100 Examples of sentences containing the noun "biogeochemical"

Definition

Biogeochemical refers to the processes that involve the cycling of biological and chemical elements in ecosystems. It encompasses the interactions between the biological (living organisms) and geological (earth) aspects of the environment, particularly focusing on nutrient cycles such as carbon, nitrogen, and phosphorus cycles.

Synonyms

• Nutrient cycling
• Ecosystem chemistry
• Biochemical cycles
• Environmental processes

Antonyms

• Abiotic processes
• Non-ecological processes
• Inorganic reactions

Examples

1. Scientists biogeochemical analyze the impact of pollutants on ecosystems.
2. The study of how nutrients biogeochemical cycle through the food web is crucial for ecology.
3. Researchers biogeochemical investigate the effects of climate change on nutrient availability.
4. The biogeochemical processes in wetlands play a vital role in water purification.
5. Understanding how carbon biogeochemical moves through the atmosphere is essential for climate science.
6. The biogeochemical interaction between soil microbes and plants influences crop yields.
7. Marine biologists biogeochemical assess the health of ocean ecosystems through nutrient cycling.
8. The biogeochemical implications of deforestation are profound for carbon storage.
9. Models that predict how nitrogen biogeochemical flows can help farmers optimize fertilization.
10. The biogeochemical transformations of phosphorus are critical for freshwater ecosystems.
11. Our understanding of how ecosystems biogeochemical function is constantly evolving.
12. The biogeochemical feedback loops in the Arctic are particularly sensitive to warming.
13. Various microbes biogeochemical mediate the breakdown of organic matter in soils.
14. Monitoring how pollutants biogeochemical move through water systems is essential for public health.
15. The biogeochemical cycling of elements is fundamental to sustaining life on Earth.
16. Conservation efforts aim to restore the biogeochemical balance in degraded habitats.
17. The biogeochemical pathways of carbon are crucial in global climate models.
18. Researchers biogeochemical analyze sediment samples to understand historical ecosystem changes.
19. The study of biogeochemical cycles helps us mitigate the effects of human activity on nature.
20. Changes in land use can significantly alter how nutrients biogeochemical cycle through an area.
21. The biogeochemical impact of agriculture on local waterways must be carefully managed.
22. Understanding how carbon biogeochemical sequesters in forests can inform carbon trading policies.
23. The biogeochemical relationships among species help maintain ecosystem stability.
24. The role of fungi in biogeochemical processes is often underestimated.
25. Researchers biogeochemical are now studying the effects of microplastics on nutrient cycles.
26. The biogeochemical properties of soil determine its fertility and productivity.
27. Invasive species can disrupt established biogeochemical cycles in native ecosystems.
28. Understanding how pollutants biogeochemical break down informs environmental regulations.
29. The biogeochemical role of oceans in regulating climate is increasingly recognized.
30. The interactions between plants and soil microbes biogeochemical are critical for nutrient uptake.
31. Scientists biogeochemical explore the implications of land-use changes on nutrient dynamics.
32. Effective waste management can improve the biogeochemical health of urban environments.
33. The biogeochemical processes that occur in peatlands are vital for carbon storage.
34. The complex biogeochemical networks in coral reefs support diverse marine life.
35. Researchers biogeochemical study the impacts of acid rain on forest ecosystems.
36. The biogeochemical cycling of sulfur is essential in understanding acid deposition.
37. Soil health is closely linked to its biogeochemical cycling capabilities.
38. The biogeochemical processes in the ocean are crucial for regulating atmospheric gases.
39. The biogeochemical significance of wetlands extends beyond mere biodiversity.
40. Changes in temperature can alter how nutrients biogeochemical cycle in aquatic systems.
41. The biogeochemical balance of ecosystems is essential for sustaining human life.
42. Researchers biogeochemical are examining the role of bacteria in nutrient cycling.
43. The biogeochemical impact of urbanization can lead to nutrient runoff and eutrophication.
44. Understanding how nutrients biogeochemical are utilized by plants aids in agricultural practices.
45. The restoration of natural habitats can enhance their biogeochemical functions.
46. The biogeochemical cycling of carbon dioxide is a critical component of the greenhouse effect.
47. Innovative technologies can help monitor biogeochemical changes in real time.
48. The biogeochemical interactions in the soil-plant-atmosphere continuum are complex.
49. Researchers biogeochemical are tasked with finding sustainable solutions to nutrient pollution.
50. The biogeochemical implications of permafrost thawing are significant for climate change.
51. Understanding how elements biogeochemical interact can inform conservation strategies.
52. The biogeochemical cycling of trace metals in soil is a critical area of study.
53. The biogeochemical activity in the rhizosphere is key to plant health.
54. Urban gardens can enhance the biogeochemical diversity of city ecosystems.
55. The biogeochemical processes governing soil carbon storage are being actively researched.
56. The biogeochemical feedback mechanisms in ecosystems can amplify climate changes.
57. Researchers biogeochemical have documented shifts in nutrient cycling due to land conversion.
58. The biogeochemical dynamics of nutrient cycling are essential for ecosystem resilience.
59. Understanding biogeochemical cycles helps policymakers make informed environmental decisions.
60. The biogeochemical role of wetlands in flood mitigation is often undervalued.
61. Monitoring how carbon and nitrogen biogeochemical interact is crucial for climate policies.
62. The biogeochemical cycling of nutrients is affected by both natural and anthropogenic factors.
63. The complex biogeochemical relationships in ecosystems form the basis of ecological research.
64. Researchers biogeochemical are focusing on the impacts of synthetic fertilizers on ecosystems.
65. The biogeochemical significance of biodiversity cannot be overstated.
66. Biogeochemical interactions can influence the availability of essential nutrients in ecosystems.
67. The biogeochemical implications of agricultural runoff are a growing concern for water quality.
68. Understanding how nutrients biogeochemical are recycled can help improve soil management.
69. The biogeochemical processes in estuaries are crucial for maintaining marine biodiversity.
70. The biogeochemical transformations that occur during decomposition are vital for nutrient cycling.
71. Researchers biogeochemical have identified key organisms that drive nutrient cycling.
72. The biogeochemical impact of mining activities can lead to significant environmental degradation.
73. The biogeochemical interactions between organisms and their environments shape ecosystems.
74. Monitoring coastal biogeochemical processes can help track the health of marine environments.
75. The biogeochemical cycling of water is essential for sustaining life on Earth.
76. Understanding how ecosystems biogeochemical respond to disturbances is critical for restoration.
77. The biogeochemical properties of soils vary greatly across different ecosystems.
78. Researchers biogeochemical are investigating the role of soils in carbon sequestration.
79. The biogeochemical feedbacks that occur in polar regions are important for global climate models.
80. Understanding how nutrients biogeochemical are utilized by microorganisms is essential for soil health.
81. The biogeochemical role of wetlands in carbon storage is being studied extensively.
82. The biogeochemical cycling of nutrients is influenced by environmental conditions.
83. Aquatic ecosystems rely on biogeochemical processes to maintain their health.
84. Researchers biogeochemical are developing new methods to assess nutrient cycling in ecosystems.
85. The biogeochemical cycling of iron in marine environments is a complex process.
86. The biogeochemical interactions between plants and soil can enhance nutrient availability.
87. Understanding biogeochemical cycles can help us predict the impacts of climate change.
88. The biogeochemical roles of various organisms are critical to ecosystem functioning.
89. Urbanization can disrupt natural biogeochemical cycles, leading to environmental issues.
90. The biogeochemical dynamics of lakes are essential for understanding their ecological health.
91. Researchers biogeochemical are studying the implications of land use on nutrient cycling.
92. The biogeochemical cycling of carbon is a key focus of climate science.
93. The biogeochemical pathways of nutrients are influenced by various environmental factors.
94. Understanding how ecosystems biogeochemical respond to stressors is vital for management.
95. The biogeochemical processes involved in composting help recycle organic materials.
96. The biogeochemical interactions in forests support a diverse range of life forms.
97. Researchers biogeochemical analyze soil samples to understand nutrient availability.
98. The biogeochemical significance of biodiversity is a crucial aspect of conservation biology.
99. The biogeochemical cycling of nutrients is essential for maintaining ecosystem services.
100. Understanding how pollutants biogeochemical break down is important for environmental health.