Scientific Capstone Project
Growing Bores at the South Pole
Mikaela Ashcroft
Physics 4900
Utah State University
May 1, 2017
Abstract: Bores in the South Pole have been monitored for over ten years, and, until the year
2012, they were found to be relatively rare. Bores start with relatively large intensity and develop
additional waves behind them depending on their movement and stability. The data from the South
Pole was gathered from the US Admundsen-Scott South Pole station. A photo was taken every 30
seconds from the months of April to August with a wide-angled lens. The data was then processed
and analyzed in multiple programs to determine wavelength, duration of event, relative velocity
over time, and direction of propagation. Studies over the recent years of- have shown a
total of 130 total bore events. The last 47 events are the subject for this paper, with additional data
from previous reports.
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Introduction:
Bores have been observed both in our
atmosphere and in oceans and river outlets.
Tidal bores act in response to the tide coming
in and overcoming the current, as can be seen
in Figure 1. Lord Rayleigh, a scientist
vibrate due to gravity waves. Gravity waves,
or more commonly known as acoustic gravity
waves, form through the vertical movement
of air. When an air pocket is moved by these
gravity waves, it forms a bore: “It is now
known that bands are caused by gravity
waves originated from the lower atmosphere,
and ripples are generated in situ by
convective
or dynamical instabilities ”
(Taylor 1). These ripples in the atmosphere
are visible in the airglow of our atmosphere,
as seen in Figure 3. This airglow is typically
found ~85 to ~100 kilometers above the
surface and is composed of OH and O2
respectively.
Figure 1: The tidal bore shows a leading wave with
additional waves following. These waves are large enough
that surfers ride these waves. Retrieved from Dickerson, S.
(2016, August 8). Beachapedia. Retrieved April 17, 2017,
from http://www.beachapedia.org/Tidal
observed effects of river bores from
horseback, drew a diagram of these bores. As
the tide pulls a wave, a pocket is formed
underneath the cresting wave. This wave,
also known as a tidal bore, creates additiona l
waves behind it. This cresting wave is shown
in Figure 2.
Figure 2: A diagram drawn by Lord Rayleigh in
response to his discovery of a tidal bore in 1908. The
velocity, given by u shows the velocity moving from left
to right. u' shows the velocity moving just right of the
wave crest. l represents the height of the wave before
the crest, and l ’ represents the height as the tide comes
in. Retrieved from
Atmospheric bores, or undular bores, are
likewise created by pockets of air. These
bores studied for this research are formed in
the upper atmosphere through air pockets that
Figure 3: An image of airglow taken from an orbiting
satellite. The green rim around the Earth shows a rim of
airglow, a layer of 𝑂2 and OH with an altitude approximate
to the mesosphere and lower thermosphere.
Bores usually change slightly in temperature
as they propagate. Each wave has a peak and
trough, where the higher intensity wave-front
is higher in temperature than its trough. This
is because of the changes in air pressure.
Because of this, atmospheric bores are
sometimes confused with cold fronts, though
there is no definitive research suggesting that
bores change the overall temperature of the
atmosphere (Davies, et al. 439). It is usually
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the result of a change in temperature that
triggers a bore. In Australia, the presence of
bores created a spike in the burning of
brushfires. This peak occurred early in the
morning, which accounts for another name of
the phenomenon: Morning Glory (Davies, et
al. 440). Atmospheric bores off a bay can be
seen in Figure 4.
Figure 4: Atmospheric bore created through gravity waves.
As the waves progress, a high build-up of pressure forms a
crest and a lowering of pressure following causes a trough.
Retrieved from: Lutzak, P. (2010, May). An Atmospheric
Bore from Oklahoma to Mississippi, April 30, 2010.
Retrieved April 17, 2017.
Since 1995 when Taylor et al. observed one
of the first mesospheric bores during the
Observations of the Hawaiian Airglow 1993
(ALOHA-93) campaign, bores have been
sought after and analyzed. Few had been
observed from that point, however, and they
were considered to be rare.
Methods:
Before 2006, only one bore event had been
witnessed in the South Pole. Since then, an
observation location in the South Pole has
been erected to view additional phenomena.
Information from the Admundsen-Scott
South Pole station observed the mesosphere
and lower thermosphere (~80 – 100km), the
highest layers of our atmosphere. The
program used was an advanced mesospheric
temperature mapper (AMTM) with a field of
view (FOV) of 144km by 180km. Images
were recorded every 30 seconds from midApril through August-. Christina
Solorio analyzed data from 2012 – 2014. The
rest was analyzed for this report. These
winter months provided relative darkness for
the atmospheric bore study.
Images were taken from the Bear Lake
observatory as raw images and were then
processed to remove much of the clutter and
excess light around the image. Bores could be
seen as waves moving across the field of
view, forming additional waves behind, also
known as trailing waves. The processed
images were rotated according to a 360°
Cartesian coordinate system, with 0° oriented
straight up. The images were then un-warped
to account for the wide angle of the lens.
Results:
Bores were detected through both the use of
keograms and through watching the
sequences of images through an image
processor called Norway. The images were
played as though through a long sequence, so
this version of detecting events could detect
individual bores and their paths across the
sky. A single event image can be seen in
Figure 5. Keograms were primarily used to
determine the propagation of movement and
direction. Keograms are extended images of
single images. Each image taken every 30
seconds was condensed to a single line only
a few pixels in diameter. These images were
then spread throughout the length of the day.
Bores could be seen as brighter lines in
contrast to darker troughs, as in Figure 6.
Temperature
keograms
showed
the
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difference in temperature of the crests of each
bore to their troughs. A segment of a
temperature keogram can be seen in Figure 7.
N
S
E
W
Figure 7: Temperature fluctuations of the waves in the
form of a keogram. This image was also taken July 29,
2015. The temperature ranges from 200K to 250K.
Figure 5: A still view of a bore moving from right to left
taken April 23, 2015. Each crest and trough can be seen
through the intensity of each variation of the wave.
shows its greater potential for breaking.
Because this image shows such great
intensity between its crests and troughs, the
bore is breaking rather quickly. Figures 5 and
6 show a much more consistent bore. It is
traveling NW and creating multiple wavelets
trailing behind. The lack of difference in
intensity shown between the crests and
troughs indicates that this event lasted much
longer than the event on April 23, 2015.
N
S
E
W
Figure 6: This black and white image of a keogram taken
on July 29, 2015 shows a wave progressing from the right
to the left. Bores can be differentiated from mere waves by
the creation of additional wavelets. The directions are
shown above. Minor fluctuations in the atmosphere can be
seen to the left of the image. The arrows show the
direction of propagation.
Though Figure 5 does not show the consistent
bands that Figures 6 and 7 do, it has a greater
intensity. Figure 5 also shows a rare
phenomenon: the bore appears to be breaking
at its center. The greater intensity of a bore
The keogram segments for June 11, 2015,
and April 23, 2015 show a much less
consistent variation in waves. Figures 8 and 9
refer to April 23, 2015, and Figures 10 and 11
refer to June 11, 2015. Figures 8 and 9 show
a burst of intensity moving NW early in the
morning. The image for this occurred for an
hour. The created wavelets seem to fade as
the image progresses. The temperature shows
little change except in the boundary between
its emergence. Figures 10 and 11 show
exceptional change in temperature from
trough to crest. The images show that the
bore tends to twist, moving from left to right.
This twisting seems to be the reason for the
bore to break in its center.
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Figure 8: Keogram of bore dated April 23, 2015. The large
changes in intensity show a definitive line between the
bore and its additional wavelets. The trailing waves fade as
the bore mores NW.
Figure 10: Keogram of bore dated June 11, 2015. This
bore shows a spiraling motion. It breaks very quickly,
showing very few additional wavelets trailing. This bore is
also moving NW.
Figure 11: Much larger changes in temperature show that
this bore changed temperature with pressure.
Figure 9: Keogram of temperature fluctuation of the bore
on April 23, 2015.
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The rate of bores per month for 2015 and
2016 is given in Graph 1. Bores are most
common in the in the beginning and end of
the winter season. Graph 2 displays the
Bore Ocurrances 2015 -
6
4
2
0
April
May
June
2015
July
August
2016
Graph 1: Histogram of bore occurrences in the years 2015
and 2016. Most events occurred in the year 2016 while
June showed the least number of events in both 2015 and
2016.
average time of day in the years 2015 and
Time of Day - Bore Events-
The South Pole experiences such cold
temperatures in the winter that snow cannot
accumulate in the air. The air flowing in this
region forms a vortex that prevents airflow
moving in and out. Atmospheric wave events
pass through the atmosphere but are
destroyed at the edge of the vortex (Taylor).
Waves are created inside the vortex, since no
atmospheric events can penetrate it. This
suggests that morning and evening events
may be in response to temperature
fluctuations, which, in turn, may be the
causes for the change in pressure.
The overall data for the 48 events seen in
2015 and 2016 show a wide range of
durations, periods, wavelengths, velocities,
and direction of propagation. Table 1 gives
the data of particularly excellent events that
occurred in both 2015 and 2016. Table 2
shows an average for all bore events of these
two years.
Discussion:
April
May
June
July
00:00 - 00:60
06:00 - 12:00
12:00 - 18:00
18:00 - 24:00
August
Graph 2: Histogram of the times of day for bores for the
years 2016. The events are listed by month. The most
common time for a bore event is in the morning and the
last 6 hours.
2016 that events occurred. As seen, bores
occur regularly in the morning from 00:00 –
06:00 hours. The bore events in the morning
also show the greatest intensity. The others
vary depending on the month.
Initial hypotheses suggested that bore events
would be rare phenomena which had only
been observed near the Equator. This
hypothesis also referred to the propagation
and creation of waves in the atmosphere
before a storm occurred. Changes in air
pressure and temperatures suggest that bores
would most often occur in the atmosphere
over oceanic regions near land masses where
convection currents heated and cooled the air.
It has been suggested for years that oceans
determine acoustic gravity wave propagation
in the atmosphere. Recent studies have
determined that the different frequenc ies
emitted from the ocean do determine
atmospheric anomalies (Godin 2015). This is
reasonable to assume because large storms
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Table 1: Exceptional bore events for every winter month of 2015 and 2016. Most bore events occurred either the beginning for the sea son orthe
end of the season. Possible reasons could be that frigid air does not provide enough temperature fluctuation. Also, pressure fluctuations may account
for independence on warmer air.
South Pole Exceptional Bores 2015 and 2016
Wavelength
Velocity
Period
Duration of
Direction of
(km)
(m/s)
(min)
Event (min)
Propagation (°)
April 23,- ±-:- ± 6.52
May 4,- ±-:- ± 5.00
June 11,- ±-:- ± 4.35
July 26,- ±-:15
97.13 ± 11.42
August 16,- ±-:- ± 4.00
April 26,- ±-:- ± 9.95
May 25,- ±-:- ± 3.45
June 5,- ±-:- ± 11.31
July 29,- ±-:- ± 3.06
August 22,- ±-:49
20.23 ± 4.26
originating in the ocean and bays show
Because the South Pole experiences its
variation in cloud formations. Increased
winter months in a vortex, it was reasonable
surveillance images of the sky during
to assume that large bores with separations of
hurricanes, though hard to obtain, should
roughly >15 km (Taylor 2007) would be
show events in the sky similar to atmospheric
scarce. However, since observations have
bores. This must suggest that atmospheric
begun in 2012, 130 bores have been found
bores experience changes in air pressure and
and documented. The average wavelength,
temperatures inside the vortex event. The
velocity, period, duration of event, and
South Pole’s average temperatures reach as
direction of propagation, found in Table 2,
low as -80° F. Because of this extreme cold,
shows that the relative data points are
it is suggested that the warmest times of the
remarkably similar. There was a total of 48
winter may show the greatest amount of
events, 41 of which were large enough to be
bores.
analyzed.
Date of Event
Range
Average
Wavelength (km)
7.11 -
Average and Range of Data
Velocity (m/s)
Period (min)
5.01 - -
Duration of Event (min)
18:33 – 277:00
85.57
Table 2: Average and range of bore events seen in the South Pole of the years 2015 and 2016. The average shows a
more accurate view of wavelength, velocity, period, and duration of event. Several outliers must be discounted for
more accurate results.
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There is sufficient error in the average
wavelength to assume that there is significa nt
variation. Though the most common entries
averaged from 40km to 60km, the variatio n
should be consistent with the time of year.
The longest wavelengths tend to be early in
the morning; these wavelengths also tend to
break early, showing much more intens ity
and far fewer trailing waves. The range of
velocities are also extremely wide. This may
be due to the variation in the waves as they
propagate in a bore event. A wave may
experience a change in rate of 20m/s over the
course of an event from leading bore to the
last trailing wave. This might suggest such a
variation in velocity. There is also a
significant difference in the range for the
period. When calculating the results outliers
such as 299.15 and 302.60 were discarded
due to its inconsistency; this may have been
because of the variation in velocity. Lower
and fewer recorded velocities for a given
event show a large discrepancy in period.
Wavelengths also determine the length of a
period,
and inconsistent
results
of
wavelengths and velocities give wide
variations in the period. Finally, the duration
of events showed the widest range. This may
have been due to the difference in pressure
and temperature in the atmosphere. Bores are
created as acoustic gravity waves. Gravity
waves vary the movement of waves in air.
The longest bores were less intense and have
continuous trailing waves. The shortest bores
have great intensity in relation to their
troughs. The most intense of these occurred
in- provided a rare double-bore
event, one moving at a roughly 330ͦ the next
trailing at roughly 30ͦ.
Conclusion:
Atmospheric bores appear to have little
consistency in duration but have relative ly
accurate averages in wavelength, velocity,
and period. Bores are much more common
than originally believed. They have been
found through this study to be much more
consistently found in the warmer months of
the winter. There have been multip le
examples of rare events, including a bore
moving in a helix, a bore so intensely bright
that it burned itself out before trialing waves
could be formed. And finally, a bore
experienced a change in direction or created
a new bore shortly after. Future studies in
bore activities could allow us to determine
weather anomalies and see how water affects
atmospheric gravity waves.
References:
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breaking tidal bore. The Journal of
the Acoustical Society of America,
139(12), 12-22.
doi:10.1121/-
Davies, L., Reeder, M. J., & Lane, T. P.
(2017). A climatology of atmospheric
pressure jumps over southeastern
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Hecht, J. H., Liu, A. Z., Walterschied, R. L.,
Franke, S. J., Rudy, R. J., Taylor, M.
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Characteristics of short-period
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observations over Maui. Journal of
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Hartung, D. T., Otkin, J. A., Martin, J. E., &
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