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This course provides students a thorough understanding and appreciation of ecosystems by describing the biota, abiotic components, interactions, and physical drivers of each major ecosystem type.
In order to understand an individual ecosystem, it is imperative to have a firm grasp on general ecologic concepts that explain ecosystem organization and function.
The course will begin with such concepts (e.g., succession, material cycles, and energy webs) and then use a systems ecology framework to describe individual ecosystem types (e.g., estuaries, lakes, rivers,…).
Ecosystem services, major stresses, and management considerations of each ecosystem will be emphasized throughout.
The course will conclude with ecological applications, namely restoration and ecological engineering.
- Introduction
- Ecology of Ecosystems
- Nutrient Cycles and Energy Flows
- Terrestrial Ecosystems
- Aquatic Ecosystems
- Ecological Engineering
This course provides students a thorough understanding and appreciation of ecosystems by describing the biota, abiotic components, interactions, and physical drivers of each major ecosystem type.
In order to understand an individual ecosystem, it is imperative to have a firm grasp on general ecologic concepts that explain ecosystem organization and function.
The course will begin with such concepts (e.g., succession, material cycles, and energy webs) and then use a systems ecology framework to describe individual ecosystem types (e.g., estuaries, lakes, rivers,…).
Ecosystem services, major stresses, and management considerations of each ecosystem will be emphasized throughout.
The course will conclude with ecological applications, namely restoration and ecological engineering.
- Introduction
- Ecology of Ecosystems
- Nutrient Cycles and Energy Flows
- Terrestrial Ecosystems
- Aquatic Ecosystems
- Ecological Engineering
Equipping students with the basic knowledge to analyze and evaluate data
Providing way to convey the information in the fields of science and environmental engineering.
- Sampling Environmental Populations (Tính toán lấy mẫu tổng thể môi trường)
- Environmental Sampling Design (Thiết kế lấy mẫu môi trường)
- Simple Random Sampling (Tính toán lấy mẫu ngẫu nhiên đơn giản)
- Systematic Sampling (Tính toán lấy mẫu có hệ thống)
- Locating Hot Spots (Định vị các điểm nóng ô nhiễm)
- Detecting and Estimating Trends (Phát hiện và ước lượng xu hướng)
Equipping students with the basic knowledge to analyze and evaluate data
Providing way to convey the information in the fields of science and environmental engineering.
- Sampling Environmental Populations (Tính toán lấy mẫu tổng thể môi trường)
- Environmental Sampling Design (Thiết kế lấy mẫu môi trường)
- Simple Random Sampling (Tính toán lấy mẫu ngẫu nhiên đơn giản)
- Systematic Sampling (Tính toán lấy mẫu có hệ thống)
- Locating Hot Spots (Định vị các điểm nóng ô nhiễm)
- Detecting and Estimating Trends (Phát hiện và ước lượng xu hướng)

The basic principles of equilibrium chemistry, particularly as they apply to aquatic systems, have served as indispensable tools for understanding the composition of, and direction of change in environmental systems.
Students are able to explain the chemical phenomena in water and processes in nature, thus offering the optimal methods to solve environmental related issues.
- INTRODUCTION TO WATER CHEMISTRY
- ACIDS AND BASES
- AQUEOUS EQUILIBRIUM
- CHEMISTRY OF METALS IN AQUEOUS SYSTEMS
- REDOX CHEMISTRY
- ADSORPTION AND ABSORPTION REACTIONS
- CHEMISTRY OF NATURAL WATER AND TREATMENT SYSTEMS
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