100 Examples of sentences containing the common noun "phytoplankton"

Definition

Phytoplankton refers to the microscopic, photosynthetic organisms found in aquatic environments, primarily in oceans and freshwater bodies. They are a crucial component of the aquatic food web, serving as a primary producer that converts sunlight into energy through photosynthesis, and are vital for the global carbon cycle.

Synonyms

• Microalgae
• Planktonic algae
• Marine phytoplankton
• Freshwater phytoplankton

Antonyms

• Zooplankton
• Terrestrial plants
• Land flora

Examples

1. Scientists Phytoplankton to measure the health of marine ecosystems.
2. Researchers Phytoplankton to study the effects of climate change on oceanic food chains.
3. The abundance of nutrients can greatly affect how much Phytoplankton grows in a given area.
4. During summer, we often see how the sun encourages Phytoplankton to thrive.
5. Many fish species depend on Phytoplankton for their early life stages.
6. The decline in Phytoplankton populations can lead to significant ecological imbalances.
7. In nutrient-rich waters, Phytoplankton can cause harmful algal blooms.
8. Researchers Phytoplankton to understand its role in carbon sequestration.
9. The health of coral reefs is closely linked to the presence of Phytoplankton.
10. Each spring, scientists Phytoplankton to assess seasonal changes in marine biology.
11. The study of Phytoplankton is essential for predicting fish stock trends.
12. As temperatures rise, how might Phytoplankton adapt to their changing environment?
13. The diversity of Phytoplankton species can indicate the overall health of the water body.
14. In laboratory settings, researchers often Phytoplankton to observe growth patterns.
15. Polluted waters can drastically reduce the amounts of Phytoplankton present.
16. We Phytoplankton to gain insight into past climate conditions.
17. The relationship between Phytoplankton and marine animals is a key focus of marine biology.
18. During oceanographic expeditions, we often Phytoplankton samples for analysis.
19. The presence of certain types of Phytoplankton can indicate water quality.
20. Fish populations often thrive in areas with abundant Phytoplankton.
21. Climate change is affecting the distribution of Phytoplankton across the globe.
22. Phytoplankton plays a significant role in the Earth’s oxygen production.
23. Some researchers Phytoplankton to develop biofuels.
24. The decline in Phytoplankton can have cascading effects on marine ecosystems.
25. We Phytoplankton to help understand nutrient cycling in oceans.
26. The seasonal blooms of Phytoplankton are critical indicators of environmental changes.
27. We often Phytoplankton to monitor ecosystem responses to pollution.
28. Harmful species of Phytoplankton can produce toxins that affect marine life and humans.
29. We need to Phytoplankton to determine the impact of runoff on coastal waters.
30. The study of Phytoplankton diversity is essential for conservation efforts.
31. Ocean currents can influence how Phytoplankton spreads across different regions.
32. Many marine organisms rely heavily on Phytoplankton as their primary food source.
33. We Phytoplankton to investigate its role in the marine carbon cycle.
34. The role of Phytoplankton in sequestering carbon has gained much attention.
35. During the research expedition, we Phytoplankton extensively.
36. Understanding Phytoplankton dynamics is crucial for predicting fishery yields.
37. Phytoplankton populations can fluctuate dramatically with changes in light and nutrient availability.
38. Environmental scientists Phytoplankton as bioindicators of marine health.
39. The rise in ocean temperatures can significantly impact Phytoplankton growth rates.
40. We often Phytoplankton when assessing the impacts of climate variability on marine ecosystems.
41. Some species of Phytoplankton are known for their bioluminescent properties.
42. In laboratory conditions, scientists can manipulate variables to study how Phytoplankton reacts.
43. The presence of Phytoplankton is vital for maintaining balanced aquatic ecosystems.
44. During the summer months, researchers frequently Phytoplankton populations.
45. The decline of Phytoplankton can lead to decreased oxygen levels in the water.
46. We Phytoplankton to understand the impacts of nutrient runoff from agriculture.
47. The interaction between Phytoplankton and grazers is a key area of study in marine biology.
48. Researchers hope to Phytoplankton to find new ways to combat climate change.
49. The historical data on Phytoplankton populations can reveal long-term environmental trends.
50. We Phytoplankton to evaluate the potential for aquaculture development in specific regions.
51. The role of Phytoplankton in nutrient cycling is fundamental to marine ecology.
52. Some communities depend on healthy Phytoplankton populations for their livelihoods.
53. We Phytoplankton to identify environmental stressors in aquatic habitats.
54. The study of Phytoplankton can help predict future changes in ocean ecosystems.
55. Phytoplankton blooms can be both beneficial and harmful depending on the species involved.
56. Monitoring Phytoplankton can provide insights into the effects of climate change on oceans.
57. We often Phytoplankton to develop environmental policy recommendations.
58. The presence of diverse Phytoplankton species is a sign of a healthy ecosystem.
59. Researchers Phytoplankton to explore its potential uses in biotechnology.
60. The influence of light on Phytoplankton productivity is an important research area.
61. We Phytoplankton to help inform conservation strategies for marine environments.
62. The health of Phytoplankton populations is critical for the sustainability of fisheries.
63. We Phytoplankton to investigate the effects of ocean acidification.
64. The decline of Phytoplankton can lead to increased carbon dioxide levels in the atmosphere.
65. Many marine species rely on Phytoplankton for their survival.
66. We Phytoplankton to assess the impacts of human activity on marine ecosystems.
67. Various factors can influence the growth rates of Phytoplankton.
68. The relationship between Phytoplankton and the environment is complex and multifaceted.
69. We Phytoplankton to study their role in oxygen production in the oceans.
70. The competitive dynamics of Phytoplankton species are essential for understanding marine biodiversity.
71. Researchers Phytoplankton to monitor ecosystem health in coastal regions.
72. The seasonal changes in Phytoplankton abundance can affect local fish populations.
73. We Phytoplankton to determine the impacts of invasive species on native marine life.
74. The decline of certain Phytoplankton species can indicate environmental stress.
75. Understanding how Phytoplankton interacts with other marine organisms is vital for ecosystem management.
76. We Phytoplankton to assess the biological responses to environmental changes.
77. The study of Phytoplankton can provide insights into oceanic carbon cycling.
78. Researchers often Phytoplankton to investigate the effects of pollution on marine life.
79. The dynamics of Phytoplankton populations are influenced by a variety of environmental factors.
80. We Phytoplankton to explore its potential as a sustainable food source.
81. The relationship between Phytoplankton and nutrient availability is a key focus in marine research.
82. Understanding how Phytoplankton responds to temperature changes is critical for predicting future ocean conditions.
83. We Phytoplankton to gather data for climate modeling.
84. The study of Phytoplankton is vital for understanding marine ecosystem resilience.
85. Researchers Phytoplankton to evaluate the effectiveness of marine protected areas.
86. The role of Phytoplankton in the marine food web cannot be overstated.
87. We Phytoplankton to help inform strategies for marine conservation.
88. The presence of Phytoplankton can indicate the overall health of the aquatic environment.
89. We Phytoplankton to understand how urban runoff affects coastal ecosystems.
90. The study of Phytoplankton is critical for predicting the impacts of environmental change.
91. Researchers often Phytoplankton to assess the effects of climate variability on marine life.
92. The abundance of Phytoplankton can be influenced by seasonal weather patterns.
93. We Phytoplankton to determine the impacts of tourism on marine environments.
94. The presence of specific Phytoplankton species can indicate water quality issues.
95. Researchers Phytoplankton to explore its potential applications in pharmaceuticals.
96. The study of Phytoplankton is essential for maintaining biodiversity in aquatic ecosystems.
97. We Phytoplankton to monitor changes in nutrient levels in coastal waters.
98. The interaction between Phytoplankton and other marine organisms is a key aspect of marine ecology.
99. Researchers often Phytoplankton to evaluate the impacts of climate change on ocean ecosystems.
100. Understanding the dynamics of Phytoplankton is essential for predicting future marine conditions.