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Lecture 13

Table of Contents

  1. Tectonics and Surface Relief
  2. Why study surface relief?
  3. Why study surface relief?
  4. Why study surface relief?
  5. Why study surface relief?
  6. Why study surface relief?
  7. Why study surface relief?
  8. Why study surface relief?
  9. Why study surface relief?
  10. Above and Below sea level
  11. 13.1 Why are continents high and oceans low?
  12. 13.1 Why are continents high and oceans low?
  13. 13.1 Why are continents high and oceans low?
  14. 13.1 Why are continents high and oceans low?
  15. 13.1 Why are continents high and oceans low?
  16. 13.1 Why are continents high and oceans low?
  17. 13.1 Why are continents high and oceans low?
  18. 13.1 Why are continents high and oceans low?
  19. 13.2 How do we know ... that mountains have roots?
  20. 13.2 How do we know ... that mountains have roots?
  21. 13.2 How do we know ... that mountains have roots?
  22. 13.2 How do we know ... that mountains have roots?
  23. 13.3 How does isostasy relate to active geologic processes?
  24. 13.3 How does isostasy relate to active geologic processes?
  25. 13.3 How does isostasy relate to active geologic processes?
  26. 13.3 How does isostasy relate to active geologic processes?
  27. 13.3 How does isostasy relate to active geologic processes?
  28. Glacial Isostasy
  29. 13.3 How does isostasy relate to active geologic processes?
  30. 13.3 How does isostasy relate to active geologic processes?
  31. 13.3 How does isostasy relate to active geologic processes?
  32. 13.3 How does isostasy relate to active geologic processes?
  33. 13.4 Why does sea level change?
  34. 13.4 Why does sea level change?
  35. 13.4 Why does sea level change?
  36. 13.4 Why does sea level change?
  37. 13.4 Why does sea level change?
  38. 13.4 Why does sea level change?
  39. 13.5 How and where do mountains form?
  40. 13.5 How and where do mountains form?
  41. 13.5 How and where do mountains form?
  42. 13.5 How and where do mountains form?
  43. 13.5 How and where do mountains form?
  44. 13.5 How and where do mountains form?
  45. 13.5 How and where do mountains form?
  46. 13.6 How does mountain building relate to the growth of continents?
  47. 13.6 How does mountain building relate to the growth of continents?
  48. Non-Subductable Crust
  49. Non-Subductable Crust 2
  50. 13.6 How does mountain building relate to the growth of continents?
  51. 13.6 How does mountain building relate to the growth of continents?
  52. 13.6 How does mountain building relate to the growth of continents?
  53. Provinces of North America
  54. 13.6 How does mountain building relate to the growth of continents?
  55. 13.6 How does mountain building relate to the growth of continents?
  56. 13.6 How does mountain building relate to the growth of continents?
  57. Island Arcs
  58. 13.6 How does mountain building relate to the growth of continents?

Text and Images from Slide

13.3 How does isostasy relate to active geologic processes?

map showing rate of elevation change over 10 years based on GPS data

Fig 13.14

So which model: Pratt-Airy or Flexural Isostasy, better reflect real-world data?

Here we see the response of NE North America to the removal of the glaciers. The Hudson Bay region, the center of glacial loading, is rebounding upwards over the past 10 years (in red), while the southern periphery around Chicago (the red -2.7) is adjusting downwards. Clearly, the flexural isostasy model conforms better to this data.

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