teacher’s notes
student’s notes
. (b) The plates concerned must be moving towards one another. There must
be a collision zone ahead. This is the Eurasian plate colliding with the
Pacific plate (forming Japan).
Collision causes earthquakes in Japan - compressional faulting.
Due to the collision, one plate sinks (subducts) beneath the other – this
plate partially melts and causes volcanic activity (of a dangerous, explosive
kind).
Over time the volcanic mountains are weathered and eroded producing
sediment, the sediment forms sedimentary rocks.
Plate pressure deforms the rocks into intense folds.
Heat and pressure due to the collision cause metamorphism of the rocks.
Q 7. Most igneous activity is at the margin behind and at the margin in front
(there is no igneous activity in the middle of this plate). The activity behind is
caused by magma rising at the mid-Atlantic ridge. Activity ahead is caused
by frictional forces as one plate subducts below the other producing
explosive volcanic activity.
Q 8. In the collision zone. Where there are mountains being formed, these are
readily attacked by weathering and erosion processes. This causes high
rates of sedimentary activity.
Q 9. In the collision zone. Heat and pressure due to the collision causes
metamorphism of the rocks.
Q 10. In the collision zone there can be intense folding, and faulting and
dangerous earthquake activity. It is much quieter where plates are moving apart.
Plate riding: how is the plate you are on moving
now?: teacher's notes
Level
This activity is designed for students aged 14 –16. It will consolidate work they have
done on the rock record and, more particularly, on plate tectonics.
Topic
This material can act as review material to test students’ understanding of plate
tectonics and the rock cycle. It highlights the links between geological processes
and plate tectonic processes.
Teaching points
This would be a useful exercise to be set for homework or in the case of teacher
absence. Teachers may prefer students have access to their notes or text books to
answer some of the more demanding questions.
Timing
About 20 to 30 minutes to complete the questions plus discussion to follow.
Answers to questions
Q 1. (a) It is moving towards the east.
(b) 3 cm per year (about as fast as your fingernails grow)
Q 2. Everything on the plate is also moving at the same speed. Also it is so slow
that it would be impossible to detect.
Q 3. Accept any answer for plate tectonics that students may have met (identical
rocks or fossils on continents that are now split / ‘jigsaw fitting’ pattern of
continents that were once joined / evidence from magnetic stripes on ocean
floors).
Q 4. Global Positioning Systems (GPSs) can make very accurate measurements
of the Earth’s surface at intervals. They will fix a given point by latitude and
longitude on the surface and the movement of a point with respect to this can
then be measured.
Q 5. No. While some move away from one another, others move towards one
another and some slide past one another.
Q 6. (a) The plates concerned must be moving away from one another. The
Eurasian plate is moving away from the N. American plate, for example.
Since there is no hole in the ocean bed appearing, any gaps must be filled by
new plate material through igneous activity at the mid-Atlantic ridge.
The pulling apart (tension) causes tensional faulting and sections of crust can
slide down forming a rift valley.
Not much sediment has accumulated since the oceanic plate is so new.
Apart from a bit of baking of one igneous rock by a newer hot one, there is no
metamorphic activity (there are no compressional pressures to cause wide
scale (regional) metamorphism).