100 Examples of sentences containing the noun "biogeochemistry"

Definition

Biogeochemistry is a scientific discipline that explores the interactions between biological, geological, and chemical processes within ecosystems. It focuses on the cycling of nutrients and elements, such as carbon, nitrogen, and phosphorus, through living organisms and the environment.

Synonyms

• Environmental chemistry
• Ecosystem chemistry
• Geobiochemistry
• Biogeochemical science

Antonyms

• Inorganic chemistry
• Physical chemistry
• Theoretical chemistry

Examples

1. Researchers in biogeochemistry study the cycling of nutrients in forest ecosystems.
2. The impact of climate change on soil composition is a critical area of biogeochemistry research.
3. Marine biogeochemistry examines how oceanic processes affect carbon sequestration.
4. Understanding biogeochemistry is essential for effective environmental management.
5. The field of biogeochemistry integrates knowledge from biology, geology, and chemistry.
6. Biogeochemistry plays a vital role in understanding nutrient dynamics in wetlands.
7. Scientists apply biogeochemistry principles to address pollution issues.
8. The biogeochemistry of coral reefs involves studying the relationships between organisms and their environment.
9. Students interested in ecology often explore biogeochemistry as a field of study.
10. Biogeochemistry helps us understand the effects of fertilizers on soil health.
11. The biogeochemistry of the Arctic is changing rapidly due to melting ice.
12. In urban environments, biogeochemistry affects the distribution of pollutants.
13. Researchers investigate biogeochemistry to improve agricultural practices.
14. The relationship between biogeochemistry and climate change is a significant focus of current research.
15. Biogeochemistry provides insight into the functioning of ecosystems.
16. The study of biogeochemistry includes both terrestrial and aquatic systems.
17. By understanding biogeochemistry, we can better manage natural resources.
18. Biogeochemistry informs our understanding of ecosystem resilience.
19. The biogeochemistry of nutrient cycling is essential for sustainable agriculture.
20. Climate models often incorporate biogeochemistry to predict future environmental changes.
21. Biogeochemistry requires interdisciplinary collaboration between scientists.
22. The effects of deforestation on biogeochemistry are profound.
23. Biogeochemistry addresses the complexities of nutrient availability in soils.
24. The role of microbes in biogeochemistry is crucial for nutrient cycling.
25. Biogeochemistry reveals how human activities impact the environment.
26. The study of biogeochemistry contributes to our understanding of ecosystem services.
27. Biogeochemistry involves analyzing soil samples for nutrient content.
28. The principles of biogeochemistry can be applied to restore degraded ecosystems.
29. Researchers utilize biogeochemistry to track the movement of pollutants.
30. Biogeochemistry plays a key role in understanding climate feedback mechanisms.
31. The biogeochemistry of freshwater systems is essential for maintaining biodiversity.
32. Biogeochemistry examines the interactions between plants and soil composition.
33. The impact of urbanization on biogeochemistry is an ongoing area of study.
34. Biogeochemistry helps in assessing the health of ecosystems.
35. The relationship between biogeochemistry and hydrology is complex and interdependent.
36. Field studies in biogeochemistry can provide valuable data for environmental policy.
37. Biogeochemistry focuses on the chemical processes that occur in living organisms.
38. By analyzing biogeochemistry, scientists can predict ecosystem responses to disturbances.
39. The biogeochemistry of agricultural lands is vital for food security.
40. During climate conferences, discussions about biogeochemistry often arise.
41. Biogeochemistry encompasses both natural and anthropogenic processes.
42. The study of biogeochemistry is crucial for understanding carbon trading.
43. Biogeochemistry links terrestrial and marine ecosystems through nutrient cycles.
44. The biogeochemistry of peatlands is important for carbon storage.
45. Biogeochemistry contributes to the understanding of ocean acidification.
46. The interactions studied in biogeochemistry can inform conservation efforts.
47. Researchers in biogeochemistry collaborate with policymakers to address environmental issues.
48. Biogeochemistry offers insights into the effects of land-use change.
49. The role of phytoplankton in marine biogeochemistry is fundamental to ocean health.
50. Biogeochemistry is essential for understanding the effects of invasive species.
51. The principles of biogeochemistry are applied in ecological restoration projects.
52. Biogeochemistry informs practices in sustainable forestry.
53. The biogeochemistry of wetlands is critical for flood regulation.
54. By studying biogeochemistry, we can better understand nutrient pollution.
55. The effects of climate variability on biogeochemistry are under investigation.
56. Biogeochemistry provides a framework for understanding ecosystem interactions.
57. Researchers use biogeochemistry to assess the impacts of agricultural runoff.
58. The role of nitrogen in biogeochemistry is a key area of research.
59. Biogeochemistry is fundamental to developing effective conservation strategies.
60. The study of biogeochemistry includes analyzing atmospheric gases.
61. Biogeochemistry explores how different ecosystems respond to climate change.
62. The principles of biogeochemistry can guide land management practices.
63. Sustainable practices in agriculture often rely on biogeochemistry.
64. The biogeochemistry of coastal regions is crucial for marine biodiversity.
65. Understanding biogeochemistry can enhance carbon capture strategies.
66. The study of biogeochemistry enables scientists to predict ecosystem responses.
67. Biogeochemistry is intertwined with the study of climate dynamics.
68. The biogeochemistry of deserts presents unique challenges for researchers.
69. Biogeochemistry helps in assessing the health of aquatic ecosystems.
70. The interactions in biogeochemistry are often complex and multifaceted.
71. Researchers combine biogeochemistry with remote sensing technology.
72. The study of biogeochemistry is vital for understanding global nutrient cycles.
73. Biogeochemistry plays a significant role in the carbon cycle.
74. The biogeochemistry of urban areas is influenced by human activity.
75. Biogeochemistry examines the effects of land use on soil health.
76. The principles of biogeochemistry help in mitigating environmental degradation.
77. Researchers focus on biogeochemistry to address climate resilience.
78. The biogeochemistry of grasslands is important for grazing management.
79. Biogeochemistry allows for a deeper understanding of ecosystem processes.
80. The effects of pollutants on biogeochemistry are a major research focus.
81. Understanding biogeochemistry is essential for effective wildlife management.
82. The biogeochemistry of lakes is critical for water quality assessments.
83. Scientists investigate biogeochemistry to better understand nutrient cycling.
84. The relationship between biogeochemistry and human health is increasingly recognized.
85. Biogeochemistry provides tools for evaluating ecosystem services.
86. The principles of biogeochemistry can inform climate adaptation strategies.
87. Researchers study biogeochemistry to understand soil carbon dynamics.
88. The biogeochemistry of agricultural soils is key for sustainable farming.
89. Understanding biogeochemistry is crucial for effective pollution management.
90. The interactions between biogeochemistry and hydrology are critical for ecosystem health.
91. Biogeochemistry helps us understand the balance of nutrients in ecosystems.
92. The biogeochemistry of tropical forests is vital for biodiversity conservation.
93. Researchers analyze biogeochemistry to assess ecosystem resilience.
94. The study of biogeochemistry is relevant for understanding ecosystem sustainability.
95. The principles of biogeochemistry are applied in environmental monitoring.
96. Understanding the biogeochemistry of sediments is important for marine ecology.
97. Biogeochemistry examines how nutrients are cycled in different ecosystems.
98. The role of soil organisms in biogeochemistry is a key focus of research.
99. By studying biogeochemistry, we can develop better conservation practices.
100. The biogeochemistry of alpine ecosystems is affected by climate change.