Variations in the Polar Jet Stream directly affect weather across Europe and North America (Francis et al., 2012). Jet Stream
dynamics are governed by the development of planetary Rossby waves (Dickinson, 1978) driven by variation of the Coriolis force
with latitude. Here we show that increasing atmospheric tides induce the development of Rossby waves, especially during winter
months. This changes the flow and direction of the Jet Stream, as measured by the Arctic Oscillation (AO). Although horizontal
tidal forces are tiny (10
Varying tidal forces act both on the oceans and atmosphere particularly at high latitudes. A detailed study (Lindzen, 1981) of atmospheric tides finds that gravitational lunar tidal winds are more important at high altitudes. The horizontal “tractional” component of net tides is responsible for tidal currents in the ocean and for tidal winds in the upper atmosphere. During northern winters the Jet Stream strengthens and shifts northwards. Meanders or Rossby waves (Dickinson, 1978) develop near the eastern edges of continental landmasses and oceans. Solar insolation falls each winter to zero inside the Arctic Circle while simultaneously the diurnal solar “expansion” tide disappears over Polar Regions. Gravitational atmospheric tides now dominate near the poles.
Winter storms in the North Atlantic form at the interface where warm Gulf air meets cold Polar air near Newfoundland. This temperature gradient produces baroclinic instability spawning storms that move westward across the Atlantic. The track of these storms follows the Jet Stream and their impact on Europe depends both on their strength and the relative position of the Jet Stream (Francis, 2012). Previous studies (Currie, 1983, 1984; Agosta, 2014; Clegg, 1984) have shown an 18.6 year cycle in rainfall across large continental zones implying a dependence of storm formation on the lunar precession. Others have speculated about a tidal influence on climate over decadal timescales (Ray, 2007). Changes in lunar declination through the 18.6 year cycle mainly affect the strength and sidereal rate of change of tidal forces with latitude.
The cold winter of 2010 corresponded to a Jet Stream positioned lower over the UK drawing cold air down from the North and East. A negative value of the Arctic Oscillation (Thompson, 1998) corresponds to a low-pressure difference between the Icelandic Low and the Azores High resulting in a weaker Jet Stream with larger meandering loops. This allows cold air to spill down from the Arctic and Siberia into mid latitudes. During the winter of 2013/2014 a strong Jet Stream was positioned directly over the UK and a string of powerful storms caused extensive coastal flooding. It was striking how several of these storms also coincided with high spring tides, for example those of 5 December 2013 and 5 January 2014.
It is the horizontal (tractional) component of tides that produces deep ocean currents and atmospheric pressure gradients in the
atmosphere. Can these also affect the Jet Stream flow? To investigate this possibility further, we have calculated the time
dependence of tractional tidal forces acting at different latitudes using the JPL ephemeris (Standish, 1990). During northern
winters the maxima of such forces occur at each new moon and their strength depends on the relative positions of the earth, moon
and sun. Although these tractional forces are only about 10
Figure 1 shows the variation of the AO index compared to calculations of the tidal tractional forces acting at 60 and
45
To investigate further, we also looked at the recent maximum lunar standstill, which occurred in 2005/06 and resulted in the
largest monthly variations of tidal forces for Polar regions. If tractional tides affect the Jet Stream flow one would expect to
see a maximum correlation between AO and tidal forces during the 2005/06 winter months. Figure 2a shows the result. There are
indeed large swings in the AO, which are again anti-correlated with tractional tidal forces. In particular the coincidence with
the 45
A large negative swing in the AO occurred in coincidence with the 2015 eclipse, with a regular anti-correlated beat beforehand. A very similar situation can be observed for the total eclipse, which occurred on 7 March 1970, and which also happened to be near a lunar standstill (Fig. 2c). The effect is even more striking.
How statistically significant are these observations? Firstly a cross-correlation analysis was performed between all daily AO
values, from 1950 to 2015, and the calculated tractional tidal acceleration at latitudes 45 and 60
As a second test, we analysed just the lunar cycles between December and the end of March for the 8 most recent winters presented
in Figs. 1 and 2. Some 40 out of 46 lunar cycles show a visible anti-correlation of the AO with tidal traction. Maxima in tidal
traction consistently shift the AO towards negative values, which then relax during tidal minima. The probability of such a run of
40/46 lunar cycles occurring randomly is
The evolution of the Jet Stream and generation of Rossby waves is an immensely complicated process. Winter weather in the Northern Hemisphere is dominated by the strength and flow direction of the Jet Stream. The intensity of flow varies from one year to another. The Arctic Oscillation is just one scalar measurement of this evolution. Despite this, we have demonstrated that there is strong statistical evidence of a sidereal tidal effect on the AO, especially during winter months. Strong tides increase the southward drag on the Jet Stream generating a Coriolis torque as the tides sweep east–west around the rotating earth, perhaps playing a role in triggering storms. It is noticeable how many of the damaging UK winter storms of 2013/2014 also coincided with high spring tides. The total effect depends both on the maxima and on the rate of change of the tractional tidal component. These both vary within the 18.6 year lunar cycle. The work reported here provides strong evidence that increasing tractional tidal forces do change the direction and speed of the Jet Stream, especially during winter months with a lag time of about 5 days. One of the authors has been using tidal variations combined with ECMWF (2013) models to improve short to medium-term weather forecasting (Madrigali, 2013). It is therefore proposed that the accuracy of medium-range weather forecasting would be improved by including quantitative gravitational tidal forcing on the Polar Jet Stream into Global Circulation Models.
The tractional (tangential) tidal force at any point
The net force per unit mass acting on point
The distance
Calculations by C. H. Best 2015.
Comparison of the Arctic Oscillation (AO) with tractional
tidal forces acting at
60
Cross-correlation of the Arctic Oscillation with tractional Tidal
acceleration since 1950. The green values are for the tractional
acceleration at 45
Schematic of the Earth-Moon system.
Evaluation of angle