Marine Biology
Curriculum guideline
Lecture: 4 hours/week
Lab/Field Experience: 3 hours/week
This course involves four hours of lecture and tutorial per week, and three hours of laboratory work. The lecture content is integrated with laboratory experiments, readings in the textbook, and scientific journal articles.
1. Introduction to marine biology
- History of marine biology
- Ocean geography
- Geological divisions of the marine environment
2. Physical and chemical characteristics of the marine environment
- Seawater properties
- Molecular structure of water
- Salinity
- Temperature
- Light
- Density
- Pressure
- Transparency
- Dissolved gases
- Ocean circulation
- Coriolis effect
- Surface currents and Eckman transport
- Waves
- Thermohaline circulation
- Wind patterns
- Tides
3. The diversity of marine life - classification, distribution, characteristics, structure, and function
- Viruses
- Domain Bacteria
- Domain Archaea
- Domain Eukarya
- Protists
- Green algae, red algae, brown algae, diatoms, dinoflagellates, silicoflagellates, haptophytes, cryptophytes, formainiferans, radiolarians, and ciliates
- Kingdom Fungi
- Lichens
- Kingdom Plantae
- Marine flowering plants
- Kingdom Animalia
- Sponges, cnidarians, flat worms, ribbon worms, round worms, arrow worms, peanut worms, segmented worms, molluscs, arthropods, ectoprocts, phoronids, brachiopods, echinoderms, hemichordates, invertebrate chordates, jawless fishes, cartilaginous fishes, bony fishes, reptiles, and mammals
4. Marine ecology
- Ecological principles
- Population growth and regulation
- Community organization
- Symbiotic relationships
- Biological zonation
- Energy flow
- Productivity
- Biogeochemical cycles
- Marine ecosystems
- Intertidal
- Types of intertidal ecosystems, abiotic characteristics, and biotic characteristics
- Estuaries and salt marshes
- Types of estuaries and salt marshes, abiotic characteristics, and biotic characteristics
- Continental shelf
- Types of shelf environments, abiotic characteristics, and biotic characteristics
- Coral reefs
- Types of coral reefs, abiotic characteristics, and biotic characteristics
- Ocean surface
- Types of ocean surface environments, abiotic characteristics, and biotic characteristics
- Ocean depths
- Types of ocean depth environments, abiotic characteristics, and biotic characteristics
5. Humans and the oceans
- Marine resources
- Fish, aquaculture, oil and gas, mining, energy, and minerals
- Human impacts on marine environments
- Climate change (acidifcation and temperature), alteration of habitats, pollution, threatened and endangered species, and marine conservation and protection
Laboratory topics will be drawn from the following:
1. Microscopy
- Usage of compound and dissecting micrscopes
- Kohler illumination
- Oil immersion
2. Scientific method and experimental design
- Measuring tidal height
- Sampling techniques
- Designing an experiment
- Writing and preparing a research proposal
3. Statistics
- Descriptive statistics
- T-test
- ANOVA
- Chi-square analysis
- Regression
- Correlation
- Using SPSS
- Graphing data
4. Physical and chemical analysis of seawater
- Density
- Salinity
- Dissolved oxygen concentration, oxygen solubility, percent saturation
- pH
- Nitrate, phosphate, sulfate, copper, and chlorophyll a concentrations
5. Topics in oceanography
- Seawater stratification
- Seawater mixing
- Pressure
- Buoyancy
- Radiative heat transfer
- Convection
- Thermal expansion
6. Marine viruses and prokaryotes
- Cell morphology
- Gram staining
- Colony morphology
- Species richness
- Coliform abundance
- Cyanophage abundance
7. Seaweeds of British Columbia
- Dinguishing seaweed groups (green, red, and brown) based on thallus colour and morphology
- Microscopic examination of seaweed thallus construction
- Macroscopic and microscopic examination of seaweed life cycle stages
- Use dichotomous keys to identify unknown seaweed specimens
8. Infaunal organisms
- Identification of organisms living in marine sediments
- Identification of organisms living in biofilms
- Assessing species richness relative to grain size in marine sediments
9. Plankton
- Identify the diversity of life obtained from plankton tows (diatoms, dinoflagellates, and zooplankton)
- Correlate plankton diversity and abundance with abiotic and biotic characteristics of seawater
10. Invertebrates
- Identify and characterize invertebrates from a number of different animal phyla
- Use dichotomous keys to identify unknown invertebrate specimens
11. Field Research Project
- Design a research project
- Collect data from the field to test a hypothesis
- Analyze collected data using statistics
- Present data in a graph (where appropriate)
- Present the research project to the class
- Submit the research project as a term paper
Upon completion of this course, the successful student should be able to:
- Describe the history of marine biology as a field of study.
- Summarize the basic divisions of the marine environment.
- Describe the physical and chemical properties of seawater.
- Illustrate and model the causes of water movement and ocean circulation.
- Identify and compare the taxonomy, characteristics, structure, and function of marine life (including viruses, bacteria, archaea, protists, plants, invertebrates, and vertebrates).
- Explain ecological concepts and principles and how they apply to marine ecosystems.
- Categorize marine ecosystems (including intertidal, estuaries, salt marshes, continental shelf, coral reefs, the ocean surface, and the ocean depths) based upon physical and biological characteristics.
- Outline the interactions between humans and the oceans (topics may include marine resources, habitat loss, pollution, and climate change).
- Demonstrate lab/field-related skills such as microscopy, chemical and physical analyses of seawater, statistical analyses of data, and the identification of marine viruses, bacteria, phytoplankton, zooplankton, seaweeds, and invertebrates.
- Design, conduct, interpret, and present a field-based research project.
Evaluation will be carried out in accordance with the Douglas College Evaluation Policy. The instructor will present a written course outline with specific evaluation criteria at the beginning of the semester. Evaluation will be based on the following:
Tests/Assignments: 0-10%
Laboratory Reports and Practical Assessments: 15-25%
Research Project Poster/Presentation and Term Paper: 15-30%
Midterm Theory Examination(s): 20-25%
Final Theory Examination: 30-40%
Note: A student who achieves less than 50% in either the lecture or laboratory portion of the course will earn a maximum P grade.
Consult the Douglas College Bookstore for the latest required textbooks and materials. Example textbooks and materals may include:
P. Castro and M. E. Huber, Marine Biology, current edition