Quantum Mechanics: The Need for an Electrodynamically Complete Model

For over a century, quantum mechanics (QM) has been a cornerstone of modern physics. Despite this extensive period, the field remains in a state of infancy with regard to its dynamics. In this article, we will explore the current state of quantum mechanics, highlight the shortcomings in its current models, and propose a path towards an 'improved' version of QM.

Current State of Quantum Mechanics

The development of quantum mechanics from 1910 to 1928 saw significant milestones, particularly in the formulation of the hydrogen atom. However, these models were primarily static and lacked the dynamic aspects required to fully describe the behavior of real atoms interacting with their electromagnetic environments.

During this crucial period, quantum mechanical models provided stationary solutions for hydrogen atoms, but these solutions did not capture the dynamic nature of real atoms. As a result, the modelers were forced to assume instantaneous energy exchanges, despite evidence from spectroscopy indicating otherwise. This discrepancy between theory and observation highlights the need for a more complete and dynamic model.

Limitations and Shortcomings

The limitations of the early quantum models are evident when considering the behavior of atoms in their natural environment. Real atoms spend a considerable amount of time in quasi-stationary states, which are approximately describable by the stationary states of the electrostatic models. However, these models fail to account for the periods of electrodynamic interactions that occur as atoms exchange energy with their surrounding electromagnetic fields.

This gap in the models is particularly important because it affects our understanding of the transition between quasi-stationary states. The periods of electrodynamic energy exchange represent critical intervals of interaction that are essential for a complete model of quantum behavior. The absence of these dynamics in early quantum models led to the conclusion that energy exchanges must occur instantaneously, a hypothesis that is at odds with experimental evidence.

Potential for Improvement

There is room for significant improvement in the field of quantum mechanics. This improvement can be achieved through the integration of new mathematical and scientific concepts, particularly in the areas of electrodynamics and applied mechanics.

One approach involves rethinking quantum mechanics from a fundamental perspective, considering the hidden attributes of nature and the interactions between the subject and the environment. This perspective opens the door to a new integrative framework that can address the shortcomings of current models.

The proposed framework emphasizes the importance of duality, where both non-physical and physical energy are recognized as fundamental components of creation. This dualistic approach is centered around the principles of subject-object interactions, with a focus on the creation process. By integrating these principles, we can develop a more comprehensive understanding of quantum mechanics.

Conclusion

While quantum mechanics has made incredible strides in its century-long journey, it still lacks a fully electrodynamically complete model. The proposal for improvement involves rethinking the fundamental aspects of quantum mechanics and integrating new theories that address the gaps in current models.

The path forward requires a new integrative framework that can bridge the gap between non-physical and physical energy. This approach will not only improve our understanding of quantum mechanics but also provide a more profound insight into the creation process and the underlying principles of nature.

With continued research and innovation, we can expect future breakthroughs that will reshape our understanding of the quantum world.