Planned intervention: On Wednesday April 3rd 05:30 UTC Zenodo will be unavailable for up to 2-10 minutes to perform a storage cluster upgrade.
Published March 26, 2020 | Version v1
Journal article Open

The resonant frequency of exchanged sound waves in a Corona-cell microphone/speaker

Description

 One of ways to control or cure viral diseases like the Corona is using of  exchanged waves between viral RNAs and cellular DNAs.  In this research, we propose a model to compare the structure of cells and Corona viruses with the structure of speakers/microphones and obtain the frequency and the shape of exchanged waves. In this model, the cellular DNA and viral RNA are formed from charged particles and by their motions, some electromagnetic waves are emerged. In fact, they act like the inductors within speakers/microphones and produce some magnetic fields. These fields interact with charges around nuclear and viral membranes and produce some currents along them. In these conditions, membranes act like the magnet  within speakers/microphones and emit some new magnetic fields. These fields interact with DNA and viral inductors, move them and produce some extra magnetic waves, These waves move charges along viral and nuclear membranes, vibrate them and produce some sound waves. Shape of these waves depend on their RNA/DNA sources. A cellular DNA coils several times around the histone and supercoiled axes and produce linear, toroid and round inductors. A viral RNA coils and creates round viral inductor. These inductors are formed from hexagonal and pentagonal bases and emit hexagonal/pentagound linear/curved sound waves. Frequency of  DNA sound waves could be between 107 -1020 .   Also, frequency of viral sound waves could be between 107 -1011    [KVirus / KCell] where KVirus , KCell are some constants depending on the genus of liquids within viral and cell membranes. In some conditions, KVirus / KCell =1 and virus could be absorbed by cells.

Files

zenodo-sepehri-corona-converted.pdf

Files (1.0 MB)

Name Size Download all
md5:8dee451b770624e1ba275903f190ad14
1.0 MB Preview Download