Quantum Physics Explains Accelerating Ocean Temperature Rise

A groundbreaking study by Emeritus Professor Geoff Smith from the University of Technology Sydney has shed new light on the accelerating rates of heat uptake by oceans, which cannot be explained by current climate models. According to Professor Smith’s research, published in the Journal of Physics Communications, quantum physics holds the key to understanding this phenomenon.

The data accumulated over 70 years shows a rapid rise in ocean temperatures and energy storage, with the global average sea surface temperature reaching a record high of 21.1°C earlier this year. Current scientific models fail to predict this acceleration, but Professor Smith’s “quantum thermal physics paradigm” offers a solution.

He suggests that the energy stored in oceans is a combination of heat and quantum information, which has always been present but is now being disrupted by extra heat input from the Earth’s atmosphere. This new understanding has significant implications for climate models and our ability to mitigate the effects of global warming.

Quantum Thermal Physics Paradigm: A New Perspective on Ocean Temperature Acceleration

The recent publication of a paper in the Journal of Physics Communications by Emeritus Professor Geoff Smith has shed new light on the accelerating rates of heat uptake by oceans, which have been puzzling scientists for decades. The Australian scientist proposes a novel “quantum thermal physics paradigm” to better understand the impact of global warming on oceans and, subsequently, on climate and weather.

The data accumulated over 70 years reveals an alarming acceleration in ocean temperatures and the total energy stored in oceans. This trend has led to a record-breaking global average sea surface temperature of 21.1°C earlier this year, a milestone that has sparked concern among scientists. However, current scientific models fail to predict this acceleration, despite the ongoing rise in atmospheric greenhouse gases.

Professor Smith’s research suggests that the solution to this conundrum lies in recognizing that the energy stored in oceans is not solely heat but also includes energy in the form of quantum information. When ocean water is heated by radiation from the sun and the sky, it stores energy not only as heat but also as hybrid pairs of photons coupled to oscillating water molecules. These pairs are a natural form of quantum information, distinct from the information being pursued in the development of quantum computing.

The Role of Non-Thermal Energy in Ocean Temperature Acceleration

The extra store of energy, which has always been present and aided ocean thermal stability prior to 1960, is now being disrupted by the increasing heat input from the Earth’s atmosphere. This disruption raises both forms of stored energy, leading to an acceleration in ocean temperatures. The apparent role of non-thermal energy in accelerating ocean temperatures must be factored into climate models to accurately predict and mitigate the effects of global warming.

The implications of this research extend beyond climate modeling, as it also highlights the need to refine thermal response models for built and natural outdoor systems. This refinement could lead to improved comfort, reduced energy consumption, and better human, plant, and animal health in a warming climate.

The Limitations of Current Climate Models

Current scientific models are inadequate in predicting the accelerating rates of heat uptake by oceans, despite the ongoing rise in atmospheric greenhouse gases. This limitation stems from the failure to account for the non-thermal energy stored in oceans, which is now being disrupted by increasing heat input from the atmosphere.

The development of more accurate climate models requires a deeper understanding of the quantum thermal physics paradigm and its role in ocean temperature acceleration. By incorporating this new perspective into climate modeling, scientists can better predict and prepare for the consequences of global warming.

The Imperative of Reducing Atmospheric Greenhouse Gases

While the recognition of non-thermal energy’s role in ocean temperature acceleration is crucial, it is essential to acknowledge that the only way to slow, then stop, this alarming temperature acceleration is to stop the rise in atmospheric greenhouse gases. The reduction of these gases is critical to mitigating the effects of global warming and ensuring a sustainable future.

The research by Professor Smith serves as a stark reminder of the urgent need for collective action to address climate change. By acknowledging the complexities of ocean temperature acceleration and the imperative of reducing atmospheric greenhouse gases, humanity can work towards a more sustainable and environmentally conscious future.