I’m not saying it’s happening. But we should keep an eye on it. SpaceX may not even know the effects of what they are doing with so many satellites.
N. U.S. and π¨π¦ Canada are the antipode challenge of them as Blue Eagle, but the majority of the U.S. is Blue Monkey magic. π©
From GROK…
Letβs dive deeper into whether Starlink satellites interfere with Earthβs magnetosphere frequencies. Iβll pull from web data, X posts, and some critical reasoning to give you a fuller picture as of April 10, 2025.
The Earthβs magnetosphere is shaped by its magnetic field, interacting with solar wind and cosmic rays, and it resonates at very low frequenciesβlike the Schumann resonances (around 7.83 Hz and harmonics). Starlink satellites, orbiting at 340β550 km, emit radio signals in the Ku-band (12β18 GHz), Ka-band (26.5β40 GHz), and potentially higher bands for communication. These are vastly higher frequencies than the magnetosphereβs natural ones, so direct overlap seems unlikely. However, thereβs more to unpack.
Recent studies, like one from Astronomy & Astrophysics (2023), found Starlink satellites leaking unintended electromagnetic radiation (UEMR) between 110β188 MHz, detected by the LOFAR telescope. This range is much closer to some ionospheric frequencies but still far above the magnetosphereβs ultra-low range.
A newer study (September 2024) showed second-generation Starlink satellites (e.g., V2 Mini) emit UEMR up to 32 times stronger than their predecessors, with signals as bright as 1300 Jy in some bands. This radiation isnβt regulated for satellites, unlike terrestrial devices, and itβs raising concernsβmostly for radio astronomy, though.
The Square Kilometre Array (SKA) analysis also noted a 70% sensitivity loss in the 10.7β12.7 GHz band due to Starlinkβs intentional emissions, but again, this is about observational interference, not magnetospheric disruption. Could this UEMR indirectly affect the magnetosphere? Some speculate that cumulative electromagnetic noise from thousands of satellitesβover 6,000 Starlink units is up now, with plans for 42,000βmight perturb the ionosphere, which couples to the magnetosphere.
A 2024 paper by Sierra Solter-Hunt (still in peer review) argues that conductive debris from deorbiting satellites (aluminum, etc.) could form a βdust bandβ in the upper atmosphere, potentially weakening the magnetosphere by altering its conductivity. She estimates SpaceX burns up 2,755 lbs of debris hourly, creating a metallic layer that might disrupt magnetic field dynamics. Critics, like John Tarduno, counter that this debris wouldnβt form a continuous conductive shell capable of significant shielding, as itβs fragmented, not a solid conductor.
X posts reflect growing unease. One user (@ExploreCosmos_Feb 2024). I flagged this debris-magnetosphere link, citing Solter-Huntβs work.
Another (@trulightwaves, April 9, 2025) claimed Starlinkβs βsuperconductingβ the ionosphere could trigger geological disastersβhyperbolic and unproven, but it shows public concern.
@gnigh (April 7, 2025) tied Starlinkβs EMF to broader atmospheric effects, though without evidence. These posts lack rigor but echo a sentiment thatβs worth probing.
Critically, the magnetosphereβs frequencies are driven by solar wind and geomagnetic stormsβlike the February 2022 event that downed 38 Starlink satellitesβnot satellite emissions. A 2024 study in Earth, Planets and Space showed moderate storms, not satellite signals, caused that orbital decay via atmospheric drag. Starlinkβs radio emissions, even UEMR, operate at power levels (e.g., ~2 ΞΌW EIRP at 159.4 MHz per one study) dwarfed by natural phenomena. Solar wind energy input is orders of magnitude higher, suggesting satellites are a minor player.
That said, the sheer scale of Starlinkβs constellation invites scrutiny. If UEMR accumulates or debris alters ionospheric conductivity, could it subtly shift magnetospheric behavior over decades? No hard data confirms this yetβSolter-Huntβs hypothesis is theoretical, and empirical studies focus on astronomy, not magnetospheric frequencies. Web searches show no consensus on direct interference; most concern is about debris or radio telescope blinding. So, as of now: Starlinkβs emissions donβt directly overlap with magnetosphere frequencies, and no solid evidence shows they disrupt them. The debris angle is intriguing, but speculativeβneeds more research.
ME: Hertz frequency is a way to note sound frequency. Both the Starlink satellites and the 12 layers of the magnetosphere emit hertz level sound. Light comes from sound so is it plausible that the light from the sun is being changed as it heads to earth because of these two phenomena?
Your question weaves together some fascinating conceptsβHertz frequencies, sound, light, Starlink satellites, and the magnetosphereβso letβs break it down and explore whether these phenomena could plausibly alter sunlight reaching Earth.
First, a clarification: Hertz (Hz) measures frequency, which applies to both sound waves (vibrations in a medium like air) and electromagnetic waves (like radio signals or light). However, sound and light are distinct. Sound is mechanical, requiring a medium, while light is electromagnetic, traveling through a vacuum. The idea that “light comes from sound” isnβt accurate in physicsβlight is emitted when charged particles (e.g., electrons in the Sun) accelerate or transition energy states, not from sound waves. (See quote below disagreeing from UCLA) Still, letβs run with your premise and see where it leads.
The energy of a sound wave in a fluid can concentrate by 12 orders of magnitude to create flashes of light that can be shorter than 50 picoseconds.
Sonoluminescence: Sound Into Light
UCLAhttp://acoustics-research.physics.ucla.edu βΊ sonoluminesc…
Synchronicity is the Source of Consciousness 