Oceanography 2011 Final Third of Course

From my notes, these are the general topics that we actually covered since the second exam on March 23.

Refer to the review sheets that I already have posted on the website for an expanded list of information associated with each topic.

Marine sediments

terrigenous sediments

biogenic sediments

other types of sediments (volcanogenic, authigenic, cosmogenic)

In-class exercise to match sediment types with where in the ocean they probably came from

(exercise was handed back)

Core transect across the Pacific Ocean

included a handout with sediment types in the cores

and reconstruction of the conditions

Carbonate Compensation Depth – CCD

chemistry of CO2 dissolved in seawater, and effect on CaCO3 sediments

Photosynthesis and respiration as opposite directions of the same basic chemical equation

added later: how nutrients such as N (as NO3) and P (as PO4) are included in these processes

important to understand the difference between:

inorganic N and P dissolved in seawater

organic N and P removed from seawater to produce organic material (e.g., phytoplankton cells)

How science works, and the contribution of science to society, policy making, and citizenship in a democracy

observation, theory, verification

important: “theory” in science does not mean “conjecture” or “speculation”

Basic chemistry – each student is responsible for reviewing the basics

(summary and presentation available on our website)

Properties of seawater – important topics are incorporated into Exercise 5 (which was handed back)

Deep-ocean circulation

important: distinguish between the shallow ocean (above ~1000 m) and deep ocean (below 1000 m)

What processes or forces move water in the shallow ocean? In the deep ocean?

Density stratification and structure of the world ocean

remember the clines

Map showing deep-ocean circulation

know: NADW and AABW what are they, where do they form

Continuity – absolutely important for any of our discussion of atmospheric and oceanic circulation

can you give a clear, concise explanation of continuity?

Energy balance for the Earth surface

what happens to solar energy as it enters the Earth’s atmosphere?

fundamentals of the atmospheric greenhouse effect

Coriolis effect / Coriolis force

important: water or air moving in the Northern Hemisphere will bend to the RIGHT b/c of Coriolis

(bends to the LEFT in the Southern Hemisphere)

Atmospheric high and low pressure systems

cyclonic – think “cyclone,” as in “tornado”

RISING air, low pressure, spins counter-clockwise in the Northern Hemisphere

anti-cyclonic

SINKING air, high pressure, spins clockwise in the Northern Hemisphere

Orographic effect – air moving up and over a mountain range, then coming down the other side

important: drawn on the board, but the principles apply more broadly than just over mountains

what happens to warm, moist air flowing off the Pacific as it crosses the Sierra Nevada Mountains?

also important: relative humidity, absolute humidity, dewpoint, compression or expansion of air

Atmospheric circulation

most important point: atmos & ocean circulation are redistributing heat across the planet surface

be able to recreate the primary circulation structure of the atmosphere

that is, the Tropical Convergence, Hadley Cells, Ferrel Cells, Trade Winds, Westerlies, Polar Easterlies

Dynamic topography of the ocean surface

“sea level” is not flat

how measured? satellite altimetry (radar to measure the elevation of the water surface)

same dataset can be processed to show:

seafloor features (such as mid-ocean ridges, trenches, seamounts)

ocean currents

wave heights

Surface-ocean circulation

important: direct interaction between atmos circulation and major gyres in the ocean basins

use the North Atlantic Ocean as a model basin

what is the general pattern of circulation, what is driving the water, why an asymmetry

Ekman transport – fundamental process related to moving surface water in the oceans

geostrophic flow – from Exercise 6 (as shown on the board in class)

means “Earth turned”

create a mound of water with Ekman transport

water flows “downhill” but is turned by Coriolis

net result is water flowing “around the mound”

western boundary currents – Gulf Stream and Kuroshio Current are examples

be able to draw a west-east cross section of the water surface across the North Atlantic Ocean

steep slope on west side drives the Gulf Stream

how is the Gulf Stream different than the Canary Current on the east side of the basin?

Two types of upwelling

equatorial divergent upwelling

Trade Winds and Ekman transport move water away from the Equator

continuity replaces surface water by drawing water up from 200-400 m depths

coastal upwelling

two good examples: coast of Peru, coast of California

prevailing winds blow parallel to the coast

cause Ekman transport away from the coast (surface water moves offshore)

continuity replaces surface water by drawing water up from 200-400 m depths

in both cases of upwelling, the upwelling water is cold and rich in nutrients

this supports high productivity of phytoplankton, and lots of zooplankton and fish

Global Climate Change

presented observed, time-series evidence for global climate change over timescales

of decades to millennia (10’s to 1000’s of years)

a PDF of the presentation is available on our course website (Final Third of the Course)