The Cheyenne Tornado
July 16 1979
Jonathan D. Finch
Historical Tornado Cases for the Boulder Warning Area
Historical Tornado Cases for the Cheyenne Warning Area
Historical Tornado Cases for the United States
April 23 1960 Cheyenne Ridge Tornado
May 7-8 1965 Front Range Tornado
June 14-17 1965 Front Range Superstorm
High plains and front range topo maps
Overview
On July 16, 1979, the most damaging tornado in Wyoming history touched down 3 miles west-northwest of the
Cheyenne airport. This strong tornado
moved east or east-southeast across the northern part of Cheyenne,
causing $22 million in damage and 1 fatality.
140 houses and 17 trailers were destroyed. 325 other houses were
damaged. Four C-130 aircraft and National
Guard equipment sustained $12 million damage. Municipal hangars
and buildings suffered another $10 million damage.
There were no hail reports with this storm or any other storm
that day in Wyoming. A woman was killed instantly by lightning after climbing to the top of Pingora Peak (11884 ft)
about 28 miles west of Lander.
July 14
On July 14 a strong shortwave trough and
associated jet streak was moving across the northern plains as shown by
the 00 UTC July 15 500mb and 250mb charts. Behind this feature across Wyoming, a cold front was already
beginning to surge down the plains as of 21 UTC. Severe weather actually developed by early afternoon in western
SD and Nebraska and in the evening in
Colorado. The warmest part of the 700mb warm plume at 00 UTC July 15
extended from central NM to northern
Colorado into southern Utah and eastern NV. Late on July 14th a cold
surge
developed primarily in the lee of the Rockies. By
the end of July 14th (06 UTC July 15th), the cold front had already
surged into northern Colorado. A front that was
enhanced by outflow was located across southern Nebraska into
central Missouri.
July 15
By 12 UTC July 15, the surface to 700mb cold surge was apparent. The cool air was actually spilling over the
Rockies into southwest Wyoming and central CO. The
shortwave trough (500mb) and associated jet streak that
moved across the northern high plains the
previous evening was located over Minnesota and Iowa. The front that
was draped across southern Nebraska and Missouri at
00 UTC July 16 was surging into central Kansas by 12UTC.
By 18 UTC the front had stalled over western Colorado but was still pushing south into New Mexico. The outflow
boundary that was located over eastern Kansas and
Missouri at 12 UTC had raced south into northeast Oklahoma
and northern Arkansas.
By 00 UTC July 16, low level moisture was beginning to surge upslope(to the southwest) from northwest Kansas
into eastern Colorado. The surface front was
beginning to stall out across central New Mexico. An outflow boundary
stretched from near Dodge City to near Tulsa.
Another clusters of convection in the Texas Panhandle resulted in
rain cooled air at Amarillo. The front in New Mexico
was about to undergo frontolysis since it had already moved
to near the mean ridge position at 500mb. The northern plains frontal boundary tightened considerably on July 15
as the elevated mixed layer hot plume shifted north
and the low level cool dome shifted south. 700mb temps on the
15th ranged from about 3 C around Sheridan to around
15-16C at Jackson Hole. With no upper air data between
Boise and Lander, one may ask how I analyzed +15C
700mb temps across western Wyoming. Well, I was able to
make judicious use of surface data to fill in
details where upper air data were lacking. This wedge of warm
air analyzed
based on the surface tempertatures at Jackson Hole
and Yellowstone. Afternoon surface temperatures at Jackson
Hole and West Yellowstone were lifted up to 700mb to yield the 700mb temperatures above these stations.
Sometimes the low levels become superadiabatic,
yielding a 700mb temp that is too warm. So the best method is to
use the mixout temperature, whether this
occurs at local noon(in windy conditions) or sometime in the early
afternoon
in lighter wind conditions. In most of my high front
range tornado cases, surface winds under the mid level hot plume
are breezy to windy and afternoon dewpoint
depressions are fairly high. Surface winds on July 16, 1979 were not as
strong. Also notice the 700mb baroclinic zone across
the midwest and northern plains. There is upper level support for
a front across this area, but not further south in
New Mexico. By the end of July 15 (06 UTC July 16), the front over
New Mexico is about to undergo frontolysis. The
surface winds over eatsern Colorado were becoming more
southeasterly, resulting in strong moisture
transport onto the front range. The surface dewpoints at Denver and
Akron
were up to 59F and 60F respectively.
July 16
By 12 UTC July 16, the front over New Mexico was
undergoing frontolysis. A 700mb baroclinic zone was located
across the Iowa. The surface front associated with this baroclinic zone was further south as one would expect in
Illinois and Missouri. A shortwave trough was
evident from the 500mb chart over Montana and northwest Wyoming.
The tail end of the upper jet streak was located over eastern Montana. The surface dewpoints at Sidney, Akron, and
Cheyenne were up to 60F, 61F and 56F respectively.
Note again that an adjustment of 7F was made to the Sidney
dewpoint. Strong surface pressure rises were
occurring at Dodge City and about to occur at Garden City at 12 UTC.
I am not
sure why.
Accas was reported at Cheyenne on the morning of the 16th after
the low clouds burned off. Therefore,
high lapse rates were likely present along the
eastern extremity of the warm plume(elevated since low level cooling
occurred at Cheyenne overnight).
From 17 to 20 UTC July 16, an area of thunderstorms
moved east-southeast across Nebraska, leaving an outflow
boundary trailing back to the west into southeast
Wyoming. Frontogenesis was also occurring across southern Wyoming
and northeast Colorado. By 20 UTC, the leading edge
of a strong pressure gradient marked the location of the new
surface frontal boundary. This makes sense based on
the position of the upper jet at 12 UTC. I was able to plot the
location of the outflow boundary at
around 15 UTC using time series of surface observations from
Scottsbluff, Alliance,
Mullen and Ainsworth, NE. 17 UTC 18 UTC 19 UTC 20 UTC.
It is possible
that this boundary sagged into
the Cheyenne area around the time of the
tornado.
|
Time(UTC) |
VIS/WX/CLDH |
T/TD |
Wind |
ALT |
Scottsbluff
|
1553
|
|
1023.3
|
14010 |
029 |
|
1657 |
|
|
07010 wshft 1655 |
032 |
| Alliance |
1549 |
20 SM |
1020.6 |
14020 |
|
|
1650 |
2SM BR OVC007 |
|
04012 |
|
| Mullen |
1645 |
10SM OVC020 |
69/55 |
13010 |
034 |
|
1730 |
1/2SM +TSRA A OVC005 |
53/53 |
04020 |
040 |
| Ainsworth |
1643 |
|
67/57 |
05015 |
042 |
|
1715 |
-TSRA |
|
34015 |
045 |
|
1745 |
7 -TSRA |
60/59 |
34015 |
050 |
By the afternoon of July 16, a well defined
frontal boundary extended from east of Yellowstone to east
of Jackson
Hole to west of Lander to near Rawlins, to
near Laramie to near Cheyenne. Note that Lander was north of the front
all day on July 16 since the winds were light and
the dewpoints were high (uper 40s F). The boundary was undoubtedly
situated west of Lander where the woman was struck
and killed by lightning. The observations at Rock Springs show
the frontal boundary to the north of them in the afternoon. Then the wind
shifted to the northeast at 00 UTC signafying
a frontal passage.
Between 20 and 21 UTC,
the front or outflow boundary sagged south through Laramie, possibly
as a result of late
morning and early afternoon thunderstorm activity
near the front that was hovering close to Laramie and Cheyenne. The
dewpoint at Lqaramie jumped to 56F at 21 UTC but the
temperature was a cool 65F. Local thunderstorms in vicinity
of the front near Laramie was probably the reason
for this cool temperature. The
frontal positions were estimated by
looking at time series of surface
observations for surface stations across the plains. For example, at 19 UTC, it is
clear
that the front is north of Rawlins, north and east
of Rock
Springs and east of Jackson Hole and West Yellowstone. It
appears that the
front is immediately north of Cheyenne and Laramie since thunder was
reported at both stations. The
front was very difficult to find across central
and eastern Kansas, but the pressure gradient north of the front became
more pronounced during the day.
Southeast Wyoming was located in the right rear
quadrant of a jet streak on the afternoon of the 16th.
700mb temperature approximation
The mid level warm plume shifted east from July 15
to July 16, with 700mb temps warming to +18-19C across parts
of southwest and south central Wyoming
and adjacent northern Colorado. A strong sfc-700mb baroclinic
frontal zone
was apparent across Wyoming.
The 00 UTC 17th Denver sounding showed +14C 700mb. However, this
sounding
was contaminated by
convection. Since Denver mixed out completely by 20 UTC with a
surface temperature of 93F,
the 700mb
temperature was surely 17C just before the cool outflow arrived.
The 700mb temperature at Grand
Junction at 00 UTC July 17 was 17C. The maximum
temperature was 97F. If you lift a parcel dry adiabatically from
the
surface(856mb) to 700mb you get
18C. Therefore it is typically better to subtract 3F from the high
temperature before
lifting to 700mb when determining
700mb temperatures, especially in light wind
situations. In strong wind and very dry
situations at elevations above 6000ft, the local
noon temperature would give a closer
approximation. In this case I used
the maximum temperature or maximum temerature (F) -3
depending on the station to augment the 700mb chart. 700mb
temps in the
hot plume on the morning(12 UTC) of the 15th and 16th were about 2 to
3C cooler than at 00 UTC. This
is because the diurnal cooled layer extends up
beyong 700mb at stations above 5000ft. This is obviously not the case
at high plains stations such as Amarillo
and Dodge City. At these locations, the hot plume sometimes actually
moves east
away from the rockies between 00 and 12 UTC,
yielding very warm 12 UTC 700mb temps.
The mid level warm plume shifted east from July 15
to July 16, with 700mb temps warming to +18-19C
across parts of southwest and south central Wyoming
and adjacent northern Colorado. A strong sfc-700mb
baroclinic frontal zone was apparent across Wyoming.
The 00 UTC 17th Denver sounding showed +14C
700mb. However, this sounding was contaminated by
convection. Since Denver mixed out completely by 20
UTC with a surface temperature of 93F, the 700mb
temperature was surely 17C just before the cool outflow
arrived. The 700mb temperature at Grand Junction at 00 UTC July 17 was 17C. The maximum temperature
was 97F. If you lift a parcel dry adiabatically from
the surface(856mb) to 700mb you get 18C. This is why
it is typically better to subtract 3F from the high
temperature before lifting to 700mb (when determining 700mb
temperatures). This is especially true in light wind
situations. In strong wind and very dry situations, the
maximum temperature would give a closer
approximation. I used the maximum temperatures at several stations
to augment the 700mb chart.
|
Elev(ft) |
Pres.(mb) |
MaxT(F) |
MaxT(F) -3 |
700mb T |
Rock Springs
|
6760 |
800 |
88 |
85 |
18
|
| Rawlins |
6813 |
799 |
88 |
85 |
18 |
| Jackson Hole |
6560 |
805 |
87 |
84 |
16.5 |
| Yellowstone |
6640 |
803 |
83 |
80 |
15 |
| Eagle |
6540 |
809 |
91 |
88 |
18 |
| Rifle |
5540 |
835 |
93 |
90 |
17 |
| Denver |
5300 |
841 |
93 |
90 |
16.5 |
| Grand Junction |
4858 |
856 |
97 |
94 |
17 |
| Vernal |
5280 |
841 |
92 * |
93 |
16.5 |
The maximum temperature at Jackson Hole was 87F.
Lifting 87F at 805mb up to 700mb yields a 700mb temperature
of 18.5C. However, you can see that Jackson Hole had
not "mixed out" by local noon since they were stuck in a fairly
fairly light wind regime. Therefore, I decided to
use MaxT (F) -3 = 84F as the mixed out temperature. This yields a
700mb temperature of 16.5C. The same procedure was
used for Yellowstone. Vernal, UT as well as much
of northern
UT is lower in elevation. I used the maximum
temperature there to find the 700mb temperature.
Theta-e Comparison
The first indication of a tornado was 3.5 miles
west-northwest of the Cheyenne
airport at 335 pm MDT(2135 UTC). The
22 UTC surface chart shows the front just south
of Laramie.
The T/TD were 71F/56F. At this time the tornado was
probably just finishing its rampage across
northern
Cheyenne. By mid-summer standards in the central or eastern USA
this would be a very
cool temperature and a low dewpoint such as would be found behind
a strong cold front. However,
the
elevation of Laramie is 7270ft. The author of this page believes
that the theta-e was similar near Cheyenne
and Laramie
on the immediate cool side of the
boundary. Despite the T/TD being 12F/16F lower at Laramie than
Topeka, the theta-e
was actually slightly higher at Laramie than at
Topeka.
| 01 UTC |
Elev(ft) |
Pres.(mb) |
SLP(mb) |
T(F) |
Td(F) |
MR(g/kg) |
theta(F) |
theta-e(K) |
Laramie
|
7270
|
788 |
1023.3
|
71 |
56 |
8.3 |
98.3
|
354.3 |
| Topeka |
881 |
991 |
1020.6 |
83 |
72 |
11.2 |
80.8 |
353.6 |
CAPE Approximation
Since the storm was near the boundary, CAPE
estimations were made on both sides of the boundary. To estimate the
CAPE on the cool side of the boundary I used the 22
UTC surface observation at Laramie. This was the only high
elevation location in the most air immediately north
of the boundary at 22 UTC. The T/TD were 71F/56F with a
surface pressure of 788mb. I used this information
along with nearby soundings from North Platte, Lander and Rapid
City, Dodge City and Denver to create an
approximate sounding for the "cool" side of the front. The surface
based
CAPE was
around 2800 j/kg at 22 UTC. A T/Td of 71F/56F
at Laramie would give the same theta-e as 77/57 near
Cheyenne. At Cheyenne it was 81F in the early
afternoon. But immedialtely north of Cheyenne it was surely cooler,
with much higher dewpoints. In fact,
the dewpoint jumped to 56F at Cheyenne by 22 UTC, but the temperature
was
cooler due to nearby
thunderstorms. Just south of the outflow boundary or front,
surface based CAPE values were
lower.
The T/TD at Cheyenne at 20-21 UTC were 80/50 and
81F/49F. Using the same thermal profile aloft(500-200mb), the
surface based CAPE at Cheyenne was 1500 j/kg.
Cloud bases
I do not have enough information to determine if the
storm was realizing the higher CAPE just north of the boundary,
or if the storm was mainly ingesting air from the
warm side. If the former is the case then the storm would have been
lower based and the vertical wind shear would have
been stronger given the easterly winds and higher dewpoints in the
cooler
air. I cannot reliably compute the shear profile or storm relative
helicity. On the front range and mountain region,
it is very difficult to approximate the 1 to 2 km
AGL wind profile. While the surface wind and winds at and above 500mb
(~4 km) might be known in this case, wind speed
and direction approximations from just above the surface to 3 km
are not
very accurate.
Upper air charts:
7-15-79 00 UTC 700 500 250
7-15-79 12 UTC 700 500 250
7-16-79 00 UTC 850 700 500 400 300 250 200
7-16-79 12 UTC 850 700 500 400 300 250 200
7-17-79 00 UTC 850 700 500 400 300 250 200
Surface charts 21 UTC 14 06 UTC 15 09 UTC 15 12 UTC 15 15 UTC 15 18 UTC 15 21 UTC 15 00 UTC 16
03 UTC 16 06 UTC 16 09 UTC 16 12 UTC 16 16 UTC 16 17 UTC 16 18 UTC 16 19 UTC 16
20 UTC 16 21 UTC 16 22 UTC 16