Which of the following statements regarding what we know about Earth’s interior is most accurate? A)We have been able to drill into the earth’s core B)Much about what we know about Earth’s mantle and core comes from caves and mines C)We know only about what is on the very surface of the earth, in what is known as the crust D)Energy waves allow us to see precisely what is deep inside the Earth, like a “tricorder” or scanner from Star Trek Which of the following statements regarding what we know about Earth’s interior is most accurate? A)We have been able to drill into the earth’s core B)Much about what we know about Earth’s mantle and core comes from caves and mines C)We know only about what is on the very surface of the earth, in what is known as the crust D)Energy waves allow us to see precisely what is deep inside the Earth, like a “tricorder” or scanner from Star Trek
Earth’s Interior What we know about Earth’s interior comes from indirect avenues of investigation. Earth’s diameter is approximately 12,756 km (~ 7,500 miles). -the deepest hole we have ever drilled into the Earth is only 9.6 km (~5 mi). so how do we know what it’s like? Seismic waves! - natural and man-made What we know about Earth’s interior comes from indirect avenues of investigation. Earth’s diameter is approximately 12,756 km (~ 7,500 miles). -the deepest hole we have ever drilled into the Earth is only 9.6 km (~5 mi). so how do we know what it’s like? Seismic waves! - natural and man-made
Earthquakes seismic (energy) waves travel through the earth some energy bounces off harder layers called reflection some energy travels through but gets bent, changing the direction the wave is traveling called refraction some energy is absorbed as it encounters materials called attenuation Allow us to model what waves show up at given locations, and when they arrive at given locations. Earthquakes seismic (energy) waves travel through the earth some energy bounces off harder layers called reflection some energy travels through but gets bent, changing the direction the wave is traveling called refraction some energy is absorbed as it encounters materials called attenuation Allow us to model what waves show up at given locations, and when they arrive at given locations.
Shallow high frequency seismic waves allow us to see reflectors and refractors at depth
Wave paths are influenced by density, temperature, and the angles at which they strike boundaries as they travel through and around the Earth
Factors affect seismic waves distance: farther = more attenuation density: higher = faster temperature: colder = faster liquid vs solid - solid = faster; p-waves and s-waves - liquid = slower; no s-waves angle of incidence- controls how much is reflected and how much is absorbed vertical arrangement of layers - controls the resultant direction of travel Factors affect seismic waves distance: farther = more attenuation density: higher = faster temperature: colder = faster liquid vs solid - solid = faster; p-waves and s-waves - liquid = slower; no s-waves angle of incidence- controls how much is reflected and how much is absorbed vertical arrangement of layers - controls the resultant direction of travel
P-wave and S-wave shadow zones - caused by transmissive and refractive properties of the waves interacting with rock and liquid
Zones of material with distinctive characteristics make up each layer in the Earth Greatly simplified it looks like concentric spheres
Crust - the rigid outer shell of the Earth, composed of solid rock; very thin- averages only 20 km thick (the crust is part of the Lithosphere) two kinds of crust Oceanic- most abundant; consists of rocks formed from mafic magma; very dense; very thin- 10 km thick Continental- underlies continents; consists of rock formed from felsic and intermediate magma; less dense than oceanic crust; thick-30 to 85 km thick Crust - the rigid outer shell of the Earth, composed of solid rock; very thin- averages only 20 km thick (the crust is part of the Lithosphere) two kinds of crust Oceanic- most abundant; consists of rocks formed from mafic magma; very dense; very thin- 10 km thick Continental- underlies continents; consists of rock formed from felsic and intermediate magma; less dense than oceanic crust; thick-30 to 85 km thick
What will happen as different kinds of crust interact with each other? A) Oceanic and Continental - ? B) Old Oceanic and Younger Oceanic - ? C) Continental and continental - ? What will happen as different kinds of crust interact with each other? A) Oceanic and Continental - ? B) Old Oceanic and Younger Oceanic - ? C) Continental and continental - ?
Uppermost mantle- Aesthenosphere Continental crust Oceanic crust Mohorovicic Discontinuity “The Moho” Mohorovicic Discontinuity “The Moho” Model of Lithosphere and Aesthenosphere showing thickness of Oceanic vs Continental crust
Isopach contour lines = lines of equal thickness of the crust
The boundary zone between the crust and the mantle is called the Mohorovicic Discontinuity or the “Moho” - a zone of low velocity transmission of seismic waves Mantle- the semi-solid (jello-like) material underlying the crust. Extends down to about 3000 km depth The uppermost part of the mantle is called the Aesthenosphere. mostly molten material The boundary zone between the crust and the mantle is called the Mohorovicic Discontinuity or the “Moho” - a zone of low velocity transmission of seismic waves Mantle- the semi-solid (jello-like) material underlying the crust. Extends down to about 3000 km depth The uppermost part of the mantle is called the Aesthenosphere. mostly molten material
The mantle is heated closer to the core Heated mantle material rises upward very slowly millions of years to move upward As it near the earth’s surface, the mantle material liquefies (due to pressure and temp relationships) It also begins to cool, and slowly starts to sink back into the core This creates a Convection current The mantle is heated closer to the core Heated mantle material rises upward very slowly millions of years to move upward As it near the earth’s surface, the mantle material liquefies (due to pressure and temp relationships) It also begins to cool, and slowly starts to sink back into the core This creates a Convection current
Two highly schematic models of mantle convection currents Two highly schematic models of mantle convection currents
Heated rising material Cooled sinking material 3D models of mantle convection currents
3D maps of the earth’s convection currents based on seismic wave analysis-complicated looking!
Earth’s core Divided into an inner and outer zone Outer zone is liquid- doesn’t transmit s-waves Probably composed of Nickel (Ni) and Iron (Fe), some heavier radioactive elements, along with some other elements (S or N- Sulfur or Nitrogen) Inner core is solid- based on speed of P-wave travel composed of same materials as outer core Important for generating Earth’s magnetic field Earth’s core Divided into an inner and outer zone Outer zone is liquid- doesn’t transmit s-waves Probably composed of Nickel (Ni) and Iron (Fe), some heavier radioactive elements, along with some other elements (S or N- Sulfur or Nitrogen) Inner core is solid- based on speed of P-wave travel composed of same materials as outer core Important for generating Earth’s magnetic field
Earth’s magnetic field is created by the rotation of the outer fluid core around the solid inner core This creates an electrical current Generates an electromagnetic Field. Similar to a bar magnet with a positive and negative end
Earth’s magnetic field fluctuates over time due to the unsteady nature of the geodynamo that is the the outer and inner core
Earth’s magnetic field interacts with solar particles, forcing them to the north or south pole, creating the Aurora Borealis
Earth’s magnetic field plays a vital role in the development of Plate tectonics theory Identification of a process that allows for Sea Floor Spreading. Earth’s magnetic field plays a vital role in the development of Plate tectonics theory Identification of a process that allows for Sea Floor Spreading.