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Seeing Inside the Earth
ESSENTIALS OF
GEOLOGY
3rd Edition
Stephen Marshak
© 2009 W.W. Norton
INTERLUDE
The Earth’s surface hides a hot interior.
© 2009 W.W. Norton
Fig. D.CO
Fig. D.1
Oceanic crust
Continental crust
Crust
Mantle
Mantle
Continental and oceanic crust are
not the same.
A simple 3-layer
Earth model.
The 19th century image of the Earth’s interior.
© 2009 W.W. Norton
Core
Fig. D.2a,b
Seismic ray
Wave front
An earthquake sends out waves in all directions.
Peridotite
Seismic waves travel at different velocities
in different rock types.
The propagation of earthquake waves — 1.
© 2009 W.W. Norton
Sandstone
Fig. D.2c,d
S-wave
Solid
Liquid
P-wave
P-wave
Solid iron
alloy
P-wave
Molten iron
alloy
P-waves travel faster in solid iron allow than in liquid, such as
molten iron alloy.
The propagation of earthquake waves — 2.
© 2009 W.W. Norton
Both P-waves and S-waves can travel through a solid, but
only P-waves can travel through a liquid.
Fig. D.3a,b
Incoming light
Air
Water
Reflected
Refracted
Faster
Slower
Slower
Faster
A ray entering slower material bends away from the boundary,
but a ray entering faster material bends toward the boundary.
Refraction and reflection of waves.
© 2009 W.W. Norton
A ray of light reflects and refracts when it crosses
the boundary between different materials.
Fig. D.4a,b
Crust
Moho
Mantle
A nearby seismograph detects crustal seismic waves first.
Crust
Moho
A distant seismograph detects mantle seismic waves first,
because waves travel faster in mantle rock.
Discovery of the Moho.
© 2009 W.W. Norton
Mantle
Fig. D.5
P-wave velocity (km/s)
7
9
5
11
0
Lithosphere
LVZ
200
Upper
Mantle
400
Depth (km)
Transition
zone
600
Lower
mantle
1000
The velocity of P-waves in the mantle changes with depth.
© 2009 W.W. Norton
800
Fig. D.6a,b,c
Seismic ray
Focus
In a stack of discrete layers, rays bend at
each boundary.
Mantle
If velocity increases gradually with depth, rays
curve smoothly.
The velocity of seismic waves changes with depth in the mantle .
© 2009 W.W. Norton
The velocity of seismic waves
increases with depth in the mantle,
so rays curve.
Fig. D.7a
Focus
103
°
P-wave
shadow zone
P-wave
shadow zone
143
°
P-waves do not arrive in the P-wave shadow zone.
Shadow zones and the discovery of the Earth's core — 1.
© 2009 W.W. Norton
P-wave
shadow zone
Fig. D.7b
Focus
103
°
S-wave
shadow zone
S-wave
shadow zone
S-waves do not arrive in the S-wave shadow zone.
Shadow zones and the discovery of the Earth's core — 2.
© 2009 W.W. Norton
103
°
Fig. D.7c
Source
Seismograph
Incident
ray
Mantle
Reflected
ray
Outer
core
Seismic waves reflect off the inner core-outer core boundary.
Shadow zones and the discovery of the Earth's core — 3.
© 2009 W.W. Norton
Inner
core
Note the error!
The outer core is liquid (the
liquidus lies to the left of the
geotherm, so it melts).
Fig. D.7d
0
Melting
curve
1000
Mantle
Depth
(km)
Geotherm
2000
3000
Solid
outer
core
4000
A graph of the geotherm and
melting curve for the Earth.
5000
Liquid
inner
core
6000
Liquid and solid
inside the Earth.
0
2000
4000
Temperature (°C)
© 2009 W.W. Norton
The inner core is solid (the
geotherm is not enough to
melt it because of high
pressure).
Fig. D.8
0
0
4
Velocity (km/s)
8
12
400
670
S-wave
2900
Core-mantle
boundary
4155
Inner coreouter core
boundary
Depth
(km)
6371
The velocity-versus-depth profile of the Earth.
© 2009 W.W. Norton
P-wave
Fig. D.9a
Mantle
Outer
core
Inner
core
Faster
Tomographic image of the whole Earth.
Tomographic images of the Earth's interior — 1.
© 2009 W.W. Norton
Slower
Fig. D.9b,c
Pacific
Ocean
Plate
graveyard
North
America
660 km
Convecting
cell
Mantle
plume
Lower Mantle
Tomographic images of the Earth's interior — 2.
Modern view of the Earth's
complex and dynamic interior.
© 2009 W.W. Norton
Close-up tomographic
image of the mantle.
Fig. D.10a,b
Ground surface
Trucks thump the ground to generate a seismic signal.
100 ft
Seismic-reflection profiling.
© 2009 W.W. Norton
1000 ft
A seismic-reflection profile. Color
stripes are subsurface layers.
Fig. BXD.1.1
Geoid high
The Earth's geoid is distorted by highs and lows in the gravity field.
An exaggerated representation of the geoid.
© 2009 W.W. Norton
Geoid low
Interlude D: Figure Credits
© 2009 W.W. Norton
BXD.1: ESA; D.10a: John Q. Thompson, courtesy of Dawson Geophysical
Company; D.10b: John Q. Thompson, courtesy of Dawson Geophysical Company.