A public lecture by Stacia Gordon, Associate Professor, University of Nevada-Reno.
The Himalayan mountain belt began to form as a result of the collision of India with Asia ~50 million years ago. This mountain belt continues to grow today, and has resulted in the largest mountains on Earth. As the Himalaya has grown taller, it also has grown deeper. At depth (~40 km below Earths surface), pressures and temperatures are so great as to begin to melt and ductilely deform rocks that were originally at the surface of India and Asia. These rocks form the base or the roots of the Himalayan mountain belt. Across the Himalaya, some of the rocks that were buried to these great depths have since been exhumed back to the surface. Tiny, but very rugged minerals extracted from these exposed rocks represent time capsules that preserve a record of the thermal, chemical, and temporal evolution of Himalayan rocks from burial to exhumation.
In this lecture Dr Gordon will trace this evolution through the Bhutanese Himalaya, describing how the tiny crystals reveal the role of melting, deformation, major fault systems, and erosion in the evolution of the mountain belt. The data collected from the active Himalaya are crucial for understanding ancient mountain systems where much of the record of their evolution has been erased.
Dr Gordon is a UWA Robert and Maude Gledden Senior Visiting Fellow.
The Himalayan mountain belt began to form as a result of the collision of India with Asia ~50 million years ago. This mountain belt continues to grow today, and has resulted in the largest mountains on Earth. As the Himalaya has grown taller, it also has grown deeper. At depth (~40 km below Earths surface), pressures and temperatures are so great as to begin to melt and ductilely deform rocks that were originally at the surface of India and Asia. These rocks form the base or the roots of the Himalayan mountain belt. Across the Himalaya, some of the rocks that were buried to these great depths have since been exhumed back to the surface. Tiny, but very rugged minerals extracted from these exposed rocks represent time capsules that preserve a record of the thermal, chemical, and temporal evolution of Himalayan rocks from burial to exhumation.
In this lecture Dr Gordon will trace this evolution through the Bhutanese Himalaya, describing how the tiny crystals reveal the role of melting, deformation, major fault systems, and erosion in the evolution of the mountain belt. The data collected from the active Himalaya are crucial for understanding ancient mountain systems where much of the record of their evolution has been erased.
Dr Gordon is a UWA Robert and Maude Gledden Senior Visiting Fellow.