Clues

From experimental results confirming the behavior of charge forces to theoretical conjectures about the nature of gravitational interactions, these clues provide essential groundwork for understanding the fabric of reality.

Galileo’s Leaning Tower of Pisa Experiment

Dropping objects of different masses to demonstrate that both fall at the same rate, challenging the conventional notion that gravity is directly linked to mass.

Planck’s Equation E=hf

Proposes that energy is quantized and relates the energy of a photon to its frequency, providing a foundational concept in quantum mechanics.

The Instantaneous Charge Force

A spark of inspiration was ignited by the Instituto Nazionale di Fisca, Rome with their bold claim, asserting the instantaneous speed of charge. Although their findings were mysteriously removed from Wikipedia, it fueled curiosity and intrigue. This fascinating idea laid the groundwork for a thought-provoking conjecture that challenges conventional notions of the universe’s workings.

CA conjectures that charge forces may operate instantaneously. This challenges conventional notions of the universe’s workings and has profound implications for our understanding of photons and other quantum phenomena. This aligns with the idea that inductors always provide the “lagging component” of current flow (flux) with the charge component of emf (electromagnetic force, i.e., the voltage) as the “leading” force in time in “real circuitry.”

If a photon moves at the speed of light, then the dipole charges moving around the axis of the dipole must be moving at a much faster speed (c*λ*π). This idea, reminiscent of Tesla’s thoughts, suggests a profound relationship between the motion of charges and the fundamental constants of the universe.

In this captivating realm, the electron stands alone as the solitary representation of the charge force. As we explore the concept of entanglement, previously discussed, the connection between photons and their instantaneously collapsing dipoles unravels before us, adding yet another layer of wonder to the enigmatic world of charge forces.

CA challenges the boundaries of conventional thinking and invites exploration of implications of instantaneous charge forces. The concept of time seems to fade away in this realm. While this might challenge established notions, it provides a fertile ground for innovative thinking and exploration.

A new insight: What if the charge and its anti-charge were the result of instantaneous connection? They must exist simultaneously around the axii of time they rotate for energy to exist at any frequency. If one disappears, the other ceases to exist in its bound form. If an electron is extracted in the positive temporal dimension, its anti-electron ceases to exist instantaneously. The energy is lost and the electron is freed up as a particle.

The idea that charge forces might operate instantaneously could provide a new way to think about entanglement. If charges and their anti-charges are instantaneously connected, it might help explain how entangled particles can affect each other so quickly. This aligns with the notion that certain quantum effects might not be bound by the traditional constraints of space and time.

As we venture forth into uncharted territories, the boundaries of conventional thinking are challenged, and new possibilities emerge. The idea of instantaneous charge forces opens the door to a realm where time seems to fade away, and the true essence of the universe’s fabric reveals itself in all its awe-inspiring beauty.

Time-Symmetry and Charge Monopoles

Exploring symmetry, especially concerning time, and the potential existence of charge monopoles could provide insights into the fundamental nature of particles and their interactions.

The idea of charge monopoles as precursors to particles is indeed a captivating clue. Charge monopoles, particularly magnetic monopoles, have been a topic of theoretical interest for many years. They are hypothetical particles that have only one magnetic pole, either north or south, unlike a typical magnet which has both.

Exploring time-symmetry in relation to charge monopoles could potentially offer new insights into the fundamental nature of particles and their interactions. Time-symmetry, or time-reversal symmetry, is a concept where the fundamental physical processes remain unchanged if time is reversed. This symmetry plays a crucial role in many areas of physics, including quantum mechanics and particle physics.

If charge monopoles exist, they could help explain why electric charge is quantized, as suggested by Dirac’s theory. This theory posits that the existence of even a single magnetic monopole in the universe would require all electric charges to be quantized. This aligns with the observed quantization of electric charge in nature.

The relationship between charge monopoles and particles like electrons could also provide a deeper understanding of particle creation and annihilation processes. If an electron and its corresponding anti-electron (positron) are connected through an instantaneous charge force, their interactions could be fundamentally different from what we currently understand.

The relationship between charge monopoles and particles like electrons could also provide a deeper understanding of particle creation and annihilation processes. If an electron and its corresponding anti-electron (positron) are connected through an instantaneous charge force, their interactions could be fundamentally different from what we currently understand.

The Temporal Dynamics of Energy

In our quest to unravel the mysteries of energy, one crucial aspect often overlooked is the role of time. Time isn’t merely a bystander in the realm of energy but a fundamental player, intricately woven into the fabric of energy transformations.

Energy isn’t static; it flows, changes form, and interacts with its environment over time intervals. Consider this: every definition of energy involves some unit of time as a component. Whether it’s the rate of energy transfer, the change in energy over time, or the temporal evolution of energy states, time is omnipresent.

By incorporating time into energy equations, we gain insights into the temporal relationships and causal connections shaping energy phenomena. We uncover how energy states evolve, influenced by external factors and interactions.

Energy Phase Shift Changes

Observing phase shifts in resonance and waves provides clues to understanding fundamental characteristics of electromagnetic energy, especially in relation to reactive energy exchange in the near field.

Michelson Morley Experiment

A groundbreaking experiment using an interferometer to detect the hypothetical “ether wind,”

Pound and Rebka Experiment

Demonstrated that the velocity difference (acceleration) of photons is identical to that which a material object would acquire in free fall, challenging Einstein’s relativity.

Large Number Hypothesis

Paul Dirac, a renowned physicist, proposed the Large Number Hypothesis (LNH) in the 1930s. This hypothesis suggests a fundamental connection between the gravitational force and the electromagnetic force, as well as a cosmological interpretation of the passage of time. He proposed that these large numbers were not mere coincidences but rather reflected a deeper underlying relationship, and may be variables rather than constants.

The LIGO Experiment

Confirmed the presence of gravitational waves, predicted by CA, suggesting an ongoing universe contrary to the expanding universe theory.

The JILA Experiment

Confirmed Earth’s gravity “gradients” cause variations in the frequency of oscillations in an atomic clock at different heights, indicating the direct effect of Z0 impedance gradients caused by gravitational organization.