The Mysterious Light Delay in Neutron Star Merger: A Closer Look at Frequency and Resistance

On September 14, 2015, the Laser Interferometer Gravitational-Wave Observatory (LIGO) detected the gravitational waves produced by the merger of two neutron stars, followed by the detection of light from the same event by several large telescopes. Astonishingly, the light arrived 1.7 seconds after the gravitational waves. This delay has sparked curiosity among physicists, astronomers, and researchers. Here, we delve into the possible reasons behind this fascinating phenomenon, focusing on the roles of frequency, energy production, and resistance in subatomic particle environments.

Understanding the Delay: Frequency and Resistance

The delay observed during the neutron star merger raises several questions. One plausible explanation involves the difference in the energetic energy production and resistance experienced by different forms of waves in subatomic particle environments.

Gravitational waves are believed to oscillate at a lower frequency compared to electromagnetic (EM) waves like light. These lower-frequency oscillations move through the fabric of space-time with less resistance, allowing them to propagate more quickly. Conversely, EM waves, such as light, encounter greater resistance in the subatomic environment, leading to a slower propagation speed.

Light versus Gravitational Waves

Light, a form of EM radiation, tends to be slowed down while traveling through denser regions. The higher the frequency of an EM signal, the more likely it is to be interfered with or slowed. For example, light waves, used in optical telescopes, are generally faster than radio waves used in radio telescopes, which have much lower frequencies.

In the case of the neutron star merger, the light traveling from the event had to cross through a region of space with significant local density and gravitational resistance. Meanwhile, the gravitational waves, which are less affected by these conditions, were able to reach Earth approximately 1.7 seconds earlier.

Energy Production and Terminal Velocities

The concept of terminal velocity comes into play when considering the speed at which various forms of waves can travel through subatomic particle environments. EM waves have a terminal velocity, which is influenced by the local conditions and density of the medium they are traveling through.

However, there may be additional factors contributing to the light's delay. The oscillations of the subatomic particles around the neutron stars could form a resistive region that affects the propagation of EM waves. This could be related to higher-order mathematical components that influence the way oscillations occur in the presence of supermassive gravitational troughs.

Normally, light cannot catch up to regions of space with the maximum expansions of π times the speed of light in a vacuum. However, if these regions are within a resistive gravitational trough or near a supermassive black hole, the conditions might allow for more rapid traversal.

Conclusion and Future Research

The delay in light observed during the neutron star merger is a complex phenomenon that requires further exploration. Understanding this delay can provide insights into the nature of subatomic particle interactions, the behavior of gravitational waves, and the dynamics of extreme cosmic events like neutron star mergers.

Future research should focus on detailed simulations and theoretical models that can help explain why light might be delayed compared to gravitational waves. This could involve a reevaluation of the General Energy Equation, incorporating higher-order mathematical components that account for the unique conditions encountered during such events.

While the exact mechanism behind this delay is still under investigation, this phenomenon underscores the importance of ongoing research in astrophysics and the role of fundamental physics principles in explaining cosmic phenomena.

Keywords: neutron star merger, gravitational waves, light delay, subatomic particles, energy production