galactic evolution is a key research focus.
100. The brilliant light of supernovae supernovae can illuminate distant galaxies for astronomers.