Wednesday, November 6, 2024

Reframing Fundamental Constants: A New Perspective on Energy, Wavelength, and Relativity

James Rogers, SE Ohio, 2024 Nov 06 0400 I put the program up I use to rescale h and c up on github: https://github.com/BuckRogers1965/RedefineMeterForPlancksConstant "A new scientific truth does not triumph by convincing its opponents and making them see the light, but rather because its opponents eventually die, and a new generation grows up that is familiar with it." - Max Planck

Abstract: This paper introduces a novel framework for understanding fundamental constants, especially Planck's constant (h), as an encoding of simpler physical relationships. By reinterpreting constants as products of unit systems, we demonstrate a fresh perspective on the linkage between energy, wavelength, and relativistic effects. This approach suggests that complexities in quantum mechanics and relativity may stem more from unit choices than from fundamental mysteries in nature.


1. Introduction

The relationship between quantum mechanics and relativity has traditionally relied on a series of fundamental constants, notably Planck’s constant (h). This paper suggests that many constants, including h, may be understood as unit-derived quantities encoding simpler, fundamental relationships. This approach demystifies physical constants and offers a new perspective on the connection between energy, wavelength, and time dilation, paving the way for a geometric interpretation of quantum and relativistic phenomena.


2. Simple Encoding Using Division and Multiplication

Before discussing physical constants, we introduce a basic encoding-decoding method that shows how division by a constant (c) creates an encoded value that can be reversed simply by multiplication, obscuring the original values.

2.1 Encoding Process

Using an arbitrary value (1234567), we encode it with a constant cc:

h=1234567ch = \frac{1234567}{c}

where:

  • 1234567 is the original number,
  • cc is the chosen constant (e.g., 3 for simplicity),
  • hh is the result of the division.

Calculation:

h=12345673=411522.3333h = \frac{1234567}{3} = 411522.3333\ldots

2.2 Decoding Process

To retrieve the original number:

Original number=h×c=411522.3333×3=1234567

2.3 Observations

The encoded value hh appears independent of the original number, providing a simple form of reversible "hiding." This example will guide our discussion of constants like hh and cc, illustrating that these may encode more basic relationships.


3. Demystifying Planck’s Constant

3.1 The Relationship h=Kch = \frac{K}{c}

We hypothesize that Planck's constant hh can be expressed as a relationship between another constant KK and the speed of light cc:

h=Kc​

where K is a constant with units of energy times length, implying that hh encodes a unit-derived relationship rather than a standalone fundamental constant.

3.2 Defining K as a Unit Scaling Factor

Using K=1.98644568×1025 \times 10^{-25} J m and c=299,792,458c m/s, we show:

h = (1.98644568 × 10−25 J m) / (299,792,458 m/s)
h = 6.62607015 × 10−34 J s

By redefining K=1 J m, we could change our units such that hh and K become unit artifacts rather than fundamental mysteries.


4. Redefining Units to Expose the Fundamental Relationship

  1. Redefining Units to Expose the Fundamental Relationship
It might seem that K is the fundamental relationship rather than h. However, K itself is a scaling factor that depends on our choice of units for mass (m) and energy (J). When we adjust the units of m and J, K changes as well, affecting both h as m^2 and c as m.
4.1 Setting hc = 1 J·m as a Thought Experiment
Suppose we define hc as 1 J·m, which leads to redefining the speed of light (c) and the meter (m) in terms of Planck's constant (h) and the scaling factor K. In this scenario:
c = K/h
This new definition results in a significantly larger value for the speed of light and a smaller value for the meter. The actual speed of light remains unchanged; only the units used to measure it are altered. These redefined units may not be practical for daily use, but they provide valuable insights into the relationships between fundamental constants.
In these redefined units:
1/c = h
This equation demonstrates that when the scaling factor K is set to 1 J·m, the inverse of the speed of light becomes precisely equal to h. However, it is important to note that both h and c have been adjusted according to the changes in m and J. This thought experiment highlights the interconnectedness of fundamental constants and their dependence on the units we use to describe them, particularly the complex interplay between the scaling factor K, Planck's constant h, and the speed of light c.

I had to write a program to find this exact place where K = 1 J m with h moving as m^2 from the meter definition inside itself, and with c only moving as the m.  It was useful that they moved at different speed, it let 1/c catch up to h as they both moved. 

Meter factor: 5.834794668552e-09

New meter length: 1.713856368228e+08 old meters

Final h: 1.946278004282e-17 J·s

Final c: 51380121329003624.000000000000 m/s

1/c: 1.946278004282e-17

Relative difference between h and 1/c: 2.404990513452e-13


Revised Equations:
  • Energy-Frequency Relation:  E=Kfc, which maintains the relationship between energy and frequency while introducing K as a scaling factor.
  • Energy-Wavelength Relation: Similarly, E=Kwavelength suggests that energy is inversely related to wavelength, reinforcing the idea that K serves as a unit scaling factor.
  • Reduced Planck's Constant:  =K2πc connects the reduced Planck constant to this framework, further emphasizing the role of K.
  • Fine Structure Constantα=e22ϵ0K highlights how fundamental constants can be expressed in terms of K, suggesting a deeper relationship between electromagnetic interactions and geometric scaling.
  • all these formulas become geometric with the understanding that K is a scaling factor.

4.2 Energy as the Inverse of Wavelength

This unit choice clarifies that energy (E) relates directly to the inverse of wavelength ():

E=1J m/λ​

or more generally

E=K/λ​

This reveals that the energy-wavelength relationship is fundamentally a geometric property, with h and c merely scaling factors based on the units we’ve chosen.  So we can replace hc with just K with the understanding that K is just unit scaling, it is not special or fundamental in any way.


5. Linking Wavelength and Time Dilation in Relativity

5.1 Wavelength as a Measure of Time Dilation

In this framework, the wavelength of a particle can reflect time dilation. Particles with shorter wavelengths (higher energy) experience different time dilation effects, linking energy to relativistic effects. The shortening of the wavelength is the effect of time dilation on that length. And different observers will see this wavelength differently from their frame of reference.  

5.2 Energy as a Reflection of Time Dilation

This perspective allows us to interpret energy not just as a scalar quantity, but as a geometric factor related to time dilation, offering a bridge between quantum and relativistic descriptions. Because the wavelength depends on your point of view the energy will can depending on how you observe it.


6. Unification of Key Concepts

This framework enables a unified view of:

  • Wave-Particle Duality in quantum mechanics,
  • Energy-Frequency Relation as a geometric feature,
  • Time Dilation and Length Contraction as direct consequences of relative motion,
  • Mass-Energy Equivalence through curvature, reinterpreting mass and gravity as manifestations of spacetime geometry.

7. Conclusion

Our reinterpretation of physical constants suggests that many aspects of quantum mechanics and relativity might be reflections of the unit systems and measurement choices rather than intrinsic properties of nature. By exposing the geometric relationship between energy and wavelength, this approach encourages a simplified and unified view of quantum and relativistic phenomena, potentially transforming our understanding of physical constants as byproducts of measurement rather than fundamental mysteries.

No comments:

Post a Comment