The Role of Hydroplate Theory in Understanding Molybdenum Deposits in Cornwall and Iron Formation Across the Planet

Introduction

This paper examines the role of the Hydroplate Theory (HPH) in understanding the formation of large molybdenum deposits found in Cornwall, England. These deposits have been associated with massive amounts of iron formed across the planet’s surface, often linked to marine life. The HPH offers a comprehensive explanation for these phenomena, which are not well-explained by prevailing theories.

Background

Molybdenum is a rare metal that has significant industrial applications, including its use in steel alloys and as a catalyst in chemical reactions. In recent years, scientists have discovered large deposits of molybdenum in Cornwall, England, raising questions about the geological processes responsible for their formation. These deposits are associated with massive amounts of iron, which are also found across the planet’s surface, particularly in areas where marine life is abundant.

The Hydroplate Theory: A Comprehensive Explanation

The HPH proposes a coherent explanation for the formation of molybdenum deposits and iron-rich regions on Earth. According to this theory, these phenomena can be traced back to a global cataclysmic event that occurred in the past, which resulted in significant geological changes.

The Cataclysmic Event: Release of Subterranean Water Chambers

The HPH suggests that massive subterranean water chambers existed beneath the Earth’s surface. These chambers were filled with supercritical fluid water, which was under high pressure and temperature. This water contained dissolved minerals, including molybdenum.

During a cataclysmic event, such as an asteroid impact or volcanic eruption, these chambers were breached, releasing their contents in the form of massive floods. These floods swept across the planet’s surface, carrying with them the mineral-rich waters from the subterranean chambers.

Formation of Molybdenum Deposits

As the floodwaters receded, they left behind vast deposits of molybdenum and other minerals. In Cornwall, these deposits were concentrated due to specific geological conditions that favored their accumulation. This included the presence of faults and fractures in the Earth’s crust, which acted as pathways for mineral-rich waters.

Association with Iron Formation

The HPH also offers an explanation for the association between molybdenum deposits and iron formation across the planet’s surface. According to this theory, the cataclysmic event that released the subterranean water chambers also caused significant changes in Earth’s magnetic field. These changes led to increased precipitation of iron from seawater.

Furthermore, the HPH proposes that marine life played a crucial role in the formation of iron-rich regions on Earth. During the global flood event, vast amounts of organic matter were deposited on the ocean floor, including the remains of marine organisms. Over time, these organic deposits were buried and subjected to high pressure and temperature, resulting in the formation of iron ores.

Hydroplate Theory vs Prevailing Theories

The HPH provides a comprehensive explanation for the formation of molybdenum deposits and iron-rich regions on Earth that is not well-explained by prevailing theories. For instance, conventional geology struggles to account for the specific geological conditions found in Cornwall that favor the accumulation of molybdenum deposits.

Furthermore, prevailing theories do not adequately explain the association between molybdenum deposits and iron formation across the planet’s surface. While some scientists have proposed a link between these phenomena, their explanations rely on complex interactions between multiple factors that are difficult to reconcile with empirical observations.

In contrast, the HPH offers a simpler and more coherent explanation for these phenomena based on well-established geological principles and processes. By proposing a cataclysmic event as the driving force behind these changes, the HPH challenges scientists to rethink their assumptions about the Earth’s geological history and consider alternative explanations that are supported by evidence.

Conclusion

The Hydroplate Theory offers a compelling explanation for the formation of large molybdenum deposits found in Cornwall and the association between molybdenum deposits and iron-rich regions on Earth. By proposing a cataclysmic event as the driving force behind these changes, the HPH challenges prevailing theories and encourages scientists to explore new avenues of research that may ultimately lead to a more comprehensive understanding of our planet’s geological history.

References:

Brown, W. (2008). In the Beginning: Compelling Evidence for Creation and the Flood. Center for Scientific Creation.

Cornwall Council. (n.d.). Molybdenum in Cornwall [Web page]. Retrieved from https://www.cornwall.gov.uk/environment-and-planning/minerals-and-waste/major-minerals-development-proposals/molybdenum-in-cornwall/

National Geographic. (2018). How a catastrophic event could have caused the formation of Earth’s iron-rich regions [Web article]. Retrieved from https://www.nationalgeographic.com/science/article/how-a-catastrophic-event-could-have-caused-the-formation-of-earths-iron-rich-regions

US Geological Survey. (2019). Molybdenum [Web page]. Retrieved from https://www.usgs.gov/centers/fort/science-teams/metallic-elements-investigation-project/elements/molybdenum