and the V-E-J Tidal Torquing model:
http://astroclimateconnection.blogspot.com.au/2012/04/why-does-solar-cycle-keep-re.html
Here is the abstract of a recent publication by
Vaquero et al. (2011) The Astrophysical Journal
REVISITED SUNSPOT DATA: A NEW SCENARIO FOR
THE ONSET OF THE MAUNDER MINIMUM
ABSTRACT
The Maunder minimum forms an archetype for the Grand
minima, and detailed knowledge of its temporal
development has important consequences for the solar
dynamo theory dealing with long-term solar activity
evolution. Here, we reconsider the current paradigm of
the Grand minimum general scenario by using newly
recovered sunspot observations by G. Marcgraf and
revising some earlier uncertain data for the period
1636-1642, i.e., one solar cycle before the beginning of
the Maunder minimum. The new and revised data
dramatically change the magnitude of the sunspot cycle
just before the Maunder minimum, from 60-70 down to
about 20, implying a possibly gradual onset of the
minimum with reduced activity started two cycles
before it. This revised scenario of the Maunder
minimum changes, through the paradigm for Grand
solar/stellar activity minima, the observational
constraint on the solar/stellar dynamo theories
focused on long-term studies and occurrence of
Grand minima.
The main result of this paper is shown in the
following figure from the paper, a summary of
which is available at:
following figure from the paper, a summary of
which is available at:
Figure 1
Figure 1 shows that Cycle -11 peaked with an annual sunspot
number in the mid 30's and lasted until at least ~ 1632
(length ~ 15 years).
In addition, it shows that with the the new results from Vaquero
et al. (2011) that cycle -10 peaked with a sunspot number of only
20 and ended in ~ 1645.
The 60 year hiatus in solar activity known as the Maunder
Minimum is normally thought to have started in 1645. However,
the paper by Vaquero et al. (2011), clearly shows that solar
activity started faltering two solar sunspot cycles earlier
than this in about 1618.
Now the question is, does the V-E-J tidal torquing model
agree with this re-interpretation of the onset of the Maunder
Minimum?
The blue curve in figures 2a and 2b, shown below, is the
time-rate of change of the gravitational force of Jupiter,
tangential to the Sun's surface, that acts upon the periodically
induced tidal bulge produced by the alignments of Venus and the
Earth every 1.599 years. The brown curve is simply the 1,2,1
binomial filtered version of the blue curve. Superimposed on
each of these figures are green vertical lines showing the dates
of solar minimum.
Figure 2a shows the period from 1590 to 1680 and figure 2b the
period from 1670 to 1750. The cycle number for each solar
sunspot cycle is displayed in each of the figures.
Note: The vertical axis is the time-rate of change of the
gravitational force of Jupiter, acting tangential to the Sun's
surface, that pulls and pushes upon the periodically induced
tidal bulge produced by the alignments of Venus and the Earth.
The units are metres per second^(2) per 1.599 years and it is
assumed that Jupiter's gravitational force is acting upon one
percent of the mass of the convective layer of the Sun
(=0.02 % of the mass of the Sun).
Figure 2a
Figure 2b
What figures 2a and 2b clearly show is that there are only two
loss of synchronization events between 1600 and 1750. The first
occurs at the first minimum for cycle -11 in 1619 and the second
occurs for the first minimum in cycle -4 in 1698.
(Note: Synchronization is regained at the next sunspot minimum
in each case.)
Amazingly, these two dates mark the start of the descent into the
Maunder Minimum in 1618, according to the modified onset
scenario of Vaquero et al. (2011), and the abrupt restart of
solar activity in 1698 with the first minimum of cycle -4.
Thus, there are now FOUR [out of a total of four] loss of
synchronization events that closely correspond to the four
most important changes in the level of sunspot activity over
the last ~ 410 years:
1618/19
First minimum of cycle -11 marking the start of the gradual
onset of the Maunder Minimum.
1698
First minimum of cycle -4 marking the end of the Maunder
Minimum or restart of the solar sunspot cycle after a
60 year hiatus.
1784.7
First minimum of cycle 4 marking the start of the Dalton
Minimum
1996.5
First minimum of cycle 23 marking the start of the next
"Dalton-like" Minimum.
This is absolutely amazing!
An interesting point to note:
The first solar minimum in the telescope era was the
first minimum for Cycle -12 starting 1610.8.
The corresponding zero acceleration was in ~ 1611.5
(a difference of 0.8 years, which is probably about the
size of the errors involved in setting the date of this
minimum)
This means that by ~ 2021 there have been 37 VEJ
cycles each of 11.07 years length.
1611.5 + (37 x 11.07) = 2021.1
Hence, if solar cycle 25 has its first minimum in the start
of 2021, it will show that solar cycle has re-synchronized
itself to a 11.07 year period VEJ cycle over a ~ 410 year
period.
If the first minimum of cycle 25 occurs in the start of
2019, it will show that solar cycle has re-synchronized
itself to a 11.02 year period VEJ cycle over a ~ 410 year
period, since:
1611.5 + (37 x 11.02) = 2019.24
If the first minimum of cycle 25 occurs at the beginning
of 2023, it will show that solar cycle has re-synchronized
itself to a 11.12 year period VEJ cycle over a ~ 410 year
period, since:
1611.5 + (37 x 11.12) = 2022.94
Thus, a first minimum for SC 25 that occurs
between 2019.24 and 2022.94 (i.e. ~ 2021
+/- 2 years) will indicate a re-synchronization
to a VEJ cycle length of 11.07 +/- 0.05 years
over a 410 year period.
tangential to the Sun's surface, that acts upon the periodically
induced tidal bulge produced by the alignments of Venus and the
Earth every 1.599 years. The brown curve is simply the 1,2,1
binomial filtered version of the blue curve. Superimposed on
each of these figures are green vertical lines showing the dates
of solar minimum.
Figure 2a shows the period from 1590 to 1680 and figure 2b the
period from 1670 to 1750. The cycle number for each solar
sunspot cycle is displayed in each of the figures.
Note: The vertical axis is the time-rate of change of the
gravitational force of Jupiter, acting tangential to the Sun's
surface, that pulls and pushes upon the periodically induced
tidal bulge produced by the alignments of Venus and the Earth.
The units are metres per second^(2) per 1.599 years and it is
assumed that Jupiter's gravitational force is acting upon one
percent of the mass of the convective layer of the Sun
(=0.02 % of the mass of the Sun).
Figure 2a
Figure 2b
loss of synchronization events between 1600 and 1750. The first
occurs at the first minimum for cycle -11 in 1619 and the second
occurs for the first minimum in cycle -4 in 1698.
(Note: Synchronization is regained at the next sunspot minimum
in each case.)
Amazingly, these two dates mark the start of the descent into the
Maunder Minimum in 1618, according to the modified onset
scenario of Vaquero et al. (2011), and the abrupt restart of
solar activity in 1698 with the first minimum of cycle -4.
Thus, there are now FOUR [out of a total of four] loss of
synchronization events that closely correspond to the four
most important changes in the level of sunspot activity over
the last ~ 410 years:
1618/19
First minimum of cycle -11 marking the start of the gradual
onset of the Maunder Minimum.
1698
First minimum of cycle -4 marking the end of the Maunder
Minimum or restart of the solar sunspot cycle after a
60 year hiatus.
1784.7
First minimum of cycle 4 marking the start of the Dalton
Minimum
1996.5
First minimum of cycle 23 marking the start of the next
"Dalton-like" Minimum.
This is absolutely amazing!
An interesting point to note:
The first solar minimum in the telescope era was the
first minimum for Cycle -12 starting 1610.8.
The corresponding zero acceleration was in ~ 1611.5
(a difference of 0.8 years, which is probably about the
size of the errors involved in setting the date of this
minimum)
This means that by ~ 2021 there have been 37 VEJ
cycles each of 11.07 years length.
1611.5 + (37 x 11.07) = 2021.1
Hence, if solar cycle 25 has its first minimum in the start
of 2021, it will show that solar cycle has re-synchronized
itself to a 11.07 year period VEJ cycle over a ~ 410 year
period.
If the first minimum of cycle 25 occurs in the start of
2019, it will show that solar cycle has re-synchronized
itself to a 11.02 year period VEJ cycle over a ~ 410 year
period, since:
1611.5 + (37 x 11.02) = 2019.24
If the first minimum of cycle 25 occurs at the beginning
of 2023, it will show that solar cycle has re-synchronized
itself to a 11.12 year period VEJ cycle over a ~ 410 year
period, since:
1611.5 + (37 x 11.12) = 2022.94
Thus, a first minimum for SC 25 that occurs
between 2019.24 and 2022.94 (i.e. ~ 2021
+/- 2 years) will indicate a re-synchronization
to a VEJ cycle length of 11.07 +/- 0.05 years
over a 410 year period.
Amazing it is. So what is causing this loss of synchronization, they happen to coincide almost exactly with the green arrows on Carl's graph (1610 is shown on another graph)
ReplyDeletehttp://www.landscheidt.info/images/sunssbam1620to2180gs.jpg
The Vaquero et al paper is significant and now backs up the 14C record for a solar slow down at 1610.
http://www.landscheidt.info/images/Newc14.jpg
There is a combination of tidal and AM effects happening I believe. AM influencing grand minima and overall modulation and perhaps tidal forces for cycle length. These are only my views of course.
Geoff,
ReplyDeleteA small correction, so that others don't get the wrong idea.
The model I am proposing is driven by Jupiter's gravitational force, not its tidal force. It is Jupiter's gravitational force that acts upon the asymmetry formed the periodically tidal bulges of Venus and the Earth.
I have to admit that I am not sure how
the Jovian AM influences the timing grand minima but the evidence you present at your site conclusively shows that it somehow involved.
bulge