Geo Oce EXAM 2
Side scan sonar
"fish" instrument towed behind vessel that sends and receives signals; low frequency sound pulses bounce off seafloor to produce picture of seafloor using reflected (returned signals called backscatter
Dropstones
large stones that drop out of icebergs to seafloor
Strata
layer of rock
Lateral continuity
layers deposited in continuous expanses
Original horizontality
layers of sediment deposit first horizontally
Anticlines
limbs dip away from the hinge and the layers fold into a hill - linear fold
Synclines
limbs dip towards the hinge and the layers create a U shape - linear fold
Turbidite
lithified turbidity current sediments that can carve submarine canyons
Deep Sea Trenches
long narrow steep depression in seafloor that is created by subduction - very fine sediment - organisms adapted to high water pressure, cold temp and low food supply
Weak reflector
low density contrast such as water to mud - lighter line
Diatoms
phytoplankton (microalgae) that secrete silica shell (frustule) and are 0.002-0.2mm and are round (centric) to elongated (pennate) structures - make up siliceous ooze
Coccolithophores
phytoplankton (microalgae) with interlocking CaCO3 plates (coccoliths) to form sphere, are less than 0.1mm - make up calcareous ooze
Discoasters
phytoplankton with str-shaped CaCO3 test, are extinct, were 0.005-0.04mm - make up calcareous ooze
Shelf break
point at which angle of seafloor steepens at around 25-550m deep
Inclusions
(a fragment of another rock) a rock including an inclusion must be younger than the inclusion
Things to look for in sediment cores
- Composition shows changes in sediment source or color to see changes in specific minerals, organic matter, and organism remains - Grain size shows nature of deposition such as sand (higher energy) and clay (lower energy) - Layer thickness shows duration of deposition where thicker layers= longer time intervals and thinner layers= brief events like storm deposits
Linear fold symmetry
- Symmetrical; limb angles similar - Asymmetrical: limb angles dissimilar - Isoclinal: tight folds, limbs nearly parallel - Overturned: beds tilted past vertical - Recumbent: beds tilted much past vertical
How do we recognize faults in rocks and in the landscape?
- can create visible shifts in distinct layers of rocks where the layers are no longer continuous on both sides - displacement of natural and human made features - displacement on the fault that offsets ground surface creates a step that is called a fault scarp
Multicore advantages
- collects duplicates at a site at the same depth - provides material for multiple research projects - enables efficient sampling - can be done in deeper waters
Moored Seafloor sediment trap advantages
- data specific to habitat (reef) or source of sediment (river) - used in shallow or deep waters - relatively easy to recover
Sub-bottom seismic profiling uses
- identify and interpret geologic processes, geologic formations, area's geologic history, and biological features like reefs - assess for fossil fuel deposits - identify locations of geohazards like landslides
Gravity core advantages
- provides long record - comparable or longer than vibracores - can be done in deeper waters (100s of m)
Piston core advantages
- provides long record (longer or as long as gravity cores) - can be done in deeper waters (100s m deep) - piston mechanism helps sediment from being disturbed (compressed) in the core barrel
Push core advantages
- requires minimal equipment - provides longer records than multicores (not as long as vibra-, piston-, or gravity cores) - can be done in shallow or deeper waters
Vibracore advantages
- requires minimal equipment but more than a push core - provides relatively long record (longer than multi- and push cores) - can be done in waters up to ~200 ft depth - fairly simple - cost effective to operate
Multibeam Echo Sounder uses
- seafloor mapping habitats and geologic features - coastal management - navigation - locating objects - collecting backscatter from water column
Side scan sonar uses
- seafloor mapping habitats and geologic features - locating human made objects (ships and planes) - assessing for resources - geohazards, and infrastructure
Surface sediment trap advantages
- specific depths - specific areas - general areas - easy to recover from water
Free-drifting naturally buoyant sediment trap advantages
- specific depths - specific currents below surface - could cover broad area - works independent from a ship allowing for more data collection
Passive continental margins
- what: continental to oceanic transition with no active plate boundary - formation: ancient continental rifts that have flooded - tectonically active?: no - found: edges of continents - sediments: terrestrial sediments (sand, silt, clay sized grains) from land with grain sizes that get finer the further from the shore - reliefs: Wide shelf with relatively low relief
Active continental margins
- what: where oceanic and continental plates converge in a subduction zone - formation: subduction zone tectonically active?: yes - found: edges of continents on subduction zone - sediments: mix of terrestrial (sand, silt, clay), volcanic (pyroclastic debris), and deep-sea (silt and clay) - geologic features: Deep sea trenches and volcanic arches and accretionary wedges - reliefs: high relief and steep slopes
Two-way travel time ______. Select all that apply: A. Can be measured with a sub-seismic profiling device B. Is a direct measurement of depth to the seafloor C. Is the measure of time it takes for a signal to leave an echo sounder, hit bottom, and reflect back to the echo sounder D. Can be used to calculate depth to the seafloor
A. Can be measured with a sub-seismic profiling device C. Is the measure of time it takes for a signal to leave an echo sounder, hit bottom, and reflect back to the echo sounder D. Can be used to calculate depth to the seafloor
Turbidity currents: Select one or more: A. Deposit sediments in a way that the coarsest grains on are the bottom and grain size gets finer upwards B. Deposit sediments in a fan shape at the base of the continental slope C. Are relatively weak forces that cannot erode or carry a lot of sediment D. Creates graded beds E. Gain energy and momentum when the continental slope levels off
A. Deposit sediments in a way that the coarsest grains on are the bottom and grain size gets finer upwards B. Deposit sediments in a fan shape at the base of the continental slope D. Creates graded beds
Plastic deformation is more likely to occur than brittle deformation if: Select one or more: A. The rock is more flexible. B. Stress is applied slowly. C. The rock is brittle. D. The rock temperature is very hot. E. The temperature of the rock and the pressure applied to it are low.
A. The rock is more flexible. B. Stress is applied slowly. D. The rock temperature is very hot.
Numerical ages determined from radioactive decay tells us what about rocks? Select one or more: A. When a magma or lava cooled to create an igneous rock. B. When the parent rock of an metamorphic rock formed. C. When a sedimentary rock was lithified. D. The individual ages of sediment grains in sedimentary rocks. E. When a metamorphic rock cooled down and became stable again after metamorphosis.
A. When a magma or lava cooled to create an igneous rock. D. The individual ages of sediment grains in sedimentary rocks. E. When a metamorphic rock cooled down and became stable again after metamorphosis.
Features of deep ocean
Abyssal plains Seamounts Guyots Atolls Deep-sea trenches Abyssal hills
Three types of unconformities
Angular unconformity Non-conformity Disconformity
Types of Linear Folds
Anticlines Synclines Monoclines
Recognize eroded linear folds.
Anticlines- youngest rocks on outside Synclines: youngest rocks on inside
Side scan sonar ________. Select all that apply: A. Uses a high frequency of sound waves B. Provides wide coverage of the seafloor due to the angle of the beams C. Is sometimes referred to as a "whale" D. Emits two beams of sound waves E. Emits beams of sound waves at wide angles to the side of the device
B. Provides wide coverage of the seafloor due to the angle of the beams D. Emits two beams of sound waves E. Emits beams of sound waves at wide angles to the side of the device
What is an example(s) of a strong reflector? Select all that apply: A. Mud B. Rock C. Metal shipwreck
B. Rock C. Metal shipwreck
When we have a high reflectance on the sonar, why do we not collect anything in the ponar grab sampler? A. The seafloor is soft and has muddy (soft) sediment B The seafloor is hard, and there is no muddy (soft) sediment C. The seafloor is soft and has no muddy sediment
B The seafloor is hard, and there is no muddy (soft) sediment
A nonconformity: Select one or more: A. Occurs between sedimentary rocks where the rocks below were tilted before the unconformity developed. B. Is a contact representing a time when no sediment may have been deposited. C. Is a contact representing a time when erosion may have removed rock or sediment. D. Occurs when sedimentary rocks overlie igneous or metamorphic rocks. E. Occurs between parallel, horizontal sedimentary rock layers.
B. Is a contact representing a time when no sediment may have been deposited. C. Is a contact representing a time when erosion may have removed rock or sediment. D. Occurs when sedimentary rocks overlie igneous or metamorphic rocks.
During Monday's lab, what marine research methods did we use? Select all that apply: A. Multibeam bathymetry echo sounder B. Ponar grab samples C. Sonar D. Sub-bottom seismic profiling
B. Ponar grab samples C. Sonar D. Sub-bottom seismic profiling
With an isoclinal anticline fold: Select one or more: A. The oldest layers will be exposed on the outside of the fold when it is eroded. B. The limbs are nearly vertical and parallel. C. The fold is "laying down" - with the limbs horizontal to the Earth's surface. D. The oldest layers will be exposed on the inside of the fold when it is eroded. E. The limbs dip toward the hinge.
B. The limbs are nearly vertical and parallel. D. The oldest layers will be exposed on the inside of the fold when it is eroded.
Classification of biogenous sediments
Based on grain size: Macroscopic Microscopic
The principle of cross-cutting relations states that: A. Younger layers are on top B. Rocks are originally deposited horizontally. C. Features that cut across others must be younger than the features they are going through. D. Older layers on top E. A rock containing an inclusion must be younger than the inclusion.
C. Features that cut across others must be younger than the features they are going through.
Lysocline
CaCO3 dissolution increases
Use of sediment traps and collected data timespan
Collect sediment settling and accumulating on the seafloor over days, months or years - Used for determining how fast sediment accumulates, types of sediment present, types of microorganisms present
Ways folds can be created and define each
Compression- buckling through shortening of the layer Conform to reverse fault- when layers move up and over step shaped faults they must bend into folds Shear- one part of layer moves over another part to produce fold Conform to monocline- faulting at depth may push up a block of crust and cause overlaying beds to bend into a monocline
Regions of passive continental margins
Continental shelf Shelf break Continental slope Continental rise
How to assess mircoorganism species in sediment cores and what can they say about the site?
Count and identify species through a sediment core to determine their ecological preferences to reconstruct environmental conditions over time through the core
Interpretation of side scan sonar
Creates acoustic shadow if object on seafloor obstructs signal from reaching seafloor, can assess object size (human made objects have strong return and are highly reflective)
Using the equation to calculate two-way travel time and the known average speed of sound in water (consult your lecture notes), what is the water depth at a location where it takes 20 seconds for the sound waves to return to the device? A. 100,000m B. 5,000m C. 60,000m D. 15,000m E. None of the above
D. 15,000m
Change in sounding technology over time
Early method- drop weight over boat and measure how much rope was let out in Fathoms Now- more electronic and precise
Layers of flat (horizontal) lines of reflectors below the seafloor suggest: A. Abyssal hills B. A submarine landslide C. Deformed sediments D. Deep-ocean sedimentation E. A submarine canyon
D. Deep-ocean sedimentation
_______________ are conical seafloor features created by volcanism that do not break the sea surface. A. Atoll lagoons B. Guyots C. Abyssal hills D. Seamounts E. Volcanic islands with atolls
D. Seamounts
Two way travel time depth conversion
Distance (depth)= [velocity (sound) x time]/ 2
Types of Circular Folds
Dome Basin
Recognize erodes circular folds
Domes- oldest rock in center Basin- youngest rock in center
Surface grab samples can be used to _________. Select all that apply; A. Study the seafloor in shallow and deep environments B. Study current patterns based on where sediments of certain sizes are found C. Study the distribution of organisms living on the seafloor D. Study the distribution of seafloor sediments E. All of the above
E. All of the above
Sub-bottom seismic profiling _________. Select all that apply: A. Uses a high frequency of sound waves, B. Shows how sound reflects off of the seafloor , C. Shows how sound reflects off of buried sediment layers, D. Detects different layers due to their hardness (density), E. Measures the time it takes for the signal to hit the seafloor and return to the device F. All of the above
F. All of the above
Indirect methods such as sub-bottom seismic profiling are often the first step in a big research project because the methods are relatively cheaper and more invasive than most direct sampling methods. True/ False
False
On a backscatter image, white (bright) features represent soft surfaces like mud that cause the sound waves to bounce back strongly to the echo sounder. True/ False
False
Radioactive isotopes with long half lives are more useful for dating geological materials because they break down quickly into their daughter elements, which means that we can measure the ratio between parent and daughter elements for longer. True/ False
False
Reflectors are boundaries between different layers, where strong reflectors represent low density differences between layers. True/ False
False
The continental shelf will be wider on an active continental margin than it will be on a passive continental margin. True/ False
False
The principle of superposition states that each sediment layer gets progressively older as they go upward. True/ False
False, they get younger as they go upwards
2 main geologic structures
Faults Folds
Describe the distribution of terrigenous grain sizes, roundness, and sorting in the ocean based on the energy of the water transporting the grains.
Grain sizes are bigger and less round close to the shore as the high energy that picks them up is depleted. As you move offshore, the sediment is more fine grained and round from the low energy environment.
Anatomy of a fold
Hinge: line along which fold has greatest curvature Limbs: sides, least curvature Axial plane: imaginary place that runs through all layers of hinge and divides the fold in half
Explain how oxygen isotopes are preserved in foraminifera shells, and how those provide a proxy record for global climate over the geologic past
If there's more oxygen in the atmosphere/ ocean it'll be in the shells showing when the climate was warmer (more oxygen) and cooler (less oxygen)
What do isotopic dates tell us about the three different rock types?
Igneous: when the magma or lava cooled Metamorphic: when the rock cooled from metamorphic temperature Sedimentary: dates or individual grains NOT the time of lithification
How is the geologic time scale constructed?
It is divided into periods based on dominant forms of life as well as major geologic and biologic events - all the types of dating were used
Importance of half-lives in determining what method of dating to use
Long half-lives are better for measuring because they are more reliable than short ones
Two way travel time
Measure of time it takes for signal to return
Why is there interest in hydrogenous sediments?
Mining the minerals
Types of sediment cores
Multicore Push Core Vibracore Gravity core Piston core
Types of faults
Normal Reverse Strike-Slip
Explain how ratios of certain elements can be used to reconstruct ocean temperature over the geologic past. Give an example.
O16 remains on land trapped in ice and snow when the climate is cold. O18 is in higher concentration. O16 melts and returns to the oceans when the climate is warmer. O18 concentration is lower.
5 Principles of Relative dating
Original horizontality Superposition Lateral continuity Cross-cutting relations Inclusion
Characteristics of mid-ocean ridges
Pillow basalt Sheeted dikes Hydrothermal Vents
Three factors that determine the distribution of microscopic biogenous sediments
Production Dissolution Dilution
Why do we correlate vertical series of rock layers?
Provide a record of location's geologic history
Where are hydrogenous sediments found?
Seafloor
Types of biogenous ooze
Siliceous ooze Calcareous ooze
Ways to correlate vertical series of rock layers
Stratigraphic correlation Lithologic correlation Fossil correlation
Paleooceanography
Study of oceans in geologic past with aim to reconstruct physical, chemical, or biological conditions such as ocean circulation, seawater chemistry, sea level/ water depth, patterns of sedimentation, biodiversity/ biogeography
Types of sediment traps
Surface sediment trap Free-Drifting Naturally-Buoyant sediment trap Moored Seafloor sediment trap
Two types of cosmogenic sediemtns
Tektites Microtektites
Five types of sediments on bottom of oceans
Terrigenous Hydrogenous Volcanic Cosmogenic Biogenous
Sediment size in the ocean gets progressively finer the farther out into the ocean you go. This is because the coarsest sediments are deposited when rivers and deltas hit the ocean, lose energy, and drop the largest (heaviest) grains. True/ False
True
Sonar determines the depth to the seafloor or objects in the water by the use of reflected sound waves. True/ False
True
Surface grab samples do not provide the same long-term temporal perspective of sedimentation as do sediment cores. True/ False
True
Why might a rock be more likely to deform plastically versus brittlely?
They are more likely to deform plastically under high temp and pressure, if the rate of stress application is slower, and if the rock is a more flexible type.
Why is it useful to know how the global climate and ocean characteristics (temperature, salinity, sea level) have changed over geologic time (over millions of years)?
To predict future patterns an asses human impacts on pre-existing patterns
A multiple refers to a very strong reflector that gets repeated in the subsurface in a sub-bottom seismic profile. It is an artifact of the strength of the reflector, not evidence for multiple strong reflectors below the seafloor. True/ False
True
Abyssal plains are composed of sediment layers that can be very thick (greater than 100's of meters thick) and that overlie oceanic crust made of basalt. True/ False
True
Backscatter refers to waves that reflect of of the seafloor, are received by the echo sounder, and produce a grayscale image of the seafloor. Select all that apply: True/ False
True
Both sheeted dikes and hydrothermal vents are created by the formation of fissures (cracks) in oceanic crust as the crust accommodates the tension of the oceanic plate pulling apart. True/ False
True
By correlating rock types, fossils, and their vertical succession we can determine the relative ages of rock layers (strata) and formations (groups of similar strata). True/ False
True
Normal faults form from a force called tension that causes a the thinning and extension of the crust, while reverse faults form when compression squeezes and shortens the crust. True/ False
True
Ponar sediment grab samples collect the upper ~20 cm of the seafloor, which may include living and dead organisms, sediments, plants, and human debris. True/ False
True
Uses and advantages of surface samplers
Uses: - studying surface sediment and composition - sediment distribution to indicate currents - living/ dead organism diversity - plants and invertebrate animals Advantages: - helpful in murky/ deep waters - come in various sizes so ship size can vary
Relative Dating
Using methods to determine the time of which one geologic event happened with respect to others
How are hydrogenous sediments created at hydrothermal vents?
Water heats up in cracks dissolving minerals in crust- water comes up to seafloor surface and cools, minerals precipitate due to changes in temp
Seamounts
abyssal mountains that DON'T reach sea surface - extinct volcanoes so sediments reflect that - house marine life on the slopes due to proximity to sunlight
Guyots
abyssal mountains with flat tops - extinct volcanoes that reached sea surface and got eroded by waves and then subsided below sea level - sediment is fine and volcanic - high diversity of life due to currents, nutrients, and habitat structure
Tephra
ash distributed by wind
Strong reflector
big density contrast such as water to rock - darker line
Low backscatter
black, weak return, reflection off softer sediments like sand and mud
Reflectors
boundaries between different layers
Contact
boundary between 2 formations
Elastic deformation
changes in shape that can be reverse by removing stress
Use of sediment cores and collected data timespan
collect 10s of cm to several meters of seafloor sediments from hundreds to millions of years
Use of surface samplers and collected data timespan
collect upper 20-50cm of sediment on seafloor (years to 1000s of years)
Biogenous sediments
composed of dead marine organisms parts
Calcareous ooze
composed of organisms that have skeletons made of calcium carbonate (coccolithophores, discoasters, foraminifera)
Siliceous ooze
composed of organisms that have skeletons made of silica (diatoms and radiolarians)
Microscopic biogenous sediments
composed of very small whole or fragmented organisms (less than 1mm) - ex. unicellular algae or protozoans - more common - create oozes
Three major marine provinces
continental margins, deep-ocean basins, mid-ocean ridge
Lithologic correlation
correlating strata by physical characteristics of rock type
Tektites
created when terrestrial sediments are melted and ejected from meteorite impact sites (gravel-sized, glassy bodies, black, green, brown, gray)
Turbidity currents
dense, rapid downslope flow of water and sediment triggered by earthquakes and unstable slopes - lose energy when slope starts t level off
Volcanic sediment distribution
deposition high near volcanoes but slows as you move away from source - grain size decreases with increasing distance from volcano
Carbonate Compensation Depth (CCD)
depth where CaCO3 dissolves completely
Numerical dating
determining the age of rocks in years before present
Echo sounder
device for determining depth to seafloor or objects in the water by emitting a sound wave signal into water and measures time it takes for wave to return
Isotopes
different versions of an element with different atomic masses (different number of neutrons)
Pumice
distributed through oceans by floating in the water
Terrigenous water transport
distribution onshore-offshore is a function of water energy as distance from shore increases - water energy decreases with grain size - fluvial sediment input - occurs around edges of continent
Abyssal hills
domed or elongated hills formed by faulting and volcanism - rise up around 1000m above sea floor but are not as tall as seamounts - sediment is volcanic
How is numerical dating done?
done through radiometric dating of isotopes half-lives to see the amount of decay
Superposition
each layer of sediment must be younger than the one below it
James Hutton
father of geology and the one who founded the idea of uniformitarianism
Hydrothermal vents
fissures in crust associated with MORs where water get superheated and infused with elements, minerals precipitate as water cools - mineral build up creates habitat structure: unique diversity of organisms that vary spatially with resources
Deep Ocean
flat expanse of sea floor, depth of over 3000m, between continental margins and MOR
Dome
fold in shape of overturned bowl - circular fold
Basin
fold in shape of upright bowl - circular fold
Plunging folds
fold with horizontal hinge
Non-plunging folds
fold with tilted hinge
Fault
form through brittle deformation
Fold
form through elastic/ plastic deformation
Cosmogenic sediments
formed or created by extraterrestrial sources with very low accumulation rates
Free-drifting naturally buoyant sediment trap
free-floating drifts down to certain depth and collects data with a current
Surface sediment trap
free-floating or tethered to a ship collects data a specific depth, moves with surface current or ship
Uncomformities
gaps in the rock record, it is a contact representing a period of non-deposition and possibly erosion
Terrigenous ice transport
glaciers carry poorly sorted sediment and the material drops out as ice metals - ice raft debris - dropstones
Formations
groups of strata with a specific rock type that represent a distinct interval of sediment deposition
Normal Fault
hanging wall goes down relative to footwall - divergent zones - tension force
Reverse Fault
hanging wall goes up relative to footwall - convergent zone - compression force
Sub-bottom seismic profiling
high frequency profiling that penetrates below seafloor reflecting off seafloor and buried sediment layer - detects different layers due to differences in hardness (density) of materials - uses strength of reflectors to produce images
Half-life
how long it takes for half a group of atoms to decay (measure ratio of parent to daughter in mineral to calculate age)
Crusts
hydrogenous sediment that occurs at a hydrothermal vent and is in deep ocean basins precipitating minerals form layered crust on seafloor - form where sedimentation is very low because otherwise nodules would be buried and stop forming
Hydrogenous nodules
hydrogenous sediment that occurs at a hydrothermal vent and is rounded lumps of manganese and other metals like iron, copper, cobalt, and nickel that form around central object like a shell of rock; concentric layers slowly deposit over it and form over millions of years
Cross-cutting relations
if 1 geologic feature cuts across another then the one that has been cut is older
Sheeted dikes
igneous intrusions travel upwards through fractures in ocean crust, melt cools below seafloor creating nearly parallel, nearly vertical series of intrusions (sheet-like)
Continental Rise
incline where the continental slope meets the crust and represents the transition between continental slope and deep-ocean - sediment is a continuation of deposition from turbidity currents creating graded bed containing sand silt and clay - deep-sea environment with no sunlight and low productivity
Biogenous ooze
made of microscopic biogenous sediments and clay - classified by composition - formed by accumulation by currents and sinking to seafloor
Macroscopic Biogenous Sediments
made of whole and fragmented marine organisms (greater than 1mm) - less common than microscopic because high concentrations of macroscopic organisms are less common - ex. CaCO3 producing organisms that have a shell (corals, shells, sea stars, urchins, shark teeth) - abundant in shallow marine settings due to abundance of CaCO3 producing organisms
Radioactive decay
measuring an atom's half-life
Radiometric dating
measuring ratios of radioactive elements and decay products to calculate a number age
Microtektites
microscopic tektites (mm), glassy, yellow-brown
Production
more biogenous sediment below areas of high primary productivity than areas of low PP
Multibeam Echo Sounder
multiple simultaneous sound waves (beams) deployed in fan-shape to produce data through backscatter to show depth plotted as bathymetry 2D or 3D map - red= shallow - blue/ purple= deep
Indirect Research Methods
no physical samples collected - data is just recorded and analyzed - noninvasive - fast - cost-effective
Push core
one core at a time (10s cm long) taken manually or with ROV
Piston core
one core at a time (10s m) by piston core barrel helping transfer force of fall into pushing core barrel farther into the sediment, long heavy and awkward and requires specialized ship
Gravity core
one core at a time (m to 0sm long) by large weight on core barrel pushing it into sediment by force of gravity (not motor) dropped from side of ship but heavy and awkward to deploy, requires a boat with a winch
Vibracore
one core at a time (m to 10s of m) by motor attached to core barrel and vibrations from the motor drive the core barrel into the sediment (taken manually or by boat with rig)
Continental margin
outer edge of continental crust and adjacent to oceanic crust under the sea level (shelf break, break, slope, rise) - active or passive
Volcanic sediments
particles ejected from volcanoes (ash and lapilli)
Uniformitarianism
physical processes operating in modern world also operated in the past at roughly the same rates
Direct Research Methods
physical samples collected - usually occurs after indirect methods - invasive - more time required - more costly
Proxies and an example
physical/ chemical parameter that can be measured and calibrated to interpret past conditions - ex. Shells/ skeletons of marine organisms accumulate in seafloor sediments as they die leaving only the hard parts and they're collected through sediment cores
Sounding
process of measuring depth of ocean
Isotopic decay
process that changes atomic number, so changing an atom of one element to another
Hydrogenous sediments
produced by chemical reactions and mineral precipitation through changes in water temp, pressure, or pH
Uses of sediment cores
provide long-term record over time - geologic sediment type changes - environmental effects like water energy and marine setting changes - biologic such as habitat or biodiversity changes - climate such as seawater temp or global ice volume changes
Authigenic sediments
refers to sediments that form in the place they're found on seafloor - hydrogenous sediments is a type because they are not created and transported somewhere else
Backscatter
reflected (return) signals that create picture of seafloor
Stratigraphic correlation
relating strata at different locations
Dilution
relative proportions of different sediment types with different distances from land - coastal areas have more terrigenous sediment that dilutes biogenic matter - terrigenous are less abundant offshore so biogenic sediments will be more abundant
Disconformity
rocks below unconformity were NOT tilted or folded before erosion (formation: deposition🡪erosion🡪deposition)
Angular unconformity
rocks below unconformity were tilted/folded before the unconformity developed (formation: deposition🡪deformation🡪erosion🡪renewed deposition)
Mid-Ocean Ridges
seafloor spreading centered with rift valley and continuous volcanic ridge - found in the mid-Atlantic - volcanic rocks (basalt) with very fine sediment over it
Ice raft Debris
sediment transported to ocean by icebergs and falls to seafloor as ice melts
Non-conformity
sedimentary rocks overlay older igneous or metamorphic rocks that were eroded. (Formation: igneous rocks form🡪igneous rock erodes🡪sedimentary rocks deposit)
Accretionary wedge
sediments scraped onto non-subducting plate from surface of subducting plate in a wedge shape
Continental Shelf
shallow, flooded edge of continent - terrestrial sediment from rivers and deltas with coarse grains in the high energy environment and the fine grains in low energy - have diversity because of the nutrients and sunlight that supports plant life - habitat changes as sunlight changes with depth - coral reefs present
Hjulstrom Curve
shows relationship between particle size and energy needed to erode, transport, and deposit sediment
Monocline
single linear fold that looks like a stair step and usually forms on a fault scarp - deforms when fault slips
Continental slope
slope between shelf break and deep ocean floor - sediments are shelf sediments transported downhill by turbidity currents (sand silt and clay) - sediment deposits in a fan shape at the base of the slope and settles out by size which creates a graded bed - submarine canyons may be here - less productive environment because of low sunlight and the slope is unstable, but the diversity is high even when abundance is low - canyon walls provide habitat
Moored Seafloor sediment trap
stationary on seafloor near area of interest
Structural geology
study of form arrangement and internal structure of rocks and how rocks deform in response to stress
Topography
study of forms and features on land surfaces
Pillow basalt
surface of extruding lava cools quickly, while hot subsurface continues to flow (round ~1m diameter)
Multicore
takes multiple short cores at once, deployed from ship
Bathymetry
topography of the ocean floor
Terrigenous sediments
transported to ocean from land by rivers, ice, wind; produced by weathering and erosion of rocks on land; typically sands, silts, and muds
Terrigenous wind transport
transports very fine sediments like dust (clay, minerals, quartz, feldspars, pyroxene or terrestrial biological grains (diatoms, spores, pollen) - well-sorted sediment - can travel very long distances - higher levels of wind transported sediments in ocean near deserts depending on wind patterns
Strike-Slip Fault
two plates slide by each other - transform - shear stress
Fossil correlation
using fossils to define relative ages of strata that what contain them
Abyssal Plains
very flat region, years of sedimentation - found throughout ocean seafloor - sediments are very fine silt and clay - marine life organisms are spread out with no sunlight and dependent on limited food sources
Atolls
volcanoes that have sunk and coral reefs form around it and volcano is fully submerged into lagoons - volcanic sediments - high diversity of life due to surface and coral reef
Dissolution
water depth - silica dissolves in warm surface waters and accumulates in cold deep waters - carbonate dissolves in cold acidic waters and accumulates in warm surface waters
Plastic deformation
when enough stress is applied to a rock that it permanently changes its shape without breaking it (creates folds)
Brittle deformation
when rocks break rather than bend (creates faults)
Graded beds
when sediments go from course to find going upwards
High backscatter
white, strong return, reflection off hard surfaces such as rock
Radiolarians
zooplankton (protozoa) that secret silica shell (test), 0.1-0.2mm, and have elaborate globular shells with holes - make up siliceous ooze
Foraminifera
zooplankton with chambered CaCO3 shell (test), are less than 1mm - make up calcareous ooze