Mimsey Borogrove
Crusader
Mike - in the attached paper, it demonstrates an relationship between solar activity and the speed of rotation of the earth. There are three things about this micro nova theory that could cause a climate change here on earth.
1) the rate the planet's rotation could change drastically in such a vast magnetic / solar wind / CME out burst scenario - even if short lived.
2) the vast amount of cosmic radiation entering our planet's atmosphere would overwhelm the geomagnetic field, resulting in a very thick cloud cover and it's albedo effect.
3) if there is a solar ejection of a vast dust cloud, it could remain in our atmosphere for centuries. Dust from volcanos has been shown to affect climate. See link about the year without a summer or google it. https://en.wikipedia.org/wiki/Year_Without_a_Summer
In the below graph you see this recurring pattern - a spike in temperature, followed by a rhythmic cooling off as the temperature drops 10 degrees Celsius (about 20 degrees Fahrenheit) before the whole cycle repeats. If there were a significanti solar nova that overheated the oceans, evaporating them on a massive scale, and followed by the dust, torrential rain and snow falls after resulting cloud / dust cover that built up the polar icepack, it could easily explain the recurring ice ages. We are at the start of a cooling off period. This cyclic co2 / temperature fluctuation is likely to be mostly unaffected by manmade emissions.
The hypothesis that is being bandied about recently, is that there is a shorter, cyclic mini, albeit less potent than the above larger cycle, nova scenario. In this graph which corresponds to our current climate, there's a spike in temperature, followed by a crash. What could cause such a variation if not from the sun? Inter stellar dust clouds? Nearby supernova? There is a vast trove of data showing the relationship between solar output and weather. It seems obvious where to look.
By the way - the infamous hockey stick of manmade co2 emissions is that tiny uptick at the far right of the graph - as you can plainly see, the earth was much hotter in the previous centuries than now.
Mimsey
Title:
Sunspot activity, solar wind, Earth's rotation and climate on a decadal time-scale
Authors:
Mörner, N.-A.
Publication:
EGS - AGU - EUG Joint Assembly, Abstracts from the meeting held in Nice, France, 6 - 11 April 2003, abstract id. 9579
Publication Date:
04/2003
Origin:
EGU
Bibliographic Code:
2003EAEJA.....9579M
Abstract
The Spörer, Maunder and Dalton Minima correlate reasonably well with observed periods of cold climate in the years 1440-1460, 1687-1703 and 1808-182. Therefore, a causal connection has been proposed. From the mode of changes in ocean surface circulation in the North Atlantic, two facts are established; viz. (1) that the recorded cold periods in western Europe, primarily, are driven by changes in ocean circulation (interchange of angular momentum between the solid Earth and the hydrosphere), and (2) that all the three periods of cooling represent periods when Earth’s rotation experienced a speeding-up (increased rate of rotation and decreased LOD). Sunspot activity and LOD express a good correlation when plotted against each other. This suggests (or indicates) that variations in the Solar Wind strength affect the Earth’s rate of rotation, which in its turn affects the oceanic and atmospheric circulation. The oceans being the Earth’s greatest store of heat has a vital impact on the redistribution of heat via changes in the ocean surface circulation. The Gulf Stream and the Kurishio Current, both bringing hot equatorial water to middle and high latitudes, have a central role in redistribution of heat and oceanic water masses (controlling the interchange of angular momentum). Similarly, the Humboldt Current play a central role in bringing cold low-latitude water up along the South American coast in ENSO and super-ENSO variability. In conclusion, there seems to be a strong causal chain-relation between sunspot activity, solar wind strength, Earth’s rate of rotation, oceanic surface circulation and regional climatic changes on a decadal time-scale.
http://adsabs.harvard.edu/abs/2003EAEJA.....9579M
1) the rate the planet's rotation could change drastically in such a vast magnetic / solar wind / CME out burst scenario - even if short lived.
2) the vast amount of cosmic radiation entering our planet's atmosphere would overwhelm the geomagnetic field, resulting in a very thick cloud cover and it's albedo effect.
3) if there is a solar ejection of a vast dust cloud, it could remain in our atmosphere for centuries. Dust from volcanos has been shown to affect climate. See link about the year without a summer or google it. https://en.wikipedia.org/wiki/Year_Without_a_Summer
In the below graph you see this recurring pattern - a spike in temperature, followed by a rhythmic cooling off as the temperature drops 10 degrees Celsius (about 20 degrees Fahrenheit) before the whole cycle repeats. If there were a significanti solar nova that overheated the oceans, evaporating them on a massive scale, and followed by the dust, torrential rain and snow falls after resulting cloud / dust cover that built up the polar icepack, it could easily explain the recurring ice ages. We are at the start of a cooling off period. This cyclic co2 / temperature fluctuation is likely to be mostly unaffected by manmade emissions.
The hypothesis that is being bandied about recently, is that there is a shorter, cyclic mini, albeit less potent than the above larger cycle, nova scenario. In this graph which corresponds to our current climate, there's a spike in temperature, followed by a crash. What could cause such a variation if not from the sun? Inter stellar dust clouds? Nearby supernova? There is a vast trove of data showing the relationship between solar output and weather. It seems obvious where to look.
By the way - the infamous hockey stick of manmade co2 emissions is that tiny uptick at the far right of the graph - as you can plainly see, the earth was much hotter in the previous centuries than now.
Mimsey
Title:
Sunspot activity, solar wind, Earth's rotation and climate on a decadal time-scale
Authors:
Mörner, N.-A.
Publication:
EGS - AGU - EUG Joint Assembly, Abstracts from the meeting held in Nice, France, 6 - 11 April 2003, abstract id. 9579
Publication Date:
04/2003
Origin:
EGU
Bibliographic Code:
2003EAEJA.....9579M
Abstract
The Spörer, Maunder and Dalton Minima correlate reasonably well with observed periods of cold climate in the years 1440-1460, 1687-1703 and 1808-182. Therefore, a causal connection has been proposed. From the mode of changes in ocean surface circulation in the North Atlantic, two facts are established; viz. (1) that the recorded cold periods in western Europe, primarily, are driven by changes in ocean circulation (interchange of angular momentum between the solid Earth and the hydrosphere), and (2) that all the three periods of cooling represent periods when Earth’s rotation experienced a speeding-up (increased rate of rotation and decreased LOD). Sunspot activity and LOD express a good correlation when plotted against each other. This suggests (or indicates) that variations in the Solar Wind strength affect the Earth’s rate of rotation, which in its turn affects the oceanic and atmospheric circulation. The oceans being the Earth’s greatest store of heat has a vital impact on the redistribution of heat via changes in the ocean surface circulation. The Gulf Stream and the Kurishio Current, both bringing hot equatorial water to middle and high latitudes, have a central role in redistribution of heat and oceanic water masses (controlling the interchange of angular momentum). Similarly, the Humboldt Current play a central role in bringing cold low-latitude water up along the South American coast in ENSO and super-ENSO variability. In conclusion, there seems to be a strong causal chain-relation between sunspot activity, solar wind strength, Earth’s rate of rotation, oceanic surface circulation and regional climatic changes on a decadal time-scale.
http://adsabs.harvard.edu/abs/2003EAEJA.....9579M
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