Relative & Absolute Dating PDF

Summary

This document provides an overview of relative and absolute dating techniques in geology. It explains the principles of relative dating, such as superposition and original horizontality, and discusses absolute dating methods, focusing on radioisotopic dating, including radioactive decay, half-life, and assumptions.

Full Transcript

Relative Dating

Process of determining if one
rock or geologic event is older
or younger than another,
without knowing their specific
ages—i.e., how many years
ago the object was formed
Relative Dating Principle

Principle of Superposition

In an otherwise undisturbed
sequence of sedimentary
strata, or rock layers, the
layers on the bottom are the
oldest and layers above them
are younger.
Relative Dating Principle

Principle of Original
Horizontality

Layers of rocks deposited from
above, such as sediments and
lava flows, are originally laid
down horizontally. The
exception to this principle is at https://cdn.britannica.com/23/151223-050-CDE6FC90/Steno-laws-stratigraphy.jpg

the margins of basins, where
the strata can slope slightly
downward into the basin.
Relative Dating Principle

Principle of Lateral Continuity
Within the depositional basin,
strata are continuous in all
directions until they thin out at the
edge of that basin. Of course, all
strata eventually end, either by
hitting a geographic barrier, such as
a ridge, or when the depositional
process extends too far from its
source, either a sediment source or
a volcano. Strata that are cut by a
canyon later remain continuous on
either side of the canyon.
https://cdn.britannica.com/23/151223-050-CDE6FC90/Steno-laws-stratigraphy.jpg
Relative Dating Principle

Principle of Cross-Cutting
Relationships

Deformation events like
folds, faults and igneous
intrusions that cut across
rocks are younger than the
rocks they cut across.
Relative Dating Principle

Principle of Inclusions

When one rock formation
contains pieces or inclusions
of another rock, the included
rock is older than the host
rock.

https://i.ytimg.com/vi/pBQ-l6X6MMk/maxresdefault.jpg
Relative Dating Principle

https://cdn.britannica.com/23/151223-050-CDE6FC90/Steno-laws-stratigraphy.jpg
Unconformities

A break in time in an
otherwise continuous rock
record. Unconformities are a
type of geologic contact—a
boundary between rocks—
caused by a period of erosion
or a pause in sediment https://geologyscience.com/wp-content/uploads/2018/06/main-qimg-a3bc6b80cbcbe824095e6a1532b5bb47-

accumulation, followed by c.jpg

the deposition of sediments
anew
Unconformities

Disconformity

Where is a break or
stratigraphic absence
between strata in an
otherwise parallel sequence
of strata.
Unconformities

Angular Unconformity

Where sedimentary strata
are deposited on a terrain
developed on sedimentary
strata that have been
deformed by tilting, folding,
and/or faulting so that they
are no longer horizontal.
Relative Dating Principle
Absolute Dating

Radioisotopic Dating

Discovery of radioactivity in
the late 1800s provided
scientists with a new
scientific tool

Assign specific time units, in
this case years, to mineral
grains within a rock
https://pixfeeds.com/images/32/608610/1200-608610-relative-vs-absolute-dating.jpg
Radioactive Decay

Isotope

An atom of an element with
a different number of
neutrons
Radioactive Decay

Radioactive Isotopes
Unstable isotopes
1H and 2H are stable, but 3H
is unstable

Radioactive Decay
Spontaneously decay over
time releasing subatomic
particles or energy in a
process
Radioactive Decay

Half-life
Time it takes for half of the
atoms in a substance to
decay

The half-life of an isotope is
the amount of time it takes
for half of a group of
unstable isotopes to decay to
a stable isotope
Radioactive Decay

Half-life
The half-life is constant and
measurable for a given
radioactive isotope, so it can
be used to calculate the age
of a rock

The half-life uranium-238
(238U) is 4.5 billion years and
the half-life of 14C is 5,730
years.
Radioactive Decay

Assumptions
The mineral grains containing the
isotope formed at the same time as
the rock, such as minerals in an
igneous rock that crystallized from
magma.

The mineral crystals remain a closed
system, meaning they are not
subsequently altered by elements
moving in or out of them.
Radioactive Decay

These requirements place some
constraints on the kinds of rock
suitable for dating, with igneous rock
being the best.

Metamorphic rocks are crystalline,
but the processes of metamorphism
may reset the clock and derived ages
may represent a smear of different
metamorphic events rather than the
age of original crystallization.
Radioactive Decay

Alpha Decay

When an alpha particle, which
consists of two protons and two
neutrons, is emitted from the
nucleus of an atom

238U – 234Th
Loss of four particles
Radioactive Decay

Alpha Decay

238U – 234Th
The radioactive decay product of an
element is called its daughter
isotope, and the original element is
called the parent isotope

The half-life of 238U is 4.5 billion
years, i.e., the time it takes for half of
the parent isotope atoms to decay
into the daughter isotope.
Radioactive Decay

Beta Decay

When a neutron in its nucleus
splits into an electron and a
proton. The electron is emitted
from the nucleus as a beta ray.
The new proton increases the
element’s atomic number by
one, forming a new element
with the same atomic mass as
the parent isotope.
Radioactive Decay

Beta Decay

Decay chain
The decay process of radioactive
elements like uranium keeps
producing radioactive parents
and daughters until a stable, or
non-radioactive, daughter is
formed.
Radioactive Decay

Electron Capture

When a proton in the nucleus
captures an electron from one of
the electron shells and becomes
a neutron.
Radioactive Decay

Electron Capture

1) an electron jumps in to fill
the missing spot of the
departed electron and emits
an X-ray
2) in what is called the Auger
process, another electron is
released and changes the
atom into an ion
Radioactive Decay
Radioactive Decay

The parent and daughter
isotopes are separated out of
the mineral using chemical
extraction. In the case of
uranium, 238U and 235U isotopes
are separated out together, as
are the 206Pb and 207Pb with an
instrument called a mass
spectrometer.
Radioactive Decay

Age calculation using the
daughter-to-parent ratio of
isotopes.
Age of the Earth

Clair Patterson – 1950s

Determine the age of the
Earth using radioactive
isotopes from meteorites,
which he considered to be
early solar system remnants
that were present at the
time Earth was forming.
Other Dating Techniques

Luminescence/Thermolumi-
nescence

Measures the time elapsed
since some silicate minerals,
such as coarse-sediments of
silicate minerals, were last
exposed to light or heat at the
surface of Earth
Other Dating Techniques

Fission Track

Relies on damage to the crystal
lattice produced when
unstable 238U decays to the
daughter product 234Th and
releases an alpha particle.
These two decay products
move in opposite directions
from each other through the
crystal lattice leaving a visible
track of damage.
Fossils and Evolution

Fossils
Evidence of past life preserved in
rocks

Actual remains of body parts
(rare), impressions of soft body
parts, casts and molds of body
parts (more common), body parts
replaced by mineral (common) or
evidence of animal behavior such
as footprints and burrows
Types of Preservation

Actual preservation

Rare form of fossilization where
the original materials or hard
parts of the organism are
preserved.

Preservation of soft-tissue is very
rare since these organic materials
easily disappear because of
bacterial decay.
Types of Preservation

Permineralization

Occurs when an organism is
buried, and then elements in
groundwater completely
impregnate all spaces within the
body, even cells. Soft body
structures can be preserved in
great detail, but stronger
materials like bone and teeth are
the most likely to be preserved
Types of Preservation

Molds and casts

Form when the original material
of the organism dissolves and
leaves a cavity in the surrounding
rock
Mold -The shape of this cavity is
an external
Cast - If the mold is subsequently
filled with sediments or a mineral
precipitate, the organism’s
external shape is preserved
Types of Preservation

Carbonization

Occurs when the organic tissues
of an organism are compressed,
the volatiles are driven out, and
everything but the carbon
disappears leaving a carbon
silhouette of the original
organism
Types of Preservation

Trace Fossil

Indirect evidence left behind by
an organism, such as burrows and
footprints, as it lived its life

Ichnology is specifically the study
of prehistoric animal tracks
Stress in Earth’s Crust

Stress

Force applied to an object

In geology, stress is the force per
unit area that is placed on a rock
Stress in Earth’s Crust

Stress Types

Confining stress
A deeply buried rock is
pushed down by the weight
of all the material above it.
Since the rock cannot move,
it cannot deform https://static.hindawi.com/articles/mpe/volume-2019/5432470/figures/5432470.fig.003.jpg
Stress in Earth’s Crust

Stress Types

Compression
Squeezes rocks together,
causing rocks to fold or https://scontent.fmnl10-1.fna.fbcdn.net/v/t1.6435-9/182680321_966783470793156_477237650343521750_n.jpg?_nc_cat=109&ccb=1-7&_nc_sid=8bfeb9&_nc_ohc=zfk9nwdLfGIAX-r7-jS&_nc_ht=scontent.fmnl10-1.fna&oh=00_AfDoixNfdcOZDak8YSE5c-
6GXQ_g_SoWYtfbm_Pbe1qQSA&oe=651F78CE

fracture (break)

Most common stress at
convergent plate
https://images.slideplayer.com/23/6584055/slides/slide_14.jpg
boundaries
Stress in Earth’s Crust

Stress Types

Tension
Rocks under tension
lengthen or break apart https://scontent.fmnl10-1.fna.fbcdn.net/v/t1.6435-9/182680321_966783470793156_477237650343521750_n.jpg?_nc_cat=109&ccb=1-7&_nc_sid=8bfeb9&_nc_ohc=zfk9nwdLfGIAX-r7-jS&_nc_ht=scontent.fmnl10-1.fna&oh=00_AfDoixNfdcOZDak8YSE5c-
6GXQ_g_SoWYtfbm_Pbe1qQSA&oe=651F78CE

Tension is the major type of
stress at divergent plate
boundaries.
https://images.slideplayer.com/23/6584055/slides/slide_14.jpg
Stress in Earth’s Crust

Stress Types

Shear
When forces are parallel but
moving in opposite https://scontent.fmnl10-1.fna.fbcdn.net/v/t1.6435-9/182680321_966783470793156_477237650343521750_n.jpg?_nc_cat=109&ccb=1-7&_nc_sid=8bfeb9&_nc_ohc=zfk9nwdLfGIAX-r7-jS&_nc_ht=scontent.fmnl10-1.fna&oh=00_AfDoixNfdcOZDak8YSE5c-
6GXQ_g_SoWYtfbm_Pbe1qQSA&oe=651F78CE

directions

Most common stress at
transform plate boundaries
https://images.slideplayer.com/23/6584055/slides/slide_14.jpg
Stress in Earth’s Crust

Strain/Deformation

When stress causes a
material to change shape, it
has undergone strain or
deformation

Deformed rocks are
common in geologically https://enigmaticscience.files.wordpress.com/2018/07/slide_3.jpg?w=900

active areas.
Stress in Earth’s Crust

A rock’s response to
stress depends on the
rock type, the
surrounding
temperature, and
pressure conditions the
rock is under, the length
of time the rock is under
stress, and the type of https://enigmaticscience.files.wordpress.com/2018/07/slide_3.jpg?w=900

stress
Stress in Earth’s Crust

Elastic deformation

The rock returns to its
original shape when the
stress is removed.
Stress in Earth’s Crust

Plastic deformation

The rock does not return
to its original shape when
the stress is removed.

https://media.springernature.com/lw685/springer-static/image/prt%3A978-3-540-31080-8%2F16/MediaObjects/978-3-540-31080-8_16_Part_Fig1_HTML.jpg
Stress in Earth’s Crust

Fracture

The rock breaks

https://4.bp.blogspot.com/-AwWfCuRhMzM/VcEdq1UPBLI/AAAAAAAABZo/KhEBz06Rt5o/s1600/7.6.jpg
Stress in Earth’s Crust
Stress in Earth’s Crust

At the Earth’s surface, rocks
usually break quite quickly, but
deeper in the crust, where
temperatures and pressures are
higher, rocks are more likely to
deform plastically.

Sudden stress, such as a hit with
a hammer, is more likely to
make a rock break. Stress
applied over time often leads to
plastic deformation.
Geologic Structure

Sedimentary rocks are formed with
the oldest layers on the bottom and
the youngest on top.

Sediments are deposited horizontally,
so sedimentary rock layers are
originally horizontal, as are some
volcanic rocks, such as ash falls.

Sedimentary rock layers that are not
horizontal are deformed.
Geologic Structure

Folds

Rocks deforming plastically
under compressive stresses
crumple into folds. They do
not return to their original
shape. If the rocks experience
more stress, they may undergo
more folding or even fracture
Geologic Structure

Folds

A monocline is a simple bend
in the rock layers so that they
are no longer horizontal
Geologic Structure

Folds

An anticline is a fold that arches
upward. The rocks dip away from
the center of the fold

The oldest rocks are at the center
of an anticline and the youngest
are draped over them

Dome – Structure
Geologic Structure

Folds

Syncline: A syncline is a fold
that bends downward. The
youngest rocks are at the
center and the oldest are at
the outside

Basin - structure
Geologic Structure

Faults

A rock under enough stress
will fracture. If there is no
movement on either side of a
fracture, the fracture is called
a joint
Geologic Structure

Faults

If the blocks of rock on one or
both sides of a fracture move,
the fracture is called a fault

Sudden motions along faults
cause rocks to break and move
suddenly. The energy released
is an earthquake.
Geologic Structure

Faults

Dip
Faults lie at an angle to the
horizontal surface of the
Earth

Dip-slip fault
Fault’s dip is inclined
relative to the horizontal
Geologic Structure

Faults

Thrust fault
Type of reverse fault in
which the fault plane angle
is nearly horizontal. Rocks
can slip many miles along
thrust faults
Geologic Structure

Faults

Normal fault
Responsible for uplifting
mountain ranges in regions
experiencing tensional
stress
Geologic Structure

Faults

Strike-slip fault
Dip-slip fault in which the
dip of the fault plane is
vertical. Strike-slip faults
result from shear stresses
Geologic Structure

Faults

Strike-slip fault
Dip-slip fault in which the
dip of the fault plane is
vertical. Strike-slip faults
result from shear stresses
Stress and Mountain Building

The world’s highest
mountain range, the
Himalayas, is growing
from the collision
between the Indian and
the Eurasian plates

The crumpling of the
Indian and Eurasian plates
of continental crust
creates the Himalayas.
Stress and Mountain Building

Subduction
Oceanic lithosphere at
convergent plate
boundaries also builds
mountain ranges

The Andes Mountains are
a chain of continental arc
volcanoes that build up as
the Nazca Plate subducts
beneath the South
American Plate
Stress and Mountain Building

Basin-and-range

When tensional
stresses pull crust
apart, it breaks into
blocks that slide up and
drop down along
normal faults.

The result is alternating
mountains and valleys
References
https://opengeology.org/textbook/7-geologic-time/
https://geo.libretexts.org/Bookshelves/Geology/Fundamentals_of_Geology_(Schulte)/07%3A_Cr
ustal_Deformation/7.03%3A_Stress_in_Earth's_Crust
https://courses.lumenlearning.com/geo/chapter/reading-continental-drift-2/
https://courses.lumenlearning.com/geo/chapter/reading-theory-of-plate-tectonics-2/
https://courses.lumenlearning.com/geo/chapter/reading-supercontinents/