Comments on this forum should never be taken as investment advice.
|
|
Thread Tools | Display Modes |
#1
|
|||
|
|||
Paralana back in the news
Great to see renewed interest in Paralana's hot rocks for geothermal energy in https://stockhead.com.au/energy/eart...l-development/ article published today 6/11/2024.
In the past I have posted about Paralana in this forum and on www.HotRockEnergy.com .... Below is a new summary. Radiogenic Heat and Structural Geology: The Dual Engines of Paralana's Geothermal Potential Introduction The Paralana geothermal project, located 300km northeast of Port Augusta in South Australia, represents a unique convergence of geological phenomena that create exceptional conditions for geothermal energy production. Two distinct geological features—radiogenic heat production and complex fracture networks—combine to form what could be one of Australia's most promising geothermal resources. Radiogenic Heat Generation: Nature's Nuclear Reactor The Radioactive Engine Deep beneath Paralana's surface lies a remarkable heat-generating system driven by naturally occurring radioactive elements. Unlike conventional geothermal systems that rely solely on heat from the Earth's core, Paralana's granite formations act as a self-sustaining heat generator through radioactive decay. Key Radiogenic Elements The granite formations contain three primary heat-producing elements: Uranium-238: Generating approximately 51.7 × 10^-12 watts per gram Thorium-232: Contributing 21.9 × 10^-12 watts per gram Potassium-40: Adding 3.5 × 10^-12 watts per gram These elements undergo constant decay, releasing energy through multiple particle emissions: Alpha particles (helium nuclei) Beta particles (electrons or positrons) Gamma radiation The interaction between these emissions and the surrounding rock matrix converts kinetic energy into thermal energy, creating a continuous heat production cycle. Longevity and Stability The extraordinary half-lives of these radioactive elements ensure the system's longevity: Uranium-238: ~4.5 billion years Thorium-232: ~14 billion years Potassium-40: ~1.3 billion years This translates to a virtually inexhaustible heat source on human timescales, providing stable, predictable heat generation for power production. Structural Geology: Nature's Heat Exchanger Formation and Development The collision between the Australian continent and Southeast Asia created an intricate network of fractures within the granite formations. This tectonic event produced a sophisticated natural heat exchange system with multiple fracture sets: Primary Horizontal Fractures Direct result of continental collision Create major fluid pathways Enhance reservoir connectivity Secondary Vertical Fractures Formed through stress release Intersect horizontal fractures Improve vertical fluid movement Tertiary Fracture Networks Developed from local deformation Create additional reservoir complexity Enhance overall permeability Enhanced Geothermal System (EGS) Implications The horizontal fracture orientation provides several critical advantages: Natural fluid traps preventing vertical escape Improved pressure maintenance Enhanced heat extraction efficiency Reduced pumping requirements Better reservoir management potential Synergistic Effects The combination of radiogenic heat production and complex fracture networks creates a uniquely efficient geothermal system: Heat Generation and Transfer Continuous Heat Production Radioactive decay provides steady heat input Natural fractures enable efficient heat transfer Minimal thermal depletion risk Optimal Heat Extraction Horizontal fractures maximize surface area Cross-cutting fracture systems improve connectivity Enhanced fluid circulation possibilities Technical Advantages The system offers multiple benefits for geothermal development: Sustained temperature gradients (46°C per km) Natural reservoir pressure maintenance Improved heat exchange efficiency Long-term resource stability Conclusion The Paralana geothermal project exemplifies how natural geological processes can create optimal conditions for geothermal energy production. The combination of radiogenic heat production and complex fracture networks provides a reliable, sustainable energy resource that could play a significant role in Australia's renewable energy future. The site's measured bottom hole temperature of 171°C and exceptional temperature gradient of 1.84 times the Australian average demonstrate the practical implications of these geological features. As Australia continues its transition to renewable energy, Paralana's unique geological characteristics position it as a potentially valuable contributor to the nation's baseload power requirements. More info at www.hotrockenergy.com No need to build powerlines? Use Geothermal Energy to make Hydrogen and use technology discussed here: Provaris' ASX: PV1 to transport it
Disclaimer: The author of this post, may or may not be a shareholder of any of the companies mentioned in this column. No company mentioned has sponsored or paid for this content. |
Thread Tools | |
Display Modes | |
|
|