Earth systems science covering plate tectonics, landforms, erosion, biomes, hydrosphere, atmospheric circulation, and the interactions among lithosphere, hydrosphere, atmosphere, and biosphere. Provides frameworks for analyzing how physical processes shape landscapes over geological and human timescales. Use when reasoning about landforms, natural hazards, climate patterns, ocean currents, biogeography, or any question about how Earth's physical systems operate and interact.
Physical geography is the study of natural features and processes on and near Earth's surface -- the lithosphere, hydrosphere, atmosphere, cryosphere, and biosphere, and the energy and material flows that connect them. It asks why landscapes look the way they do and how they change over time.
Agent affinity: reclus (Earth sciences, physical systems), humboldt (integrated physical-human perspective)
Concept IDs: geo-plate-tectonics, geo-landforms-erosion, geo-biomes, geo-hydrosphere, geo-weather-systems, geo-atmospheric-circulation, geo-climate-zones
Earth's lithosphere is divided into approximately 15 major tectonic plates that move relative to one another at rates of 1--15 cm per year. Alfred Wegener proposed continental drift in 1912; the mechanism (mantle convection driving seafloor spreading) was confirmed in the 1960s through magnetic striping, deep-sea drilling, and earthquake seismology.
Plate boundary types:
| Boundary | Motion |
|---|
| Features |
|---|
| Example |
|---|
| Divergent | Plates move apart | Mid-ocean ridges, rift valleys, new oceanic crust | Mid-Atlantic Ridge, East African Rift |
| Convergent (oceanic-continental) | Oceanic plate subducts | Volcanic arcs, deep trenches, Andean-type mountains | Cascadia Subduction Zone, Andes |
| Convergent (continental-continental) | Neither subducts easily | Fold mountains, crustal thickening, no volcanism | Himalayas (India-Eurasia) |
| Convergent (oceanic-oceanic) | One plate subducts | Island arcs, deep trenches | Mariana Trench, Japanese Islands |
| Transform | Plates slide laterally | Earthquakes, offset features, no volcanism | San Andreas Fault, Alpine Fault (NZ) |
The Wilson Cycle. Continents rift, oceans open, oceanic crust subducts, oceans close, continents collide, and the cycle restarts over ~200--500 million years. The current configuration of continents is a snapshot in a continuous process.
Landforms result from the competition between tectonic uplift (constructive) and erosion (destructive). The balance between these forces determines whether a landscape is rising, in steady state, or being worn down.
Weathering breaks rock into smaller pieces or dissolves it in place:
Erosion transports weathered material via water, wind, ice, or gravity:
Davis vs. Hack. William Morris Davis (1899) proposed a "cycle of erosion" where landscapes progress from youth to maturity to old age. John Hack (1960) countered with "dynamic equilibrium" -- landscapes adjust continuously to tectonic and climatic inputs rather than progressing through a fixed sequence. Modern geomorphology integrates both perspectives.
The hydrosphere includes all water on, in, and above Earth. The water cycle -- evaporation, condensation, precipitation, infiltration, runoff -- is the master cycle connecting atmosphere, surface, and subsurface.
Key reservoirs:
Surface currents are driven by wind and deflected by the Coriolis effect. Five major gyres (North Atlantic, South Atlantic, North Pacific, South Pacific, Indian Ocean) distribute heat poleward on western boundary currents (Gulf Stream, Kuroshio) and return cool water equatorward on eastern boundary currents (California, Canary).
Thermohaline circulation (the "global conveyor belt") is driven by density differences from temperature and salinity. Cold, salty water sinks in the North Atlantic (North Atlantic Deep Water formation) and flows southward at depth, eventually upwelling in the Southern Ocean and Indian/Pacific basins. Full circuit: ~1,000 years.
El Nino-Southern Oscillation (ENSO). A coupled ocean-atmosphere oscillation in the tropical Pacific. El Nino (warm phase) weakens trade winds, warms the eastern Pacific, and shifts precipitation patterns globally. La Nina (cool phase) strengthens trade winds and cools the eastern Pacific. ENSO is the dominant mode of interannual climate variability.
The atmosphere is layered: troposphere (0--12 km, where weather occurs), stratosphere (12--50 km, ozone layer), mesosphere (50--80 km), thermosphere (80--700 km). Temperature profiles define the boundaries.
Global circulation cells:
Jet streams flow west-to-east at the boundaries between cells (~10 km altitude). The polar jet stream marks the polar front and drives mid-latitude weather systems.
The Koppen climate classification (1884, revised by Geiger) uses temperature and precipitation thresholds to define five major groups:
| Group | Name | Key feature | Example regions |
|---|---|---|---|
| A | Tropical | All months >18C, high rainfall | Amazon basin, Congo basin, Southeast Asia |
| B | Arid | Evaporation exceeds precipitation | Sahara, central Australia, Atacama |
| C | Temperate | Coldest month -3C to 18C | Pacific Northwest, Mediterranean, southeastern China |
| D | Continental | Coldest month <-3C, warmest >10C | Siberia, upper Midwest, Scandinavia |
| E | Polar | Warmest month <10C | Antarctica, Arctic tundra, high mountains |
Each group subdivides by precipitation seasonality (f=year-round, s=dry summer, w=dry winter, m=monsoon) and temperature (a/b/c/d for the warm-season gradient).
A biome is a large-scale ecological community classified by its dominant vegetation, which is controlled primarily by climate (temperature and precipitation).
Terrestrial biomes (simplified):
Biogeography studies the distribution of species in space and through time. Key principles:
Physical geography's power lies in understanding interactions, not isolated systems.
Examples of cross-system interaction:
Humboldt's insight. Alexander von Humboldt recognized in the early 19th century that nature is an interconnected web -- temperature, altitude, latitude, vegetation, and human activity form a single system. His "Naturgemalde" (1807) cross-section of Chimborazo showed how climate, vegetation, and agriculture change with elevation, the first integrated physical geography diagram.