100 Examples of sentences containing the noun "autotrophism"

Definition

Autotrophism refers to the process by which certain organisms, known as autotrophs, produce their own food from inorganic substances. This process typically involves photosynthesis or chemosynthesis, allowing these organisms to convert light energy or chemical energy into organic compounds.

Synonyms

• Autotrophy
• Self-feeding
• Primary production

Antonyms

• Heterotrophism
• Dependency
• Parasitism

Examples

1. Many plants exhibit autotrophism through photosynthesis.
2. The study of autotrophism is essential for understanding ecosystems.
3. Bacteria can display autotrophism by utilizing chemical reactions for energy.
4. Scientists are researching the implications of autotrophism in climate change.
5. Without autotrophism, food chains would collapse.
6. The concept of autotrophism is fundamental in biology.
7. Autotrophism allows organisms to thrive in environments lacking organic materials.
8. Many aquatic organisms demonstrate autotrophism in unique ways.
9. The efficiency of autotrophism affects agricultural yields.
10. Understanding autotrophism helps us appreciate the balance of nature.
11. Plants rely on autotrophism to convert sunlight into energy.
12. The role of autotrophism in carbon fixation is crucial for life on Earth.
13. Researchers are exploring the limits of autotrophism in extreme environments.
14. The evolution of autotrophism has shaped the planet's biodiversity.
15. Certain algae exhibit remarkable autotrophism in nutrient-poor waters.
16. Autotrophism is a key factor in the productivity of marine ecosystems.
17. The discovery of autotrophism in deep-sea vents changed our understanding of life.
18. Autotrophism supports the base of the food web in terrestrial habitats.
19. The process of autotrophism is often studied in ecology courses.
20. Fungi do not exhibit autotrophism; they are heterotrophic.
21. Autotrophism is essential for the survival of herbivores.
22. During the summer, plants maximize autotrophism through longer daylight hours.
23. The efficiency of autotrophism varies among different species.
24. Understanding autotrophism can lead to advancements in sustainable agriculture.
25. The decline of autotrophism among coral reefs is alarming.
26. Autotrophism can be impacted by changes in climate and habitat.
27. Some researchers focus on enhancing autotrophism in crops.
28. Autotrophism is a vital process for oxygen production in the atmosphere.
29. The relationship between autotrophism and heterotrophism is intricate.
30. Autotrophism enables life to flourish in various ecosystems.
31. The impact of pollution on autotrophism is a significant environmental concern.
32. Autotrophism is a fundamental characteristic of green plants.
33. Without autotrophism, Earth’s atmosphere would lack oxygen.
34. The mechanisms of autotrophism are complex and varied.
35. Plants play a crucial role in autotrophism within their habitats.
36. Understanding autotrophism helps in developing biofuels.
37. The decline in autotrophism can lead to food shortages.
38. Autotrophism is a key concept in understanding ecological interactions.
39. The discovery of new forms of autotrophism has broadened our knowledge of life.
40. Autotrophism allows for the recycling of nutrients in an ecosystem.
41. The efficiency of photosynthesis is a measure of autotrophism.
42. Autotrophism can be influenced by environmental factors such as light and water.
43. The study of autotrophism provides insights into evolutionary biology.
44. Agricultural practices can enhance autotrophism in crops.
45. The relationship between autotrophism and biodiversity is significant.
46. Autotrophism is essential for maintaining the planet's oxygen levels.
47. Algae are often studied for their unique forms of autotrophism.
48. The concept of autotrophism dates back to early biological studies.
49. Advances in biotechnology may improve autotrophism in crops.
50. Autotrophism is a critical factor in bioenergy production.
51. Understanding autotrophism is vital for conservation efforts.
52. The decline of autotrophism in certain species raises ecological red flags.
53. Autotrophism in plants is often enhanced through genetic modification.
54. The relationship between soil quality and autotrophism is closely studied.
55. Autotrophism contributes to the carbon cycle on Earth.
56. The process of autotrophism is essential for life as we know it.
57. Autotrophism can vary significantly between different ecosystems.
58. The efficiency of autotrophism can be measured through biomass production.
59. The role of autotrophism in carbon sequestration is increasingly recognized.
60. Autotrophism is a driving force behind ecological succession.
61. The decline of autotrophic species can disrupt autotrophism in ecosystems.
62. Autotrophism is crucial for the survival of many marine species.
63. The interplay between autotrophism and climate change is a hot research topic.
64. Understanding autotrophism is essential for addressing food security issues.
65. Autotrophism allows organisms to harness solar energy for growth.
66. The study of autotrophism helps us understand energy flow in ecosystems.
67. Autotrophism is key to the productivity of terrestrial and aquatic environments.
68. The evolution of autotrophism has led to diverse life forms.
69. Some extremophiles exhibit unique forms of autotrophism.
70. Autotrophism is a critical component of agricultural sustainability.
71. The balance between autotrophism and heterotrophism is crucial in ecosystems.
72. The decline of autotrophism in certain regions can lead to biodiversity loss.
73. Autotrophism is often influenced by human activities and pollution.
74. Understanding the mechanisms of autotrophism can aid in ecological restoration.
75. Autotrophism is fundamental to the functioning of food webs.
76. The efficiency of autotrophism can be optimized through various techniques.
77. Autotrophism is essential for the survival of many terrestrial species.
78. The concept of autotrophism is foundational in environmental science.
79. The relationship between autotrophism and soil health is critical.
80. Autotrophism plays a vital role in nutrient cycling within ecosystems.
81. The process of autotrophism is vital for maintaining ecosystem balance.
82. Autotrophism allows organisms to create energy from sunlight.
83. The study of autotrophism encompasses various scientific disciplines.
84. The implications of autotrophism for climate policy are significant.
85. Autotrophism is a key factor in predicting ecological responses to change.
86. Understanding the diversity of autotrophism can enhance conservation strategies.
87. Autotrophism is crucial for maintaining global oxygen levels.
88. The relationship between autotrophism and water availability is complex.
89. Autotrophism is often studied in the context of ecosystem services.
90. The decline of autotrophism in urban areas poses challenges for biodiversity.
91. Autotrophism can be affected by changes in land use practices.
92. The study of autotrophism can lead to innovations in food production.
93. Autotrophism enables life to persist in extreme environments.
94. The role of autotrophism in nutrient availability is critical for plant growth.
95. Autotrophism is a fundamental aspect of ecological research.
96. The efficiency of autotrophism can impact overall ecosystem health.
97. Autotrophism is essential for sustaining life on Earth.
98. The impact of climate change on autotrophism is a growing concern.
99. Autotrophism is a key driver of productivity in natural systems.
100. The future of autotrophism is vital to understanding ecological resilience.