ESCI 1210 - Earth Science

Credit Hours: 4.00

Prerequisites: None

(formerly NATS 1210)

This is a lecture/laboratory course for non-science majors. It is a survey of the earth sciences intended to aid the student in understanding the interrelationships of the universe through the investigation of such topics as matter and energy, astronomy, geology, and meteorology.

Contact Hours: 4

OUTCOMES AND OBJECTIVES
Outcome 1:
Upon completion of this course, students will be able to demonstrate knowledge of the organization of the Universe.

Objectives:

Discuss theories of creation of the Universe.
Identify components and organization of the Universe.
Diagram the arrangement of the Solar system.

Outcome 2:
Upon completion of this course, students will be able to identify the structure of the Earth.

Objectives:

Identify minerals and rocks and discuss their development.
Discuss internal and external forces that impact the Earth’s development.

Outcome 3:
Upon completion of this course, students will be able to describe weather development on Earth.

Objectives:

Discuss composition and structure of the atmosphere.
Describe moisture, clouds, and precipitation
Discuss air pressure and wind.
Describe weather patterns.

COMMON DEGREE OUTCOMES
(Bulleted outcomes apply to the course)

1. The graduate can integrate the knowledge and technological skills necessary to be a successful learner.

2. The graduate can demonstrate how to think competently.

3. The graduate can demonstrate how to employ mathematical knowledge.

4. The graduate can demonstrate how to communicate competently.

The graduate is sensitive to issues relating to a diverse, global society.

COURSE CONTENT OUTLINE

The nature of Earth Science
1. Resources
2. Population
3. Environmental Problems
How Science Works
1. Hypothesis
2. Theory
3. Scientific Methods
Earth Materials
1. Minerals
  1. Elements and types of chemical bonds
  2. Properties of Minerals
  3. Mineral Resources
2. Rocks
  1. Igneous Rocks
    1. Magma vs. Lava
    2. Plutonic structures vs. Volcanic structures
    3. Compositions of igneous rocks
    4. Where igneous rocks form on Earth
  2. Sedimentary Rocks
    1. Clastic vs. chemical sediment
    2. Formation of sedimentary rocks
    3. Where sedimentary rocks form on Earth
  3. Metamorphic Rocks
    1. Foliated vs. Nonfoliated metamorphic rocks
    2. Where metamorphic rocks form on Earth
Internal and External Forces
1. Plate Tectonics
  1. Divergent boundaries
  2. Convergent boundaries
  3. Transform Boundaries
2. Earth’s Interior
  1. Core
  2. Mantle
  3. Crust
3. What drives the motions of the plates?
  1. Convection cells
4. Running Water
  1. Drainage Basins
  2. River Systems
5. Glaciers
  1. How glaciers move
  2. Glacial erosion
  3. Glacial deposits
The Atmosphere
1. Composition
2. Structure
Moisture, Clouds, Precipitation
1. Humidity: Relative vs. absolute
2. Processes that lift air
3. Condensation and cloud formation
4. Types of precipitation
Air Pressure and Wind
1. Isobars
2. The Coriolis effect
3. Cyclones vs. anticyclones
Weather Patterns and Severe Weather
1. Air Masses
2. Fronts
3. The Mid‐Latitude cyclone
4. Thunderstorms
5. Tornadoes
6. Hurricanes
Astronomy
1. The Solar System
  1. Our sun
  2. Planets
  3. Moons
  4. Asteroids, meteoroids, comets
2. Earth‐Moon system
  1. Phases of the Moon
  2. Earth’s Seasons
  3. Eclipses: Lunar and Solar
3. Beyond our Solar System
  1. Properties of stars
    1. Brightness
    2. Distances between stars
  2. Star formation and evolution
  3. Stellar Remnants
    1. White Dwarfs
    2. Neutron Stars
    3. Black Holes
  4. Galaxies
    1. The Milky Way Galaxy
    2. Other types of galaxies
  5. Theories of Formation
    1. The Big Bang
    2. The Steady State model

Primary Faculty
Schafer, Carl
Secondary Faculty

Associate Dean
Young, Randall
Dean
Pritchett, Marie

Official Course Syllabus - Macomb Community College, 14500 E 12 Mile Road, Warren, MI 48088