Fall of Empires by Natural Phenomena
May 16, 2025
Natural Phenomena
June 16, 2025Can volcanic eruptions be predicted? In 2021, researchers Michael Cassidy and Lara Mani analyzed ice cores from both poles and recorded 1,113 volcanic signatures in Greenland ice and 737 in Antarctica, dating from 60,000 to 9,000 years ago. They identified 97 events likely to have had a climatic impact equivalent to a magnitude 7 or greater eruption. They concluded that magnitude 7 events occur approximately once every 625 years, while magnitude 8 events happen every 14,300 years.
- https://www.ngenespanol.com/el-mundo/es-hora-de-prepararse-para-las-supererupciones-volcanicas-advierten-expertos/
- https://www.20minutos.es/noticia/5042404/0/un-equipo-vulcanologos-advierte-riesgo-erupcion-volcanica-masiva/
- https://www.lavanguardia.com/natural/20220912/8518456/cientificos-advierten-riesgo-super-erupciones-volcanica-siglo-pmv.html
Volcanic activity frequency of magnitude 7 every 625 years
625 years / 1 subera of 179 years = 3.5 suberas frequency of 179 years
625 years / 1/2 subera of 859,5 years = 7 frequency of 1/2 suberas of 89,5 years
179 years = 1 subera
1 Era / 2.148 years / 12 suberas or constelations of 179 years
Volcanic activity frequency of magnitude 8 every 14,300 years:
14.300 years / 1 subera of 179 years = 80 suberas of 179 years of frequency
179 years = 1 subera
1 Era / 2.148 years / 12 suberas or constelations of 179 years
As we have seen earlier, global events that repeat cycles or half-cycles are being activated. In the case of volcanic eruptions, volcanic activity of magnitude 7 and 8 according to these recent discoveries from 2021, the evidence that they are associated with axial precession and its units of measurement is irrefutable because, when dividing these cycles of 625 and 14,300 years by the unit of measure of 179 years, the result is a whole number or its half.
The Iceland volcano example shown below provides clear proof of how when a volcano enters its axial repetition cycle, it becomes activated.
Content
Volcanic eruptions in Iceland
Precessional relationship between the Iceland volcano of 2023/4 AD and the previous 8 recorded peak activities.
In the October 2023 Cosmobiological Astrology Congress in Mexico and in interviews with Mexico in 2023, you can check how I warned that in 2024 we have a GLOBAL CRITICAL EVENT due to a volcanic fault event, initially in January, with a MINOR CRITICAL EVENT (initial date of the event in Iceland) and its peak between March 28 and April 6. Throughout January and February 2024, I have been providing all the dates of minor reactivations of the volcano/fault in private chats, which you can see on the website.
We can clearly see that there are two trends or cycles in the 8 strongest volcanic activities recorded in Iceland:
- In which the Bárðarbunga cycles 1477 AD, Katla (Eldgjá) 934 AD, Grímsvötn 8230 BC +/- 50 years and thel Katla 1755 AD. coincide in their cycles in 2023/4 AD. and thus in their relation to the axial precession and its units of measurement.
- In which the Katla cycles 1262 AD., Katla 1625 AD., Katla 1721 AD. and the Laki cycle 1783 AD coincide with another date in its cycle repetitions related to Hekla 1990 AD and 1971 AD. In this case, they are also related between them by the axial units but their repetition cycle date is different.
1/ Cycles 2023/4 AD
Volcanic activity Bárðarbunga 1477 AD
2023/4 AD – 1477 AD. = 546 years
546/179 = 3.0 3 suberas repeats cycle
Volcanic activity Katla (Eldgjá) 934 AD
2023/4 AD – 934 AD = 1089 years
1089/179 = 6.0 6 suberas repeats cycle
Volcanic activity Grímsvötn 8230 BC +/- 50 years
8230 BC. – 2023/4 AD. = 6207 years
6207/89.5 = 69.35 70 half suberas repeats cycle. The error margin is too wide but it should be considered.
Volcanic activity Katla 1755 AD.
2023/4 AD – 1755 AD = 268 years
268/179 = 1.498 1.5 suberas repeats cycle
2/ Cycles 1991 AD y 1970 AD
In 1991 AD and 1970 AD, the volcanic activities of Hekla in 1991 AD and Hekla in 1970 AD occurred, which are the years when the four activities I present among the eight most active historical eruptions complete their cycle. Therefore, these four are associated with those dates of Hekla in 1991 AD and 1970 AD, and it is possible to calculate when they will complete their half cycle or full cycle again. I did not want to delve further into other previous dates of volcanic activities, but without a doubt, earlier dates of volcanic events in Iceland could be found that were associated with cycle 2, which does not complete its cycle in 2023/4 AD but in 1991 AD and 1970 AD.
To calculate the new half or full cycle of this volcanic activity line, one would simply add 89 years or 179 years to 1991 AD and 1970 AD to see when it will activate again, or subtract 89 years or 179 years to find when other volcanic eruption activities took place, thus confirming the cycles.
Next cycle repetition:
- (2073 AD. – Katla1625 AD) / 179 = 2.50 2 suberas and a half
- (2073 AD. – Katla1262 AD.) / 179 = 4.53 4 suberas and a half
- (2073 AD. – Katla1721 AD) / 179 = 1.97 2 suberas
- (2073 AD – Katla1262 AD) / 89,5 = 9.06 9 half suberas
- (2073 AD. – Katla1625 AD) / 89,5 = 5.005 5 half suberas
- (2073 AD – Katla 1721 AD) / 89,5 = 3.94 4 half suberas
Cycle fit verification for 1991d.c. and 1970d.c.
Volcanic activity Katla 1625 AD
(Hekla1991 AD– Katla1625 AD) / 179 = 2.04 2 suberas
Volcanic activity Katla 1262 AD
(Hekla1991 AD – Katla1262 AD) / 179 = 4.07 4 suberas
Volcanic activity Katla 1721 AD
(Hekla1991 AD – Katla 1721 AD) / 179 = 1.508 1 subera and a half
Volcanic activity Laki 1783 AD
(Hekla1991 AD – Laki1783 AD.) / 179 = 1.15 1 subera
Only the volcanic activity of Laki 1783 AD slightly deviates from the cycle of both the lines of cycle fulfillment.
Relatinship between them:
(Katla 1625 AD. – Katla1262 AD) / 179 years = 2.02 2 suberas repeat cycle at the same time, there is an association between them.
(Laki1783 AD – Katla 1262 AD) / 179 years = 2.92 3 suberas repeat cycle at the same time, there is an association between them.
(Laki 1783 AD – Katla 1625 AD) / 179 = 0.9 1 subera repeats cycle at the same time, there is an association between them.
(Katla 1721 AD – Katla1625 AD) / 179 = 0.53 ½ subera repeats cycle at the same time, there is an association between them.
(Katla 1721 AD – Katla 1262 AD.) / 179 = 2.55 2 suberas and a half repeat cycle at the same time, there is an association between them.
Island volcanoe 2.023/4 AD and its relation with
8 maximum volcanic historical activities In Iceland
Mexico volcanic activity
Precessional relationship between the volcanic activity of Popocatépetl 2023 AD and other major historical global activities.
Vocanic activity: Volcanoe eruption Lago Toba 74,000 BC. Maximum historical event.
(74,000 BC.+ 2023 years) /25776 years or 1 Era = 2.95 Eras 3 Eras close to repeating cycle.
Precessional relationship between the volcanic activity of Popocatépetl 2023 AD and the last 2 major activities of Popocatépetl.
Activity 1927 AD
2023 AD. – 1927 AD. = 96 years
96/89.5 = 1.07 half subera 1 half subera completes cycle
Activity 1664 AD
2023 AD – 1664 AD. = 359 years
359/179 = 2.00 2 suberas completes cycle
Volcanoes eruptions registered in Japan
Precessional relationship between Sakurajima volcano and the previous 3 major recorded eruptions.
On February 14, 2024, the volcano will erupt again. The largest recorded plinian eruptions of this volcano occurred in 1471-1476 AD, 1779-1782 AD, and 1914 AD.
2024 AD.-1471 AD = 553 years
553 / 179 = 3.08 suberas 3 suberas repeat cycle
The 1471 AD eruption repeats complete cycle by 2024 AD.
1782 AD.-1471 AD.= 311 years
311 / 89 = 3.494 half suberas 3.5 half suberas repeats cycle.
The 1471 AD eruption. is related to the 1782 AD eruption in a half subera.
1914 AD. – 1476 AD = 438 years
438 / 89 = 4.92 half suberas 5 half suberas repeats half a cycle
The 1476 AD eruption is related to the 1914 AD eruption in a half subera.
