Thursday, March 24, 2016

There is a natural Gleissberg-like Cycle in the Lunar tidal stresses placed upon the Earth

Preamble

1. There is a lunar tidal cycle that synchronizes the slow precession of the lunar line-of-apse with the seasons and the Synodic cycle (i.e. the Moon's phases). 

The tidal cycle is called the 31/62 year Perigee-Syzygy Cycle. This tidal cycle is the time required for a full (or new moon) at Perigee to re-occur at or very near to the same point in the seasonal calendar.

It is highly recommended that readers go to the following link to get a fuller understanding of the parameters that are used to define the lunar orbit as well a better understanding of the 31/62 year Perigee-Syzygy tidal cycle, before proceeding with this post.

II. Seasonal Peak Tides - The 31/62 year Perigee-Syzygy  Tidal Cycle.

2. The current post needs to be read in the light of the fact that a previous post at:


claimed that:

El Niño events in New Moon epochs preferentially occur near times when the lunar line-of-apse aligns with the Sun at the times of the Solstices..

El Niño events in the Full Moon epochs preferentially occur near times when the lunar line-of-apse aligns with the Sun at the times of the Equinoxes. 

CURRENT POST

The Changing Aspect of the Lunar Orbit & its Impact Upon the Earth's Length of Day.

a. Inter-Annual Changes in the Earth's LOD

The blue curves in figures 1a, 1b, and 1c (below) show the Earth's LOD over a six year period from January 1966 through to December 1971.  These plots use daily LOD values that are available online from the International Rotation and Earth Reference System Service (IERS) covering the period from January 1962 until the present.


1a   LOD - 1966 to 1968


















1b   LOD – 1968 to 1970


















1c   LOD – 1970 to 1972


















It is evident from these three figures that there are abrupt periodic slow downs in the Earth's rotation rate (corresponding to an increase in LOD ~ 1 msec) once every 13.66 days (blue curve)* that are accompanied by much smoother longer-term changes in LOD that are associated with the annual seasonal cycle (red curves).

The smoother longer-term seasonal variations in LOD are primarily the result of changes in the angular momentum of the Earth that are a response to the slow (north-south) seasonal movement of the Earth's atmosphere and its wind patterns.

The green LOD curve is a crude seasonally de-trended version of the blue LOD curve.

[Note: Half of a lunar tropical month = 27.32158 /2 = 13.66079 days.*]

b. Reason for the Peaks in the Earth's LOD

A more detailed investigation show that the spikes in LOD (in the blue and green curves) occur
within a day or two of the time that the Moon crosses the Earth's Equator.

This tells you that the slow down in the rotation rate is a direct result of the lunar tidal bulge in the
Earth's oceans (and atmosphere) passing across the Earth's Equator.

The slow down occurs for much the same reason that a twirling ice-skater slows down their rate of
spin by extending their arms i.e. by the conservation of angular momentum.















c. The Change in the Ratio of Consecutive Peaks in LOD


In early 1966 (figure 1a) the peaks in LOD associated with transits of the Moon across 
the Equator from the northern to the southern hemisphere, are roughly twice as large
as the next peaks in LOD (13.66 days later) that are associated with transits of the
Moon across the Equator from the southern to the northern hemisphere.

By early 1969 (figure 1b), the consecutive peaks in LOD are almost equal in size

By late 1971 (figure 1c), the peaks in LOD that are associated with transits of the
Moon across the Equator from the southern to the northern hemisphere, are
roughly twice as large as the next peaks in LOD (13.66 days later) that are associated
with transits of the Moon across the Equator from the northern to the southern
hemisphere.

2. 



Figure 2 shows that the absolute size of the slow down in the Earth’s rotation rate is
determined by the proximity of the Moon as its crosses the Earth’s Equator 

3.


















Figure 3 shows the ratio of consecutive peaks in LOD versus lunar distance (in kilometres) for the
numerator of the ratio, for the years from 1966 to 1971.

Figures 2 and 3 indicate that:

Whenever the ratio of consecutive peaks in LOD is close to 1.0, the distance of the
Moon from the Earth at consecutive transit crossings of the Equator are close to the
Moon's average distance from the Earth of approximately 380,000 km.

However, whenever the ratio of consecutive peaks in LOD is far from 1.0 (i.e. either
2.0 or 0.5), the distance of the Moon from the Earth at one transit crossing is at the
distance of closest approach (i.e. the distance of lunar perigee = 356,000 km), and the
distance of the Moon at the other transit crossing is at its furthest from the Earth
(i.e. the distance of lunar apogee = 407,000 km).

4. 



Figure 4 shows the difference in lunar distance for consecutive transits of the Earth’s
Equator from 1962 to 1976.

Figure 4 confirms that whenever the perigee of the lunar orbit is pointed at Sun at the time of the
Summer or Winter solstices, the difference in lunar distance for consecutive transits of the Earth’s
equator is near zero kilometres i.e. the ratio of consecutive peaks in LOD are ~ 1.0 because the lunar
 distances at consecutive crossings are both close to the average lunar distance of 380,000 km

Similarly, figure 4 confirms that whenever the perigee of the lunar orbit is pointed at Sun at the time
of the Vernal or Autumnal equinoxes, the difference in lunar distance for consecutive transits of the
Earth’s equator approaches the maximum 50,000 km i.e. the ratio of consecutive peaks in LOD are
far from 1.0 because the Moon is near perigee and apogee at consecutive crossings.

d. Reason for the Change in the Ratio of Consecutive Peaks.

5. Lunar Perigee pointing at the Sun near Summer or Winter Solstices



























The yellow tilted elliptical orbits in figure 5 above, represent the apparent movement of the Sun about
the sky as seen from the Earth. The Sun takes a full tropical year (365.242189 days) to move once
about the yellow orbit, crossing the Earth’s equatorial plane (the grey plane) once every
six months at the Spring and Autumnal (Fall) equinox, respectively.

The red tilted elliptical orbits above, represent the apparent movement of the Moon about the sky
as seen from the Earth. The Moon takes a full tropical month (27.32158 days) to move once about
the red orbit, crossing the Earth’s equatorial plane roughly once every 13.66 days where the red
orbit crosses the black line [N.B. the ~ 5 degree tilt of the lunar orbit with respect to the ecliptic is
ignored as a second order effect at this stage of the argument.] 

Clearly, if the perigee of the lunar orbit points at the Sun at either the Winter (i.e. the top diagram)
or Summer Solstice (i.e. the bottom diagram), the Moon will be roughly at or near its average
distance from the Earth (i.e. ~ 380,000 km). This means that when it crosses the Earth’s equatorial
plane at consecutive transits of the Equator (i.e. the intersection of the red orbit and the black line),
the difference in lunar distance for consecutive transits will approach zero (i.e. the ratio of
consecutive peaks in LOD will be close to 1.0) 

6. Lunar Perigee pointing at the Sun near Vernal or Autumnal Equinox


   






















The yellow tilted elliptical orbits in figure 6 above represent the apparent movement of the Sun about
the sky as seen from the Earth. The Sun takes a full tropical year (365.242189 days) to move once
about the yellow orbit, crossing the Earth’s equatorial plane (the grey plane) once every six
months at the Spring and Autumnal (Fall) equinox, respectively.

The red tilted elliptical orbits above, represent the apparent movement of the Moon about the sky
as seen from the Earth. The Moon takes a full tropical month (27.32158 days) to move once about
the red orbit, crossing the Earth’s equatorial plane roughly once every 13.66 days where the red
orbit crosses the black line.

Clearly, if the perigee of the lunar orbit points at the Sun at either the Vernal (i.e. the bottom
diagram) or Autumnal Equinox (i.e. the top diagram), the Moon will be at or near perigee and apogee
at consecutive transits of the equatorial plane (i.e. where the red orbit crosses the black line).

This means that when it crosses the Earth’s equatorial plane at consecutive transits, the difference in
lunar distance for consecutive transits will approach its maximum value of 50,000 km (i.e. the ratio
of consecutive peaks in LOD will be as far from 1.0 as possible).

Hence, figure 4 tells us that the perigee moves from pointing at the Sun at a Solstice(/Equinox)
to pointing at the Sun at the following Equinox(/Solstice) in the seasonal calendar once every  
2.0 Full Moon Cycles (FMC) = 2.0 x 411.78444836 days 2.2547695 sidereal years = 2.2548570
tropical years

e. The 9.019 Tropical Year Cycle

7. 


















Figure 7 shows the ratio of the consecutive 13.66 day peaks in LOD from 1962 to 1988.

It is evident from this plot that the long-term variation in the ratio of consecutive peaks is dominated
by a periodicity of ~ 9.0 years. In addition, there is an approximate 18.0 year periodicity that
modulates the ~ 9 year periodicity.  

The 9.0 periodicity results from the fact that 4.0 x 2 FMC = 9.019428 tropical years  is the
time required for slowly drifting perigee of the lunar orbit to return to pointing at the Sun at the same
Solstice or Equinox (since it takes 2.2548570 topical years for the alignment of the perigee with the
Sun at a Solstice/Equinox to move to the following Equinox/Solstice in the seasonal calendar.

(N.B. The ~  9.0 period is close to but not necessarily the same as the 8.85 years that it takes the
lunar line-of-apse to precess once around the Earth with respect to the star. In addition, the
~ 18.0 periodic modulation of the 9.0 year period is close to but not necessarily the same as the 18.6
year period that it takes the lunar line-of-nodes to precess once around the Earth with respect to the
stars. The 18.6 year period is caused by the slowly changing tilt of the Moon’s orbit with respect to
the Earth’s equator caused by precession of the lunar-line-of-nodes - Please see the Addendum at the
end of this post about the possible long-term interaction of these two lunar cycles).

f. A Gleissberg Cycle in the Ratio of Consecutive Peaks in LOD.

The slow pro-grade precession of the perigee of the lunar orbit through the seasonal calendar leads to
the perigee moving from pointing at the Sun at one Solstice(/Equinox) to pointing at the Sun at the
following Equinox(/Solstice) once every 2.0 Full Moon Cycles (FMC) = 2.0 x 411.78445750
days = 2.2547695 sidereal years2.2548570 topical years.

However, since 2.0 FMC is longer than 2.00 sidereal years (by 0.2547695 sidereal years), the perigee
of the lunar orbit will slowly drift from pointing at the Sun at a given point in the seasonal calendar,
only re-synchronizing with the seasonal calendar after:
  
(2.0000000 x 2.2547695) / (2.2547695 - 2.0000000) 17.70046823 sidereal years 

This comes about because there are 8.850234 lots of 2.00 sidereal year cycles in 17.70046823
sidereal years and 7.850234 lots of 2.2547695 sidereal year cycles in 17.70046823 sidereal years.

In effect, what this means is that there will be a precise realignment between when the lunar perigee
points at the Sun at a given Solstice/Equinox and when it does so again at the same point in the
seasonal calendar (i.e. the same Solstice/Equinox), once every 354.000 years:    

157 x 2.0 FMC = 353.9988071 354.00 sidereal years

Of course, it would take half of this time i.e. 177.0 sidereal years, if we broaden our criterion to
include the cases where the lunar Perigee points directly away from the Sun:

157 x 1.0 FMC = 176.9999404 ≈  177.000 sidereal years

And it would take half of this time again i.e. 88.5 years, if we only make the constraint that the
Perigee of the lunar orbit move from one Solstice/Equinox to the next, rather than go through the full
seasonal calendar:

157 x 0.5 FMC = 88.499702 ≈  88.500 sidereal years 

Hence, the long-term variations of the ratio of the strength of the consecutive (13.66 day) slow
downs in the Earth’s LOD that are caused by the Moon transiting across the Earth’s Equator,
have a natural long term repetition cycle with respect to the seasons that matches that of the:

88 year Gleissberg Cycle 


~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Addendum 1 - A Possible 2340 Year Hallstatt-like Cycle 

In this blog post we have established that there is a quasi 9.0 year periodicity in the ratio of
consecutive increases in the Earth’s LOD that result from transits of the Moon across the Earth’s
Equatorial plane every 13.66 days.

There is a possibility that the quasi 9.0 periodicity could be the harmonic mean of the two factors in
figure 7 that are influencing the long-term variations in the ratio of consecutive increases in the
Earth’s LOD  i.e. the 8.8505 tropical year precession of the lunar line-of-apse (i.e. the Lunar
Anomalistic Cycle - LAC) and the 9.3001 (= 18.6002/2.0) tropical year half cycle for the precession
of the lunar-line of nodes (i.e. the half Lunar Nodical Cycle - LNC) such that:

2.0 x (9.3001 x 8.8505) / (9.3001 + 8.8505) = 9.0697(3) tropical years

Since 9.0697(3) tropical years is slightly longer than 9.00 tropical years, it slowly drifts by 0.0697(3)
tropical years once every 9.06973 years, resulting in a forward shift by
one full tropical year once every:

9.06973 / (9.06973 9.00000) 9.06973 / 0.06973 ≈ 130.069267 tropical years

In addition, the beat period between 9.0697(3) tropical year and 9.00000 tropical year gives:

9.00 x 9.06973 / (9.06973 – 9.00) = 1170.623 tropical year  ≈  9.0 x 130.069267 tropical years

Which is half of a Hallstatt-like cycle of 2341.247 tropical years. 

Hence, the interaction between the LAC with LNC naturally produces a Hallstatt-like cycle.

Addendum 2 - Some More Information on the 31 Year Perigee-Syzygy Lunar Tidal Cycle

A1

















Figure A1 shows the offset in days from a New/Full Moon at each instant where the Perigee of the
lunar orbit points either towards or away from the Sun - up to 27.5 FMC = 31.00308 sidereal years.
This figure shows us that phase of the Moon goes from:

New --- Full --- New --- Full    every

0.0 --- 9.00 --- 18.00 --- 27.00 FMC's

0.0 --- 10.146463 --- 20.292925 --- 30.439388 sidereal years

with the Moon being less than one day past Full Moon at 27.5 FMC = 31.00308 sidereal years.

A2

















Figure A2 shows the offset of the Moon from the lunar line-of-apse at each instant where the Perigee
of the lunar orbit points either towards or away from the the Sun - up to 27.5 FMC = 31.00308
sidereal years (N.B. the Perigee alternates between point directly at the Sun to pointing directly away
from the Sun once every 0.5 FMC).

Hence

New Perigee --- Full Apogee --- New Perigee --- Full Apogee    every

0.0 --- 9.00 --- 18.00 --- 27.00 FMC's

0.0 --- 10.146463 --- 20.292925 --- 30.439388 sidereal years

with the Moon returning to perigee, less than one day past Full Moon, at 27.5 FMC = 31.00308
sidereal years.

7 comments:

  1. Ian, you couldn't have made it any more clear. This work you have done on LOD and on the moons position with respect to El NINO is excellence in science.
    As I stated on the Tallbloke blog, I can pass a curve through NOAA El NINO data but I have no confidence in an extension of the curve. And I had to modulate the phasing of the base frequencies with 2 times the VEJ and the Jupiter/Saturn axial.
    You may find the base frequencies interesting and I list them below:
    Years
    1.50994
    2.12028
    2.56617
    2.79465
    3.45452
    4.91751
    6.62037
    12.8152
    They may suggest frequencies to you that are close to these that have physical meaning.

    ReplyDelete
    Replies
    1. In reply to RJ Salvador, So I take it that your extrapolated fit to ENSO for the 70 years prior to 1950 is poor?

      Delete
    2. Yes. I started with frequencies from an analysis in an article by Theodor Landscheidt. I let them float and the fit was still very poor. As the LOD is most likely a main factor in El NINO formation and the LOD model is in part essentially four lunar and two earth frequencies riding on the 2xVEJ and JS axial frequency curve, I modulated the phases of the base frequencies with these two. The fit immediately locked with r^2=0.82. But this model is still missing something and is too sensitive. It needs a re-think.

      Delete
    3. It will be great if someone can formulate a deterministic non-chaotic fit to ENSO. Then one of the largest natural contributors to the global surface temperature time-series can be compensated for, and the enormous secular contribution of aCO2 to the rising trend can be more clearly accounted for.

      Delete
  2. Whut - Amen! Except I would say "...and the minor secular contribution of aCO2 to the future, as yet unknown, trend [in global mean temperature] can be more clearly accounted for."

    ReplyDelete
    Replies
    1. When I say "enormous secular contribution", I don't necessarily mean in scale, but in proportion. From my work using the CSALT model, the contribution from "effective" CO2 (i.e. CO2 plus other GHGs and H20 feedback) is at least 90% of the rising trend.

      I rarely comment on the scale aspect of AGW, because a more existential issue is the decline of the once plentiful crude oil supply. There is no getting around that one.

      What I am doing is gap analysis -- filling in the details on the general consensus, stuff that no one else seems to want to do.

      Delete
  3. This comment has been removed by the author.

    ReplyDelete