Modelling Magma Movement: Unexpected Journeys in the Field and Lab

Modelling Magma Movement: Unexpected Journeys in the Field and Lab

Earth Sciences, University of Liverpool via YouTube Direct link

Summary

24 of 25

24 of 25

Summary

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Classroom Contents

Modelling Magma Movement: Unexpected Journeys in the Field and Lab

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  1. 1 Modelling magma movement: Unexpected journeys in the field and the lab
  2. 2 The Liverpool MAGMA Lab approach
  3. 3 Unexpected journey in the field..
  4. 4 Scaled analogue experiments
  5. 5 Dyke Geometry & surface deformation
  6. 6 Medusa - LaVision Laser System
  7. 7 Simple magma Analogue materials
  8. 8 Particle image velocimetry (PIV)
  9. 9 Dyke Flow velocity from PIV analysis
  10. 10 Silicon oil Dyke - 3 rpm
  11. 11 Scaling - Reynolds number (Re)
  12. 12 Scaling Results - Reynolds number
  13. 13 Unexpected journey in the Lab.. Newtonian fluid dyke at different Re
  14. 14 Newtonian fluid dykes - Flow regimes
  15. 15 Magma: A multiphase fluid
  16. 16 Crystal proportion and crystal shape
  17. 17 What about bubbly magma?
  18. 18 Modelling complex magma rheology
  19. 19 Another unexpected journey in the Lab... Magma analogues - were they shear thinning?
  20. 20 What about Reynolds number effects?
  21. 21 Drastically different flow regimes for dykes
  22. 22 How might flow regimes be expressed in solidified magma?
  23. 23 Sill geometry, strain rates and flow
  24. 24 Summary
  25. 25 Final thoughts and future directions

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