When a very fast RF pulse enters a human body, it generates a burst of energy (a Brillouin precursor) that can travel much deeper than predicted by the conventional models. Brillouin precursors can be formed by high-speed data signals as used in 5G. StarLink uses an even higher frequency.

Propagation of THz irradiation energy through aqueous layers: Demolition of actin filaments in living cells

When a very fast RF pulse enters a human body, it generates a burst of energy (a Brillouin precursor) that can travel much deeper than predicted by the conventional models. Brillouin precursors can be formed by high-speed data signals as used in 5G.

StarLink uses an even higher frequency, in the range that Brillouin precursors are known to occur.

Propagation of THz irradiation energy through aqueous layers: Demolition of actin filaments in living cells

When a very fast RF pulse enters a human body, it generates a burst of energy (a Brillouin precursor) that can travel much deeper than predicted by the conventional models. Brillouin precursors can be formed by high-speed data signals as used in 5G.

Propagation of THz irradiation energy through aqueous layers: Demolition of actin filaments in living cells

When a very fast RF pulse enters a human body, it generates a burst of energy (a Brillouin precursor) that can travel much deeper than predicted by the conventional models. Brillouin precursors can be formed by high-speed data signals as used in 5G.

Propagation of THz irradiation energy through aqueous layers: Demolition of actin filaments in living cells

Propagation of THz irradiation energy through aqueous layers: Demolition of actin filaments in living cells