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BY ORDER OF THE SECRETARY AIR FORCE HANDBOOK 15-101
OF THE AIR FORCE
5 NOVEMBER 2019

Weather

METEOROLOGICAL TECHNIQUES

ACCESSIBILITY: Publications and forms are available on the e-Publishing website at
www.e-Publishing.af.mil for downloading or ordering
RELEASABILITY: There are no releasability restrictions on this publication

OPR: HQ USAF/A3WT Certified by: HQ USAF/A3W
(Mr. Ralph O. Stoffler)
Supersedes: AFWA/TN-98/002, Pages: 248
13 Feb 2012 Revision

This handbook marks the first formal publication of a long-lived and highly-esteemed reference in
the Air Force Weather community; it is a new publication, derived from the legacy Field Operating
Agency Technical Note 98/002, Meteorological Techniques, and supersedes all existing iterations
of the legacy document. The transition from informal tech note to formal Air Force Handbook will
enable the Air Force to host it in the same location as other 15-series publications, allow for more
frequent updates, and will ensure appropriate review and approval of the processes and procedures
contained in the document. The handbook, when used with relevant data and additional Air Force
guidance, provides general guidance for effective meteorological techniques for a variety of
parameters. It is not a substitute for sound judgement and situationally relevant meteorological
reasoning. Refer recommended changes and questions about this publication to the Office of
Primary Responsibility listed above using the Air Force Form 847, Recommendation for Change
of Publication; route AF Forms 847 from the field through the appropriate chain of command.
Ensure that all records created as a result of processes prescribed in this publication are maintained
in accordance with Air Force Manual 33-363, Management of Records, and disposed of in
accordance with Air Force Records Information Management System Records Disposition
Schedule. The use of the name or mark of any specific manufacturer, commercial product,
commodity, or service in this publication does not imply endorsement by the Air Force.

SUMMARY OF CHANGES

The document has been substantially revised and should be completely reviewed. The legacy
98/002 tech note has been updated several times over the twenty years since its initial publication,
2 AFH15-101 5 NOVEMBER 2019

and this Handbook was created based upon the 2012 tech note revision as a starting point. While
the table of contents and list of topics will be familiar to anyone who has used the legacy technical
note, numerous techniques were updated to reflect advanced processes and procedures, and many
illustrations and figures were modernized with improved graphics and pictures.

Chapter 1—SURFACE WEATHER ELEMENTS 9

1.1. Visibility................................................................................................................. 9

Figure 1.1. Whiteout Conditions................................................................................................ 10

Figure 1.2. Pre-frontal fog associated with a warm front........................................................... 18

Figure 1.3. Post-frontal fog associated with a slow-moving cold front..................................... 18

Table 1.1. Visibility limits based on snowfall intensity............................................................ 19

Table 1.2. Threshold dust-lofting wind speeds for different desert environments................... 21

Table 1.3. Favorable conditions for the generation and advection of dust............................... 21

Figure 1.4. WSCC example........................................................................................................ 26

Figure 1.5. Visibility Climogram example for Vandenberg AFB.............................................. 26

Figure 1.6. OCDS-II example.................................................................................................... 27

Figure 1.7. Radiation Fog Point example................................................................................... 27

Table 1.4. Fog threat thresholds, indicating likelihood of radiation fog formation.................. 28

Table 1.5. Fog Stability Index (FSI) thresholds, indicating likelihood of radiation fog
formation.................................................................................................................. 28

Figure 1.8. Visible (A) and infrared (B) comparison of dust detection capability..................... 29

Figure 1.9. Sunrise dust plume detection, due to forward scattering......................................... 30

Figure 1.10. AOD product, showing areas of atmospheric dust.................................................. 30

Table 1.6. Interpretation of the GEPS and MEPS Pollution Trapping Index (PTI) index........ 35

1.2. Precipitation............................................................................................................ 36

Figure 1.11. Overrunning associated with a typical cyclone........................................................ 37

Figure 1.12. Method 1 – the plot shows where to expect different precipitation types............... 39

Table 1.7. Probability of snowfall as a function of freezing level height................................. 40

Figure 1.13. Melting layer depth vs. mean layer temperature for freezing rain potential............ 42

Figure 1.14. Typical freezing rain sounding. Note the depth and magnitude of the melting
layer, as well as the moisture into the dendritic layer.............................................. 43
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Figure 1.15. Precipitation type nomogram, based on 1000 mb and 850 mb wet bulb
temperatures............................................................................................................. 43

Figure 1.16. Precipitation type nomogram, based on 1000-850 mb and 850-700 mb
thicknesses............................................................................................................... 44

Figure 1.17. Freezing drizzle soundings...................................................................................... 45

Figure 1.18. Idealized sleet sounding........................................................................................... 46

Figure 1.19. MAXTEMP and SLR relationship........................................................................... 52

Table 1.8. Snowfall accumulation vs. surface visibility........................................................... 55

Table 1.9. General Rules of Thumb – Drizzle.......................................................................... 57

Table 1.10. General Rules of Thumb – Thickness Values and Precipitation Type.................... 57

Table 1.11. General Rules of Thumb – Freezing Precipitation................................................... 57

Table 1.12. General Rules of Thumb – Parameter Values and Precipitation Type.................... 58

1.3. Surface Winds........................................................................................................ 58

Figure 1.20. Centrifugal and Centripetal Forces.......................................................................... 59

Figure 1.21. Geostrophic Wind.................................................................................................... 60

Figure 1.22. Isallobaric Wind....................................................................................................... 61

Figure 1.23. Comparison of open-cell cumulus (top of image) and closed-cell stratocumulus
(bottom of image).................................................................................................... 63

Figure 1.24. Open-cell cumulus shapes, based on wind speed.................................................... 63

Figure 1.25. Stratocumulus lines over the Alaskan Peninsula..................................................... 64

Figure 1.26. Von Karman vortices downstream of Madiera, off the western African coast........ 65

Table 1.13. Elevation, Temperature, and Wind Speed Adjustments.......................................... 66

Figure 1.27. The shape of the coastline determines sea breeze divergence or convergence........ 68

Table 1.14. Crosswind Component Table................................................................................... 72

Table 1.15. Low-level wind shear decision flowchart................................................................ 73

Table 1.16. Vector difference directional charts......................................................................... 74

Table 1.17. Wind speed and wind gust calculator, using the 1.4 multiplier............................... 77

1.4. Temperature............................................................................................................ 79

Figure 1.28. Standard surface model of daily atmospheric heating and cooling in relation to
radiation gains and loses under clear skies.............................................................. 79
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Figure 1.29. Computation of maximum Skew-T temperature. With no inversion and (A)
mostly cloudy skies, (B) mostly clear skies. With an inversion and (C) mostly
cloudy skies, (D) mostly clear skies........................................................................ 81

Table 1.18. K-value correction factors for the Callen and Prescott method............................... 82

Table 1.19. K-value correction factors for the McKenzie method............................................. 83

Table 1.20. Wind chill temperature chart................................................................................... 85

1.5. Pressure................................................................................................................... 85

Table 1.21. Standard atmospheric pressure and temperature – by altitude................................. 87

Table 1.22. Standard atmospheric pressure and temperature – by level..................................... 87

Table 1.23. Altimeter settings..................................................................................................... 88

Figure 1.30. Pressure conversion chart........................................................................................ 89

Figure 1.31. Pressure Altitude formula........................................................................................ 90

Chapter 2—FLIGHT WEATHER ELEMENTS 91

2.1. Clouds..................................................................................................................... 91

Figure 2.1. WWMCA Cloud Free Plot over China and East Asia............................................. 93

Figure 2.2. Global plot of mean total cloud amount, May, 1800-2100 UTC............................. 94

Figure 2.3. Calculation of the MCL........................................................................................... 96

Figure 2.4. CCL Parcel Method................................................................................................. 96

Table 2.1. Expected bases of convective clouds from surface dew point depression............... 97

Figure 2.5. Stratus dissipation technique, using mixing ratio and temperature.......................... 99

Figure 2.6. Tropopause method of forecasting cirrus bases and tops........................................ 99

2.2. Turbulence.............................................................................................................. 100

Table 2.2. Aircraft Turbulence Category Type......................................................................... 103

Table 2.3. Turbulence Conversion Chart.................................................................................. 107

Figure 2.7. Kelvin-Helmholtz wave lifecycle............................................................................ 109

Table 2.4. Richardson Number calculation and interpretation................................................. 110

Figure 2.8. “S-shaped” tropospheric temperature profile, indicating potential turbulence........ 112

Figure 2.9. Surface cyclogenesis and jet-core CAT and secondary jet-core CAT..................... 113

Figure 2.10. CAT during the development of an upper-level low. Patterns b and c show the
areas of moderate CAT as the low breaks off from the trough................................ 113
AFH15-101 5 NOVEMBER 2019 5

Figure 2.11. CAT area along a shear line associated with an upper level low............................. 114

Figure 2.12. CAT in a diffluent wind pattern............................................................................... 115

Figure 2.13. CAT areas in shearing troughs................................................................................. 116

Figure 2.14. CAT with wind maximum to the rear of the upper trough...................................... 117

Figure 2.15. CAT with upper level ridges.................................................................................... 118

Figure 2.16. Mountain wave cloud structure................................................................................ 119

Table 2.5. Low level mountain wave turbulence guidance chart.............................................. 120

Figure 2.17. Mountain Wave Turbulence nomogram.................................................................. 121

Figure 2.18. Gravity waves on visible satellite imagery.............................................................. 122

Table 2.6. Expected turbulence locations................................................................................. 123

Figure 2.19. Low-level turbulence forecasting flowchart – Category II aircraft......................... 123

Figure 2.20. Convective cloud turbulence forecasting, using the Skew-T................................... 124

Table 2.7. Surface-9000 foot temperature difference vs. turbulence intensity......................... 125

Table 2.8. Layer above 9000 feet temperature difference vs. turbulence intensity.................. 125

Figure 2.21. Low-level turbulence nomogram............................................................................. 125

Figure 2.22. Turbulence in a deformation zone........................................................................... 126

Figure 2.23. Transverse bands...................................................................................................... 126

Figure 2.24. Billow clouds........................................................................................................... 127

Figure 2.25. Mountain waves....................................................................................................... 127

Figure 2.26. AFW-WEBS authoritative upper level turbulence outlook..................................... 129

Table 2.9. Stratospheric Layer Advanced Turbulence Index.................................................... 129

2.3. Icing........................................................................................................................ 130

Figure 2.27. Rime Icing................................................................................................................ 133

Figure 2.28. Clear Icing – smooth and rough varieties................................................................ 134

Table 2.10. Icing type based on temperature.............................................................................. 134

Table 2.11. Icing amount definitions.......................................................................................... 135

Figure 2.29. Cumuliform cloud icing locations........................................................................... 137

Figure 2.30. Icing with a warm front............................................................................................ 138

Figure 2.31. Icing with a cold front.............................................................................................. 138
6 AFH15-101 5 NOVEMBER 2019

Figure 2.32. Intake icing.............................................................................................................. 139

Figure 2.33. Carburetor icing....................................................................................................... 140

Figure 2.34. Carburetor icing potential........................................................................................ 141

Table 2.12. Icing potential based on temperature and dew point depression.............................. 142

Figure 2.35. Typical icing areas in a mature cyclone................................................................... 143

Figure 2.36. Icing flowchart......................................................................................................... 144

Figure 2.37. Example of the “-8D Method” for determining icing potential............................... 146

2.4. Miscellaneous Weather Elements............................................................................ 147

Figure 2.38. Increasing flight level winds with CAA.................................................................. 147

Figure 2.39. Decreasing flight level winds with WAA................................................................ 148

Figure 2.40. Graphical representation of contrail formation........................................................ 151

Figure 2.41. Appleman chart, for contrail forecasting................................................................. 152

Figure 2.42. Appleman charts for non-bypass, low-bypass, and high-bypass engines................ 154

Table 2.13. Engine bypass type for military aircraft................................................................... 155

Figure 2.43. GALWEM no bypass forecast product. High bypass and low bypass versions are
also available............................................................................................................ 156

Table 2.14. Probabilities of contrail formation based on temperature and pressure level.......... 157

Figure 2.44. Space weather stoplight chart.................................................................................. 160

Figure 2.45. UHF SATCOM impacts chart................................................................................. 162

Figure 2.46. Point-to-point HF radio usable frequency forecast chart......................................... 163

Figure 2.47. Planck curves for black bodies at a range of temperatures...................................... 166

Table 2.15. Comparison of temperature of an object and its emitted energy............................. 166

Figure 2.48. Inherent, apparent, and threshold contrast............................................................... 167

Table 2.16. Three hypothetical objects, showing the relationship between emissivity and
physical/radiative temperatures............................................................................... 169

Figure 2.49. Type of scattering, based on wavelength and scatterer size.................................... 171

Figure 2.50. Rayleigh scattering.................................................................................................. 171

Figure 2.51. Mie scattering.......................................................................................................... 172

Figure 2.52. Sun angle and angle of incidence............................................................................. 173
AFH15-101 5 NOVEMBER 2019 7

Table 2.17. General effects of weather and other obscurations on EO sensors.......................... 174

Figure 2.53. Thermal crossover of a tank against a grassy background....................................... 176

Chapter 3—CONVECTIVE WEATHER 181

3.1. Thunderstorms........................................................................................................ 181

Figure 3.1. Single cell thunderstorm hodograph........................................................................ 181

Figure 3.2. Multi-cell thunderstorm hodograph......................................................................... 182

Figure 3.3. Supercell thunderstorm hodograph.......................................................................... 182

Figure 3.4. Classic supercell...................................................................................................... 183

Figure 3.5. High-precipitation supercell..................................................................................... 183

Figure 3.6. Low-precipitation supercell..................................................................................... 184

Figure 3.7. Microburst atmospheric profiles (Dry, Wet & Hybrid)........................................... 184

3.2. Synoptic Patterns.................................................................................................... 193

Table 3.1. Severe thunderstorm development potential............................................................ 194

Figure 3.8. Type A severe weather synoptic pattern - dryline................................................... 195

Figure 3.9. Type B severe weather synoptic pattern - frontal.................................................... 196

Figure 3.10. Type C severe weather synoptic pattern – overrunning........................................... 197

Figure 3.11. Type D severe weather synoptic pattern – cold core............................................... 198

Figure 3.12. Type E severe weather synoptic pattern – squall line.............................................. 199

3.3. Convective Weather Tools...................................................................................... 200

Table 3.2. General thunderstorm (instability) indicators.......................................................... 201

Table 3.3. Severe thunderstorm indicators................................................................................ 202

Table 3.4. Tornado indicators................................................................................................... 202

Table 3.5. Tornado forecasting tools........................................................................................ 203

Table 3.6. S-Index calculation.................................................................................................. 204

Figure 3.13. Line echo wave pattern (LEWP) and bow echo evolution...................................... 207

Figure 3.14. Bow echo schematic and reflectivity example......................................................... 208

Table 3.7. Product analysis matrix and reasoning.................................................................... 209

Table 3.8. Identifying features of airmass thunderstorm development on upper air charts...... 210

Table 3.9. WINDEX Equation.................................................................................................. 212
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Table 3.10. Wet microburst potential table, using VIL and Echo Tops...................................... 213

Figure 3.15. Sea breeze on a base reflectivity product................................................................. 214

Table 3.11. T1 convective gust potential.................................................................................... 216

Figure 3.16. T2 gust computation chart....................................................................................... 217

Figure 3.17. Hail prediction chart, using cloud depth ratio and freezing level............................ 218

Figure 3.18. Hail size parameters on the Skew-T diagram.......................................................... 219

Figure 3.19. Preliminary hail size nomogram.............................................................................. 219

Figure 3.20. Final hail size nomogram – only use if WBZ height is above 10,500 feet.............. 220

Table 3.12. VIL density and hail size......................................................................................... 221

Attachment 1—GLOSSARY OF REFERENCES AND SUPPORTING INFORMATION 222
AFH15-101 5 NOVEMBER 2019 9

Chapter 1

SURFACE WEATHER ELEMENTS

1.1. Visibility. The American Meteorological Society defines visibility as “The greatest distance
in a given direction at which it is just possible to see and identify with the unaided eye, (1) in the
daytime, a prominent dark object against the sky at the horizon, or (2) at night, a known, preferably
unfocused, moderately intense light source.” Forecasting visibility is a challenge due to the
difficulty in predicting the complicated behavior of “dry” and “moist” (both liquid and solid)
airborne particles that obstruct or reduce visual range. Basic overviews of dry obstructions
(lithometeors) and moist obstructions (hydrometeors) are provided below, followed by more
concentrated analyses of individual obstructions.
1.1.1. Dry Obstructions (Lithometeors). A lithometeor is the general term for particles
suspended in a dry atmosphere; these include haze, smoke, dust, and sand.
1.1.1.1. Haze. Haze is an accumulation of very fine dust or salt particles in the atmosphere;
it does not block light, but instead causes light rays to scatter. Haze particles produce a
bluish color when viewed against a dark background, but look yellowish when viewed
against a lighter background. This light-scattering phenomenon (called Mie scattering) also
causes the visual ranges within a uniformly dense layer of haze to vary depending on
whether the observer is looking into the sun or away from it. Typically, haze occurs under
a stable atmospheric layer and significantly effects visibility. In general, industrial areas
and coastal areas are most conducive to haze formation.
1.1.1.2. Smoke. Smoke is usually more localized than other visibility restrictions. Accurate
visibility forecasts depend on detailed knowledge of the local terrain, surface wind patterns,
and smoke sources (including schedules of operation of smoke generating activities).
1.1.1.3. Blowing Dust and Sand. Windblown particles such as blowing dust and sand can
cause serious local restrictions to visibility, often reducing visibility to near zero. The
critical wind speed for lifting dust and sand varies according to vegetation, soil type, and
soil moisture. Specific forecasting rules vary by station and time of year; local references
and procedures should document the wind speeds, directions, and surface moisture
conditions in which visibility restrictions are most likely to occur.
1.1.2. Moist Obstructions (Hydrometeors). Condensation or sublimation of atmospheric water
vapor produces a hydrometeor. These particles form either in the free atmosphere or at the
earth‘s surface, and include frozen water lifted by the wind. Hydrometeors that cause surface
visibility reductions generally fall into two categories:
1.1.2.1. Precipitation. Precipitation refers to all forms of water particles, both liquid and
solid, which fall from the atmosphere and reach the ground; these include: liquid
precipitation (drizzle and rain), freezing precipitation (freezing drizzle and freezing rain),
and solid (frozen) precipitation (ice pellets, hail, snow, snow pellets, snow grains, and ice
crystals).
10 AFH15-101 5 NOVEMBER 2019

1.1.2.2. Suspended (Liquid or Solid) Water Particles. Liquid or solid water particles that
form and remain suspended in the air (damp haze, cloud, fog, ice fog, and mist), as well as
liquid or solid water particles that are lifted by the wind from the earth‘s surface (drifting
snow, blowing snow, blowing spray) cause restrictions to visibility. One of the more
unusual causes of reduced visibility due to suspended water/ice particles is whiteout, while
the most common cause is fog.
1.1.2.2.1. Whiteout Conditions. Whiteout is a visibility-restricting phenomenon that
occurs when a uniformly overcast layer of clouds overlies a snow- or ice-covered
surface. Most whiteouts occur when the cloud deck is relatively low and the sun angle
is at about 20° above the horizon. Cloud layers break up and diffuse parallel rays from
the sun so that they strike the snow surface from many angles (Figure 1.1). This
diffused light reflects back and forth between the snow and clouds until the amount of
light coming through the clouds equals the amount reflected off the snow, completely
eliminating shadows. The result is a loss of depth perception and an inability to
distinguish the boundary between the ground and the sky (i.e., there is no horizon).
Low-level flights and landings in these conditions become very dangerous.

Figure 1.1. Whiteout Conditions.

1.1.2.2.2. Fog. Fog is often described as “a stratus cloud resting near the ground.” Fog
forms when the temperature and dew point of the air approach the same value, either
through cooling of the air (producing advection, radiation, steam, or upslope fog) or by
adding enough moisture to raise the dew point (frontal fog). When composed of ice
crystals, it is called ice fog.
1.1.2.2.2.1. Advection Fog. Advection Fog forms due to moist air moving over a
colder surface, and the resulting cooling of the near-surface air to below its dew-
point temperature. Advection fog can occur over both water and land.
1.1.2.2.2.2. Radiation Fog. Also called ground or valley fog, this type of fog is
produced by radiational cooling. Under stable nighttime conditions, long-wave
radiation is emitted by, and cools, the ground, forming a temperature inversion. In
turn, moist air near the ground cools to its dew point. Depending on the moisture
content of the ground, moisture may evaporate into the air, raising the dew point of
this stable layer, accelerating radiation fog formation.
AFH15-101 5 NOVEMBER 2019 11

1.1.2.2.2.3. Upslope Fog. Upslope fog occurs when sloping terrain lifts air, cooling
it adiabatically to its dew point and saturation. Upslope fog may be viewed as either
a stratus cloud or fog, depending on the point of reference of the observer. Upslope
fog generally forms at higher elevations and builds downward into valleys. This
fog can maintain itself at higher wind speeds because of increased lift and adiabatic
cooling. Upslope winds more than 10 to 12 knots usually result in stratus rather
than fog. The eastern slope of the Rocky Mountains is a prime location for this type
of fog.
1.1.2.2.2.4. Frontal Fog. Associated with frontal zones and frontal passages, this
type of fog can be divided into types: warm-front pre-frontal fog; cold-front post-
frontal fog; and front-passage fog. Pre- and post-frontal fogs are caused by rain
falling into cold stable air and raising the dew point. Frontal-passage fog can occur
in a number of situations, such as when warm and cold air masses, each near
saturation, are mixed by very light winds in the frontal zone. It can occur when
relatively warm air is suddenly cooled over moist ground with the passage of a
well-marked precipitation cold front. It can also occur during low-latitude summer,
where evaporation of front-passage rain water cools the surface and overlying air
enough to add sufficient moisture to form fog.
1.1.2.2.2.5. Ice Fog. Ice fog is composed of ice crystals rather than water droplets
and forms in extremely cold, arctic air (–29°C (–20°F) and colder). Factors
contributing to reduced visibility associated with ice fog are temperature, time of
day, water vapor availability, and pollutants. Burning hydrocarbon fuels, steam
vents, motor vehicle exhausts, and jet exhausts are major sources of water vapor
and pollutants that help to produce ice fog. A strong low-level inversion contributes
to ice fog formation by trappingand concentrating the moisture in a shallow layer.
Once ice fog forms, it usually persists until the temperature rises or there is an air
mass change.
1.1.2.2.2.6. Sublimation Fog. The Glossary of Meteorology defines sublimation as
the “transition from solid directly to vapor.” Ice crystals sublime under low
humidity in below-freezing conditions. Sublimation fog occurs when ground frost
sublimes at sunrise, increasing atmospheric moisture. This can cause a rapid onset
of short-lived, shallow, foggy conditions reducing visibility to as low as 1/2 mile.
1.1.2.2.2.7. General Fog Forecasting Guidance:
1.1.2.2.2.7.1. Fog lifts to stratus when the lapse rate approaches dry adiabatic.
1.1.2.2.2.7.2. Marked downslope flow prevents fog formation.
1.1.2.2.2.7.3. The wetter the ground, the higher the probability of fog
formation.
1.1.2.2.2.7.4. Atmospheric moisture tends to sublimate on snow, making fog
formation, and maintenance less likely.
1.1.2.2.2.7.5. With sufficient radiational cooling (below freezing), fog can
dissipate rapidly and form ground frost through the deposition process.
12 AFH15-101 5 NOVEMBER 2019

1.1.2.2.2.7.6. Rapid formation or clearing of clouds can be decisive in fog
formation. Rapid clearing at night after precipitation is especially favorable for
the formation of radiation fog.
1.1.2.2.2.7.7. The wind speed forecast is important because decreases may lead
to the formation of radiation fog. Conversely, increases can prevent fog,
dissipate radiation fog, or increase the severity of advection fog.
1.1.2.2.2.7.8. A combination advection-radiation fog is common at stations
near warm water surfaces.
1.1.2.2.2.7.9. In areas with high concentrations of atmospheric pollutants,
condensation into fog can begin before the relative humidity reaches 100%.
1.1.2.2.2.7.10. The visibility in fog depends on the amount of water vapor
available to form droplets and on the size of the droplets formed. At locations
with large amounts of combustion products in the air, dense fog can occur with
a relatively small water vapor content.
1.1.2.2.2.7.11. After sunrise, the faster the ground temperature rises, the faster
fog and stratus clouds dissipate.
1.1.2.2.2.7.12. Solar insolation often lifts radiation fog into thin, multiple
layers of stratus clouds.
1.1.2.2.2.7.13. If solar heating persists, and no higher clouds block surface
heating, radiation fog usually dissipates.
1.1.2.2.2.7.14. Solar heating may lift advection fog into a single layer of stratus
clouds and eventually dissipate the fog if the insolation is sufficiently strong.
1.1.2.2.2.8. In summary, the following characteristics are important to consider
when forecasting fog:
1.1.2.2.2.8.1. Synoptic situation, time of year, and station climatology.
1.1.2.2.2.8.2. Thermal (static) stability of the air, amount of
cooling/moistening expected, wind strength, and dew-point depression.
1.1.2.2.2.8.3. Trajectory of the air over types of underlying surfaces (i.e.,
cooler surfaces, bodies of water).
1.1.2.2.2.8.4. Terrain, topography, and land surface characteristics.
1.1.3. Visibility Details.
1.1.3.1. Fog. Fog may develop or intensify when one or more of the following conditions
are satisfied:
AFH15-101 5 NOVEMBER 2019 13

1.1.3.1.1. Air at the surface is saturated or slightly supersaturated with respect to
water in the presence of cloud condensation nuclei. For fog to form, the air near the
Earth’s surface must be saturated, or nearly so, meaning that the temperature must equal
the dew point (RH = 100%). In reality, because fog is simply a cloud that has formed
at the surface, the surface air must be supersaturated for the fog to form. This wouldn’t
be possible if the air was perfectly pure with no particulates, but because the air near
the surface has many particles of dust, soil, and other minerals, the air can become
supersaturated (RH slightly greater than 100%), which allows visible cloud droplets to
form. However, mixed-phase (freezing) fogs and ice fogs can develop even if the
environment is slightly unsaturated with respect to liquid water (RH less than 100%).
Mixed-phase fogs are composed of supercooled water droplets and ice crystals, while
ice fog is composed entirely of ice crystals and usually occurs at very cold temperatures
(less than -30°C). For the formation of these fogs, RH with respect to water will
typically be between 99% and 99.9%, while RH with respect to ice may or may not be
greater than 100%. The surface air can become saturated via the following mechanisms:
1.1.3.1.1.1. Temperature cooling to the dew point via cold air advection or
radiational cooling.
1.1.3.1.1.2. Dew point increasing to the temperature via moisture advection or
evapotranspiration from the earth’s surface.
1.1.3.1.1.3. Precipitation very rapidly raises the dew point and cools the
temperature so they eventually equal each other. This process is called “wet-
bulbing”, whereby precipitation falls through an unsaturated layer of air and the
resultant evaporative cooling eventually lowers the temperature to the wet-bulb
temperature, while at the same time the dew point increases as moisture is added to
the layer.
1.1.3.1.1.4. Introduction of more fine particulates (ash, dust, etc.) into surface air
that is already very moist, which allows supersaturation to more easily be achieved.
This is akin to cloud seeding.
1.1.3.1.2. A wet ground surface exists, such as a body of water, moist vegetation, or
soil recently moistened by precipitation. While not imperative for fog formation, a wet
surface such as water or moist vegetation serves as a source of moisture for the
planetary boundary layer (PBL). This moisture increases the dew point of the PBL and
reduces the amount of cooling that is required for fog formation. A wet surface is
especially important for radiation fog formation (discussed in greater detail below),
which may not always have an advective source of surface moisture such as from an
ocean or lake.
1.1.3.1.3. Surface winds are less than 10 knots. Advection fog is characterized by
stronger surface winds than radiation fog, but in general surface winds greater than 10
knots are detrimental to fog formation because they make it difficult for saturation to
be achieved by maintaining a well-mixed PBL and bringing in drier ambient air. When
fog has already formed, however, the turbulence generated by surface winds less than
10 knots plays a pivotal role in the intensity and maintenance of the fog deck.
14 AFH15-101 5 NOVEMBER 2019

1.1.3.1.4. Dry air with relative humidity less than 50% exists above the surface moist
layer. Dry air above the surface is primarily important for radiation fog development
and evolution, but is also important for the transition of advection fog to radiation fog.
Dry air above the surface to great heights aloft is indicative of clear skies that are
conducive to radiative cooling of the earth’s surface. This allows the temperature to
cool to the dew point, which also creates a surface temperature inversion. At some
point, if the surface temperature cools to the dew point temperature, the air becomes
saturated and fog may form. When fog does form, dry air aloft allows the top of the fog
deck to continue to cool via outgoing IR radiation, which reinforces the fog deck and
often causes it to intensify. The presence of dry air aloft also has an impact on the
thickness of the fog deck. For example, because the residual layer (RL) above the
surface temperature inversion is usually dry adiabatic, winds within the RL will mix
dry air above the inversion into the fog deck. This causes the intensity of the fog deck
to fluctuate, but also causes it to deepen as turbulence develops within the fog deck.
When the sun rises, dry air aloft permits maximum heating of the fog deck. Solar
radiation is able to penetrate to some depth within the fog, which eventually causes it
to lift and dissipate when IR cooling is no longer sufficient to maintain the fog.
1.1.3.1.5. Moisture convergence is occurring, especially along coastlines or in areas
of complex terrain. Moisture convergence is a measure of the degree to which moist
air (water vapor) is converging into a given area. It takes into account converging winds
and the advection of moisture by these winds. Moisture convergence occurs along
frontal boundaries, complex terrain, and coastlines where the transition from “smooth”
water to land with higher friction causes winds to slow down and converge. Moisture
convergence is one of the most important aspects of advection fog formation, since it’s
common along coastlines when a sea breeze is present and can quickly bring
unsaturated air to saturation and keep it saturated as long as onshore flow is maintained.
As such, it’s the primary factor in coastal advection fog events, especially if other
factors (e.g., subsidence, dry air aloft, etc.) are favorable.
1.1.3.1.6. Precipitation falls into a slightly unsaturated layer, bringing surface relative
humidity with respect to water to 100%, or slight supersaturation (relative humidity
greater than 100%). Light precipitation (drizzle, mist) often leads to fog formation in
the presence of warm fronts, cold fronts, or other convergent boundaries. When light
precipitation falls into an unsaturated layer of air, some of it evaporates which cools
and moistens the unsaturated air. This simultaneously lowers the temperature and raises
the dew point, making precipitation an ideal way to saturate a layer of air. If winds are
light and all of the particulates in the air have not been washed to the surface by heavier
rain, fog often forms.
1.1.3.1.7. Warm air advection occurs within an existing temperature inversion above
a surface moist layer. Warm air advection (WAA) within the temperature inversion
above the fog layer is important to fog duration. If WAA is occurring in the inversion,
the inversion will be strengthened and will take longer to be mixed out by daytime
heating and turbulent mixing. This will allow the foggy air to be trapped under the
inversion for a longer period of time.
AFH15-101 5 NOVEMBER 2019 15

1.1.3.1.8. The atmosphere is statically or conditionally stable. Stability is one of the
most important considerations when forecasting fog. Fog will rarely form in a statically
or conditionally unstable PBL, because drier air from aloft is allowed to mix with moist
surface air. In other words, the moist surface air is not isolated from the drier air aloft.
Most fog events occur under a surface anticyclone (surface high pressure), which
effectively holds water vapor at the surface and isolates the surface from the typical
well-mixed layer above an inversion. Both temperature inversions and subsidence
inversions suppress substantial vertical mixing, and allow shallow fog layers to
develop.
1.1.3.1.9. Surface dew points are high. While not imperative for fog formation, a high
surface dew point generally means that the surface will not need to cool as much to
achieve saturation. In addition, a higher dew point means there is more moisture near
the surface, which is important for potential fog thickness. Fogs that form in maritime
environments with high dew points will generally be thicker than fogs that form where
dew points are lower.
1.1.3.1.10. Upslope flow is occurring. Fog is very common upstream along mountain
ranges where moist air impinges on the mountain barrier, is lifted, and condenses to
form clouds along the mountain side. Upslope flow is basically moisture convergence
along a mountain barrier or other area of complex terrain. If a moist flow pattern
persists, then upslope fog can last for several days as moisture is continually lifted along
the mountain-side and condenses to form fog.
1.1.3.1.10.1. The opposite is downslope (katabatic) flow, which results in
compressional warming of descending air and often leads to fog dissipation during
the daylight hours. There are cases, however, where this sinking air along the
mountain side spreads out on top of colder air in the valley, reinforcing an existing
fog deck by creating a temperature inversion that traps the valley moisture.
1.1.3.1.11. There is snow cover and/or the ground is frozen. Advection fog often
occurs during the winter months when warm, moist air moves over snow covered
and/or frozen ground. The surface air is cooled from below by the ground surface,
which may bring the surface air to saturation, allowing fog to develop.
1.1.3.1.12. There is cloud cover during the day and/or clear skies at night. Cloud cover
above a fog layer can cause the layer to remain in place or intensify during the day by
absorbing solar radiation that would otherwise penetrate the fog layer and cause it to
dissipate. During nighttime hours, however, the same clouds can cause the fog layer to
slowly dissipate as the clouds emit down-welling IR radiation into the fog layer, which
mitigates some of the cooling of the fog layer from below.
1.1.3.2. Specific Forecasting Guidance – Advection Fog: Advection fog is relatively
shallow and accompanied by a surface-based inversion. The depth of this fog increases
with increasing wind speed (though at wind speeds above 9 knots greater turbulent mixing
usually causes advection fog to lift into a low stratus cloud deck). Other favorable
conditions include:
16 AFH15-101 5 NOVEMBER 2019

1.1.3.2.1. Coastal areas where moist air is advected over water cooled by upwelling.
During late afternoon, such fog banks may be advected inland by sea breezes or
changing synoptic flow. These fogs usually dissipate over warmer land; if they persist
through late afternoon, they can advect well inland after evening cooling and last until
convection develops the following morning.
1.1.3.2.2. In winter, when warm, moist air flows over colder land. This is commonly
seen over the southern or central United States and the coastal areas of Korea and
Europe. Because the ground often cools by radiation cooling, fog in these areas is called
advection-radiation fog, a combination of radiation and advection fogs.
1.1.3.2.3. Warm, moist air that is cooled to saturation as it moves over cold water
forms sea fog. If the initial dew point is less than the coldest water temperature, sea fog
formation is unlikely. In poleward-moving air, or in air that has previously traversed a
warm ocean current, the dew point is usually higher than the cold water temperature.
Sea fog dissipates if a change in wind direction carries the fog over a warmer surface.
An increase in the wind speed can temporarily raise a surface fog into a stratus deck.
Over very cold water, dense sea fog may persist even with high winds. The movement
of sea fog onshore to warmer land leads to rapid dissipation. With heating from below,
the fog lifts, forming a stratus deck. With further heating, this stratus layer changes into
a stratocumulus cloud layer and eventually changes into convective clouds or dissipates
entirely. Cooling after the heat of the day can cause sea fog to roll back in and restrict
ceilings and visibility again.
1.1.3.3. Specific Forecasting Guidance – Radiation Fog: Radiation fog occurs in air with
a high dew point. This condition ensures radiation cooling lowers the air temperature to
the dew point. The first step in making a good radiation fog forecast is to accurately predict
the nighttime minimum temperature. Additional factors include the following:
1.1.3.3.1. Air near the ground becomes saturated. When the ground surface is dry in
the early evening, the dew- point temperature of the air may drop slightly during the
night due to condensation of some water vapor as dew or frost.
1.1.3.3.2. In calm conditions, this type of fog is limited to a shallow layer near the
ground; wind speeds of 3-7 knots bring more moist air in contact with the cool surface
and cause the fog layer to thicken. A stronger breeze prevents formation of radiation
fog due to mixing with drier air aloft.
1.1.3.3.3. Constant or increasing dew points with height in the lowest 200 to 300 feet,
so that slight mixing increases the humidity.
1.1.3.3.4. Stable air mass with cloud cover during the day, clear skies at night, light
winds, and moist air near the surface. These conditions often occur with a stationary,
high-pressure area.
1.1.3.3.5. Relatively long period of radiational cooling, e.g., long nights and short days
associated with late fall and winter in humid climates of the middle latitudes.
1.1.3.3.6. In nearly saturated air, light rainfall will trigger the formation of ground fog.
1.1.3.3.7. In valleys, radiation fog formation is enhanced due to cooling from cold air
drainage. This cooled air can result in very dense fog.
AFH15-101 5 NOVEMBER 2019 17

1.1.3.3.8. In hilly or mountainous areas, an upper-level type of radiation fog—
continental high inversion fog—forms in the winter with moist air underlying a
subsiding anticyclone. A stratus deck often forms at the base of the subsidence
inversion, then lowers. Since the subsiding air above the inversion is relatively clear
and dry, air at the top of the cloud deck cools by long-wave radiational cooling, which
intensifies the inversion and thickens the stratus layer. A persistent form of continental
high inversion fog occurs in valleys affected by maritime polar air. The moist maritime
air may become trapped in these valleys beneath a subsiding stagnant high-pressure
cell for periods of two weeks or longer. Nocturnal long-wave radiational cooling of the
maritime air in the valley causes stratus clouds to form for a few hours the first night
after the air becomes trapped. These stratus clouds usually dissipate with surface
heating the following day. On each successive night, the stratus cloud deck thickens
and lasts longer into the next day. The presence of fallen snow adds moisture and
reduces daytime warming, further intensifying the stratus and fog. In the absence of air
mass changes, eventually the stratus clouds lower to the ground. The first indicator of
formation of persistent continental high inversion fog is the presence of a well-
established, stagnant high- pressure system at the surface and 700 mb level. In addition,
a strong subsidence inversion separates very humid air from a dry air mass aloft over
the area of interest. The weakening or movement of the high-pressure system and the
approach of a surface front dissipates this type of fog.
1.1.3.3.9. Radiation fog sometimes forms about 100 feet (30 meters) above ground and
builds downward. When this happens, surface temperature rises sharply. Similarly, an
unexpected rise in surface temperature can indicate impending deterioration of
visibility and ceiling due to fog.
1.1.3.3.10. Radiation fog dissipates from the edges toward the center. This area is not
a favorable area for cumulus or thunderstorm development.
1.1.3.4. Specific Forecasting Guidance – Frontal Fog. Frontal fog forms from the
evaporation of warm precipitation as it falls into drier, colder air in a frontal system.
1.1.3.4.1. Pre-frontal, or warm-frontal, fog (Figure 1.2) is the most common and often
occurs over widespread areas ahead of warm fronts. Whenever the dew-point
temperature of the overrunning warm airmass exceeds the wet-bulb temperature of the
cold airmass it‘s replacing, fog or stratus form. Fog usually dissipates after frontal
passage due to increasing temperatures and surface winds.
1.1.3.4.2. Post-frontal, or cold-frontal, fog (Figure 1.3) occurs less frequently than
warm-frontal fog. Slow-moving, shallow-sloped cold fronts characterized by vertically
decreasing winds through the frontal surface, produce persistent, widespread areas of
fog and stratus clouds 150 to 250 miles behind the surface frontal position to at least
the intersection of the frontal boundary with the 850 mb level. Strong turbulent mixing
behind fast-moving cold fronts, characterized by vertically increasing winds through
the frontal surface, often produce stratus clouds but no fog.
18 AFH15-101 5 NOVEMBER 2019

Figure 1.2. Pre-frontal fog associated with a warm front.

Figure 1.3. Post-frontal fog associated with a slow-moving cold front.

1.1.3.5. Snow and Blowing Snow. According to the AMS Glossary of Meteorology,
blowing snow is snow lifted from the surface of the earth by the wind to a height of 2
meters (6 feet) or more, and blown about in such quantities that horizontal visibility is
reduced to less than 7 statute miles. Blowing snow is encoded as BS in surface aviation
weather observations and as BLSN as an obstruction to vision in METAR or SPECI
observations. Blowing snow can be falling snow or snow that has already accumulated but
is picked up by strong winds. Consider the following rules of thumb when forecasting
visibility in snow or blowing snow:
1.1.3.5.1. Moderate, dry, and fluffy snowfall with wind speeds exceeding 15 knots
usually reduces visibility in blowing snow.
1.1.3.5.2. Snow cover that has previously been subject to wind movement (either
blowing or drifting) usually does not produce as severe a visibility restriction as new
snow.
1.1.3.5.3. Snow cover that fell when temperatures were near freezing does not blow
except in very strong winds.
1.1.3.5.4. The stronger the wind, the lower the visibility in blowing snow. The
converse is also true; visibility usually improves with decreasing wind speed.
AFH15-101 5 NOVEMBER 2019 19

1.1.3.5.5. Loose snow becomes blowing snow at wind speeds of 10 to 15 knots or
greater. Although any blowing snow restricts visibility, the amount of the visibility
restriction depends on such factors as terrain, wind speed, snow depth, and
composition.
1.1.3.5.6. Blowing snow is a greater hazard to flying operations in polar regions than
in mid- latitudes because the colder snow is dry, fine and easily lifted.
1.1.3.5.7. Winds may raise the snow 1000 feet above the ground, lowering visibility.
A frequent and sudden increase in surface winds in polar regions may cause the
visibility to drop from unlimited to near zero within a few minutes.
1.1.3.5.8. Fresh snow blows or drifts at temperatures of –20°C (–4°F) or less. After 3
or more days of exposure to direct sunlight, snow forms a crust and does not readily
drift or blow. The crust, however, is seldom uniform across a snowfield. Terrain
undulations, shadows, and vegetation often retard the formation of the crust.
1.1.3.5.9. If additional snow falls onto snowpack that has already crusted, only the new
snow blows or drifts.
1.1.3.5.10. Use Table 1.1 as a guide to forecast visibility based on the intensity of
snow. When forecasting more than one form of precipitation at a time, or when
forecasting fog to occur with the precipitation, consider forecasting a lower visibility
than shown in Table 1.1

Table 1.1. Visibility limits based on snowfall intensity.
Intensity Visibility Limits (statute miles)
Light snow showers Greater than ½ mile
Moderate snow showers Greater than ¼ mile but less than ½ mile
Heavy snow showers Less than ¼ mile
1.1.3.6. Haze. Research shows that the primary constituent of haze droplets over industrial
areas, such as the central and eastern United States and parts of Asia, is sulfuric acid. In
these areas, sulfur dioxide released from industry (such as oil refining and steel
manufacturing) bonds with oxygen in oxidation reactions enhanced by sunlight and/or
liquid water. These reactions result in the formation of sulfate aerosols, include sulfuric
acid. Sulfate aerosols are hygroscopic (they absorb water from the environment), even at
relative humidities as low as 70%, making them effective condensation nuclei. When the
environment is supersaturated, sulfate aerosols grow large enough to be seen as clouds.
When the humidity is low, however, they only grow to around a tenth of a micrometer in
diameter, and remain suspended in the atmosphere to form haze. Haze usually occurs in
the planetary boundary layer (PBL), which extends from the surface up to about 2 km on
average, but can extend up to 500 mb in places like Southwest Asia. The top of the PBL is
delineated by a temperature inversion and a cessation of vertical mixing, and this is
typically the upper boundary of a haze layer. However, elevated layers of haze may also
occur, such as in regions downstream from where particles have been lofted above the PBL
by cumulus clouds. Elevated haze is also possible on the poleward side of fronts. Sulfate
aerosols are chemically stable, and as such, settle very slowly. Therefore, in the absence of
a cleansing mechanism such as precipitation, haze can persist for days. This is especially
true when atmospheric conditions are stagnant, such as under a persistent area of high
20 AFH15-101 5 NOVEMBER 2019

pressure. Here, limited mixing, plenty of sun, and increasing boundary layer moisture
create particularly favorable conditions for the formation of sulfate aerosols. Haze
normally restricts visibility to 3 to 6 miles, and occasionally to less than 1 mile. It usually
dissipates when the atmosphere becomes thermally unstable or wind speeds increase. This
can occur with heating, advection, or turbulent mixing.
1.1.3.7. Dust Storms. Dust storms are a function of wind speed, wind direction and soil
moisture content. After generating blowing dust upstream, wind speed becomes important
in advection of the dust. Dust may be advected by winds aloft when surface winds are weak
or calm. Duration of the advected dust is a function of the depth of the dust and the
advecting wind speeds. Synoptic situations, such as cold frontal passages, may change both
the wind direction and the probability of dust advecting into your area.
1.1.3.7.1. Dust Source Regions. Forecasting dust generation is more difficult than
forecasting the advection of observed dust into the area; there are several key factors
to keep in mind, including the following common dust source regions:
1.1.3.7.1.1. Deserts. Dust storms occur in regions with little vegetation and
precipitation; these conditions are most prevalent in deserts, where rainfall is
scarce. In general, dust is unlikely within 24 to 36 hours of a rainstorm, but
rainstorms can lead to increased dust potential beyond 36 hours. Runoff after heavy
rain carries soil particles picked up by erosion; once the water evaporates, these
particles can be easily lofted.
1.1.3.7.1.2. Agricultural areas. Agricultural land that is fallow, recently tilled, or
has a marginal growing climate is a potential source area for dust. The mechanical
breaking of soil creates an environment rich in fine-grained soil that is picked up
and moved by seasonal winds. This is commonly observed in northern Syria and
Iraq.
1.1.3.7.1.3. Coastal areas. Dust plumes can be generated in advance of cold fronts
moving across sandy or silty coastal regions.
1.1.3.7.1.4. River flood plains (alluvial plains). The flood plain of the Tigris and
Euphrates Rivers in southern Iraq serves as the source region for many dust storms,
particularly during shamal events - a northwesterly wind that blows over Iraq and
the Persian Gulf states. Shamals are often strong during the day and decrease in
strength at night.
1.1.3.7.1.5. Dry lake beds. Water in lakes erodes rocks and forms fine-grained
soils. When lakes dry up, these soils inhibit plant growth and blow easily in strong
winds.
1.1.3.7.2. Dust Lofting Mechanisms. After an appropriate source, the next key
ingredient for dust storm generation is wind from the surface through the depth of the
boundary layer strong enough to move and loft dust particles. Table 1.2 shows
threshold dust-lofting wind speeds for different desert environments. The first sand and
dust particles that move are those from 0.08 to 1 mm in diameter; this occurs with wind
speeds of 10 to 25 knots. In general, winds at the surface need to be 15 knots or greater
to mobilize dust. Once a dust storm starts, it can maintain the same intensity even when
wind speeds slow to below initiation levels, since the bond between dust particles and
AFH15-101 5 NOVEMBER 2019 21

the surface is already broken. Lofting of dust also requires turbulence in the boundary
layer. Typically, wind shear creates the turbulence that lofts dust up and away from the
surface. As a rule of thumb, if the wind at the surface is blowing 15 knots, the wind at
1000 feet) must be about 30 knots to keep the dust particles aloft. An unstable boundary
layer, which favors vertical motions, is also necessary for dust lofting. With the lack of
vegetation in dust-prone regions, the ground can experience extreme daytime heating,
which creates an unstable boundary layer. As the amount of heating increases, the
unstable layer deepens. In contrast, stable boundary layers suppress vertical motions
and inhibit dust lofting. Diurnal effects also impact dust storm potential. Dry desert air
has a wide diurnal temperature difference. Strong radiative cooling leads to rapid heat
loss after sunset, resulting in a surface-based inversion, which may inhibit dust lofting.
However, the formation of a surface-based inversion has little effect on dust that is
already suspended higher in the atmosphere. Furthermore, if winds are sufficiently
strong, they will inhibit the formation of an inversion or even remove one that has
already formed. Table 1.3 shows favorable parameters for dust storm generation in
various scenarios.

Table 1.2. Threshold dust-lofting wind speeds for different desert environments.
Environment Threshold Wind Speed
Fine to medium sand in dune-covered areas 10 to 15 mph (8.7 to 13 knots)
Sandy areas with poorly developed desert pavement 20 mph (17.4 knots)
Fine material, desert flats 20 to 25 mph (17.4 to 21.7 knots)
Alluvial fans and crusted salt flats (dry lake beds) 30 to 35 mph (26.1 to 30.4 knots)
Well-developed desert pavement 40 mph (36.8 knots)

Table 1.3. Favorable conditions for the generation and advection of dust.
Parameter or Condition Favorable When
Location with respect to source region Located downstream and in close proximity
Agricultural practices Soil left unprotected
Previous dry years Plant cover reduced
Wind speed 30 knots or greater
Wind direction Significant dust source is upstream
Cold front Passes through the area
Squall line Passes through the area
Leeside trough Deepening and increasing winds
Thunderstorm Mature storm in local area or generates
blowing dust upstream
Whirlwind In local area
Time of day 1200 to 1900L
Surface dew point depression 10 C or greater
1.1.3.7.3. Dust Removal Mechanisms. Lofted dust eventually settles, but may travel
half way around the globe before doing so. The three most common dust removal
mechanisms are dispersion, advection, and entrainment in precipitation.
22 AFH15-101 5 NOVEMBER 2019

1.1.3.7.3.1. Dispersion. Dust plumes tend to fan out as they move downstream
from their source regions; this is caused by dispersion. At the most basic level, the
more air that entrains into a dust plume, the more the plume dilutes, spreads out,
and disperses. Dispersion is primarily influenced by turbulence, which mixes
ambient air with the dust plume. Any increase in turbulence increases the rate at
which the plume disperses. There are three kinds of turbulence that act to disperse
a plume - mechanical, caused by air flowing over features such as hills or buildings;
shear, resulting from differences in wind speed and/or direction; and buoyancy,
caused by parcels of air rising during the diurnal heating of the surface.
1.1.3.7.3.2. Advection. Advection moves dust away from its source; winds aloft
may carry dust in a direction different from the wind direction at the surface. When
predicting where a dust plume will travel, check the vertical wind profile. Dust that
leaves the ground going one direction can rise to a level where it travels in an
entirely different direction.
1.1.3.7.3.3. Entrainment in precipitation. Most dust particles are hygroscopic, or
water-attracting. In fact, dust particles usually form the nucleus of precipitation.
Because of this affinity to moisture, precipitation very effectively removes dust
from the troposphere.
1.1.3.7.4. Dust storm types. Several types of dust storms, including shamal, frontal,
and convective, are described below. The shamal is unique to the Middle East, but
frontal and convective dust storms can be experienced in other arid regions, including
the Southwestern United States.
1.1.3.7.4.1. Summer shamal. The term “shamal” comes from the Arabic word for
“north,” and describes a type of dust storm caused by prevailing north winds over
the Arabian Peninsula, Iraq, and Kuwait. Typical sources for the dust lie between
the Tigris and Euphrates rivers. The summer shamal, also known as the “Wind of
120 days,” is nearly constant from June through September across Syria, Saudi
Arabia, and Iraq. It is caused by convergence between the Southern Arabian
Peninsula Monsoon Trough and the subtropical ridge that extends from the
Mediterranean Sea into Iraq and the northern Arabian Peninsula. Additionally, cold
air advection aloft causes steep lapse rates and increased instability. The end result
is that updrafts keep dust particles suspended, sometimes at high altitudes. Due to
the dry desert air and high rate of thermal radiation during the day, a nocturnal
radiational inversion is established almost every night across Southwest Asia
(SWA) as the desert floor cools. The inversion is usually quite shallow, extending
up to 1000-2000 feet above ground level. Above the inversion, a nocturnal low-
level jet (LLJ) stream is often established. When the inversion collapses or is mixed
out during the ensuing daylight hours, the strong LLJ winds can reach the surface
and are also a source of the summer shamal, as long as they exceed 15 knots.
Summer shamal dust storms are typically 3000-8000 feet tall, but can extend up to
15,000-18,000 feet. Visibilities can go from unrestricted to zero within minutes and
remain that way for 1-3 hours before slowly starting to increase. Dust storms can
last from 1-10 days depending on the wind flow pattern and atmospheric stability
profile, but 3 days is average.
AFH15-101 5 NOVEMBER 2019 23

1.1.3.7.4.2. Winter shamal. Many winter shamal dust storms are associated with
passing cold fronts, which are classified as “frontal dust storms.” A few, however,
are caused as very cold air masses funnel south or southeastward from Turkey or
Syria into the Tigris/Euphrates River Valley. These cold air masses maintain
temperature and moisture continuity as they descend the Arabian Peninsula,
creating a relatively sharp temperature gradient between the leading edge of the air
mass and the surrounding air. Because the air mass is much colder than the
surrounding air, it lifts the warmer and more buoyant ambient air, as well as dust if
the ambient vertical temperature profile is conditionally unstable aloft. This
physical mechanism, known as a density current, is the same mechanism that lofts
dust when a thunderstorm downdraft reaches the surface, causing a haboob.
1.1.3.7.4.3. Frontal dust storms. The main difference between frontal dust storms
and shamals is a matter of scale; shamals are localized, mesoscale phenomena,
while frontal dust storms are caused by synoptic-scale systems whose winds carry
sand particles over large distances. They accompany low pressure systems and
associated frontal boundaries. The three major varieties are prefrontal, postfrontal,
and shear-line.
1.1.3.7.4.3.1. Prefrontal. Prefrontal dust storms occur across much of SWA as
low pressure systems move across the region. The polar front jet stream located
behind a cold front and the subtropical jet stream located ahead of a cold front
can converge into a single jet streak (or jet max) that translates to the surface in
the left front quadrant. Ageostrophic circulations associated with the divergent
(left-front and right-rear) quadrants of the jet streak also increase upward
vertical velocities, which enhance the probability of dust lofting as well.
Prefrontal winds are called the Sharqi in Iraq, the Kaus in Saudi Arabia, the
Shlour in Syria and Lebanon, and the Khamsin in Egypt. Easterly to southerly
prefrontal winds are favored for prefrontal dust storms in October and
November, but such plumes will rarely be long-lived given their prefrontal
nature. Wind speeds are 10-20 knots on average, although gusts of 25-30 knots
do occur. Prefrontal dust storms can be difficult to detect in METSAT imagery
because they are short-lived and often located over similarly shaded terrain.
Cloud cover due to pre-cold frontal overrunning often obscures these types of
dust storms from METSAT view.
1.1.3.7.4.3.2. Postfrontal. Postfrontal dust storms are associated with a
dynamic weather feature (e.g., cold front); cloudiness associated with the cold
front may mask the dust signature in METSAT imagery, but in most cases the
dust “head” is the best indicator of the leading edge of the cold air. Given their
stronger mechanical forcing, postfrontal dust storms usually reach greater
heights than those associated with shamal winds. They typically reach 8,000-
15,000 feet, but postfrontal dust has been observed up to jet stream level
(~30,000 feet). Surface winds are 15-30 knots on average, but gusts of 40-50
knots may occur with very strong low pressure systems. Wind speed can be
estimated by the thermal contrast across the front. A temperature change of
10°C corresponds to a maximum wind speed of 30 knots, with a 5 knot increase
for every additional 5°C. There are two types of postfrontal dust storms: The
24 AFH15-101 5 NOVEMBER 2019

first type lasts 24-36 hours as a cold frontal system migrates across SWA. Dust
moves across the Persian Gulf in 12-24 hours, and the cold front can reach the
southern Arabian Peninsula in 48-72 hours. The second type lasts 3-5 days and
occurs when a weaker cold front (typically in early autumn) stalls out and
becomes stationary. Cyclogenesis occurs along the stationary boundary, with
frontal waves moving to the east-northeast.
1.1.3.7.4.3.3. Shear line. These dust storms are common in winter along the
Arabian Peninsula, Red Sea, and in the equatorial regions of Africa. Trade
winds from the east converge with a polar high pressure system, resulting in a
narrow band of accelerated flow. This creates enough turbulence to lift dust
particles into the atmosphere. Being slightly warmer than the cool air, the dust
is sometimes apparent on infrared satellite imagery. A similar situation is
observed on the Arabian Sea when a cold front weakens across the India-
Pakistan border. A shear line is produced, which can yield a rope cloud if
sufficient moisture is present. Wind speeds are typically 10-25 knots, with gusts
to 40 knots. Visibility typically remains 1-3 nautical miles.
1.1.3.7.4.4. Convective dust storms. Convective dust storms are very difficult to
forecast, partially because they are typically a small-scale phenomenon (e.g., dust
devils may be only tens of meters in width). Microbursts are particularly dangerous
for aircraft, given the reduced visibility and unpredictable nature of high winds.
1.1.3.7.4.4.1. Dust devils. Dust devils occur throughout much of the world;
they’re created by strong surface heating under clear skies and light winds when
the sun warms the air near the ground to temperatures well above those just
above the surface layer. Once sufficient heating is achieved, a localized pocket
of air quickly rises through the cooler air above it. Hot air rushes in to replace
the rising air at the bottom of the developing vortex, intensifying the spinning
effect. Once formed, the dust devil is a funnel-like chimney through which hot
air moves both upwardly and circularly. The dust devil persists until the supply
of warm, unstable air is broken or depleted. Dust devils are typically smaller
and less intense than tornadoes, although the strongest dust devils can achieve
the intensity of a weak tornado. Dust devil diameter is typically between 10 and
300 feet (3 to 90 meters), with an average height of 500 to 1000 feet (150 to
300 meters). Dust devils typically last only a few minutes, but may persist for
up to an hour in optimal conditions.
1.1.3.7.4.4.2. Haboobs. A haboob is an intense dust storm generated by the
convective outflow from a collapsing or ongoing thunderstorm, or from any
collapsing cumuliform cloud of appreciable vertical extent. Haboobs are most
frequent in the deserts of northern Africa, but they also occur in SWA and the
southwestern United States. Because low-level air is so dry in desert
environments, any precipitation that falls into it will quickly evaporate (or
sublimate in the case of ice crystals). This cools the ambient air, making it
negatively buoyant with a tendency to sink towards the surface. As long as the
wet bulb potential temperature of the sinking air (downdraft) remains cooler
than the potential temperature of the air at the surface by at least 4°C, that air
will continue to the surface unimpeded and spread out in all directions, but with
AFH15-101 5 NOVEMBER 2019 25

a stronger component in the direction of the low-level winds. The air that
reaches the surface is colder and therefore denser than the ambient
environmental air, so the downdraft air will act like a wedge that rapidly lifts
the positively buoyant warm air around it. While this is happening, any dry soil
at the cold air/warm air interface has the potential to be lofted to great heights
and propagate in the direction of the average cloud-bearing layer winds - this
intense dust event is the haboob. The haboob environment is usually
characterized by a surge of midlevel moisture, with a dry adiabatic lapse rate
below that. Some elevated instability usually exists in the form of a “best lifted
index” (the most unstable lifted index) less than 0. Haboobs usually travel an
average of 60-90 miles, but can travel greater distances if the convective
outflow is strong enough, the low-level winds are strong enough, and/or the
vertical temperature profile is dry adiabatic over a large area. Most haboobs
reach a height of 5000-8000 feet, but some can ascend to 10,000-14,000 feet.
Peak winds in the haboob are approximately 95% greater than the speed of
movement. Duration varies, but can reach up to six hours.
1.1.4. Visibility Forecasting Aids and Techniques – Fog.
1.1.4.1. AFW Ensemble Visibility Forecasts. Air Force Weather’s ensemble products (the
Global Ensemble Prediction Suite (GEPS) and the Mesoscale Ensemble Prediction Suite
(MEPS) use statistical regression analyses of relative humidity, precipitable water, and
surface wind speed to produce visibility probability products, available from the AFW-
WEBS ensembles page at
https://weather.af.mil/confluence/display/AFWWEBSTBT/Ensembles+Main+Page.
Each ensemble produces probability products for visibilities less than five, three, and one
statute miles.
1.1.4.2. Visibility Climatology. The 14th Weather Squadron (https://climate.af.mil) is
the Air Force’s climatology center, and operates and maintains a vast library of
climatological data. For fog forecasting, their most useful products are wind stratified
conditional climatologies (WSCC), surface climograms, and operational climatic data
summaries (OCDS-II).
1.1.4.2.1. Wind Stratified Conditional Climatologies (WSCC). Given a set of initial
conditions (month, time of day, wind direction, ceiling height, and visibility), WSCCs
indicate the percentage likelihood that a particular visibility category will be observed
at a future hour (Figure 1.4). The output can be used as a baseline for constructing fog
forecasts in areas that are conducive to fog formation.
26 AFH15-101 5 NOVEMBER 2019

Figure 1.4. WSCC example.

1.1.4.2.2. Surface Climograms. A climogram is a two-dimensional view of the
likelihood of an event’s occurrence; many weather parameters are available, including
fog. Figure 1.5 is a surface climogram for Vandenberg AFB, showing the likelihood
of visibility less than 5 statute miles for all hours of the day and all months of the year.

Figure 1.5. Visibility Climogram example for Vandenberg AFB.

1.1.4.2.3. Operational Climatic Data Summaries (OCDS-II). The OCDS-II web
application enables users to generate plots of fog frequency, stratified by time of day
and month of the year, for a user-selected station (Figure 1.6).
AFH15-101 5 NOVEMBER 2019 27

Figure 1.6. OCDS-II example.

1.1.4.3. Radiation Fog Point (FP). The radiation fog point is the temperature (in °C) at
which radiation fog forms. To find the FP, first find the pressure level of the LCL. From
the dew point at the LCL, follow an isohume (line of constant saturation mixing ratio)
down to the surface; the temperature value where the isohume intersects the surface is the
radiation fog point. For an example of this calculation, refer to Figure 1.7 In the example,
the LCL is at 630 mb, and the dew point at the LCL is -40°C. Following the isohume down
to the surface from that dew point value, the FP is determined to be -36°C.

Figure 1.7. Radiation Fog Point example.
28 AFH15-101 5 NOVEMBER 2019

1.1.4.4. Radiation Fog Threat (FT). The radiation fog threat indicates the potential for
radiation fog formation; it’s calculated by subtracting the radiation fog point (see the
previous section for details) from the 850 mb wet-bulb potential temperature (WBPT850).
If not already known, WBPT850 is found by first finding the pressure level of the 850 mb
LCL, and then lowering the parcel moist adiabatically to 1000 mb; the point at which the
lowered parcel intersects the 1000 mb level is the WBPT850. Refer to Table 1.4 to
determine the likelihood of radiation fog formation.

Table 1.4. Fog threat thresholds, indicating likelihood of radiation fog formation.
Fog Threat Value Likelihood of radiation fog formation
Greater than 3 Low
Between 0 and 3 Moderate
Less than 0 High

Fog Threat Value = WBPT850 – Fog Point

1.1.4.5. Radiation Fog Stability Index (FSI). The radiation fog stability index uses a
representative 1200Z sounding to give the likelihood of radiation fog formation, and is
defined in Table 1.5

Table 1.5. Fog Stability Index (FSI) thresholds, indicating likelihood of radiation fog
formation.
FSI Value Likelihood of radiation fog formation
Greater than 55 Low
Between 31 and 55 Moderate
Less than 31 High

FSI = 4TSfc - 2(T850 + TdSfc) + W850

TSfc = Surface temperature in °C. T850 = 850 mb temperature in °C.
TdSfc = Surface dew point in °C. W850 = 850 mb wind speed in knots.

1.1.4.5.1. The FSI is indicative of radiation fog potential if there’s strong static stability
between the surface and 850 mb, as indicated by increasing temperatures with height
in the layer.
1.1.4.5.2. FSI is also indicative of radiation fog potential if there’s ample moisture in
the layer, indicated by the surface dew point depression (i.e., the difference between
the surface temperature and dew point).
1.1.4.5.3. Finally, FSI is also indicative of radiation fog potential if there are slow wind
speeds at 850 mb, which aren’t conducive to mixing drier ambient air into the fog layer.
1.1.5. Visibility Forecasting Aids and Techniques – Dust.
1.1.5.1. AFW Ensemble blowing dust forecasts. The GEPS and MEPS produce blowing
dust probability products, available on AFW-WEBS, for visibilities less than five, three,
and one statute miles.
AFH15-101 5 NOVEMBER 2019 29

1.1.5.2. Satellite detection of dust. Satellite detection of dust is difficult, especially at night
and in single channel imagery. Enhanced RGB satellite imagery and Aerosol Optical Depth
(AOD) have somewhat eased these difficulties. Satellite animations (especially daytime
visible imagery) can help identify the location of dust, since the movement of the dust
plume makes it stand out against the stationary land surface. Animated infrared imagery
can also be used to track dust over land during the day, since the dust contrasts against the
hot land surface. Infrared imagery is not as useful at night, since the land cools and the
contrast between the dust and land decreases.
1.1.5.2.1. Daytime detection. In general, dust is easier to detect during the day than at
night, although there are some differences depending on the time of day. Figure 1.8
depicts visible (A) and infrared (B) Moderate Resolution Imaging Spectroradiometer
(MODIS) images, respectively. In the visible image, dust is easily discernible over the
Red Sea, but more difficult to observe over the adjoining land; in visible imagery, dust
stands out over the dark water background, but blends in with the sandy land surface.
The opposite is true in the infrared image; here, dust is clearly depicted over land, but
not over the Red Sea. The dust over land is cooler than the underlying surface, and thus
detectable on infrared imagery. Over the Red Sea, the thermal contrast is lessened, and
the dust disappears.

Figure 1.8. Visible (A) and infrared (B) comparison of dust detection capability.

1.1.5.2.2. Sunrise and sunset detection. Dust detection in visible satellite imagery at
sunrise and sunset varies from detection during the day. If a satellite is looking in the
general direction of the sun and the dust, the forward scattering of dust particles
heightens the reflection from dust. Conversely, if the satellite is looking away from the
sun, backscattering occurs. Now, less solar energy is being reflected back to the
satellite, reducing the ability to detect dust. An example of forward scattering is shown
in Figure 1.9; a large dust cloud is seen progressing across the Arabian Peninsula at
dawn. This dust plume would be difficult to detect in the middle of the day.
30 AFH15-101 5 NOVEMBER 2019

Figure 1.9. Sunrise dust plume detection, due to forward scattering.

1.1.5.2.3. Aerosol Optical Depth (AOD). AOD is a unit-less measure of the amount of
light that airborne particles, such as dust, smoke, haze, and pollution, prevent from
passing through a column of the atmosphere. AOD doesn’t provide surface visibility
estimates (since the dust detected could reside anywhere in the vertical column), but it
can serve as a first-order indicator of potential reduced surface visibilities. Figure 1.10
shows a sample AOD product over Southwest Asia, with warm colors indicating the
presence of atmospheric dust.

Figure 1.10. AOD product, showing areas of atmospheric dust.
AFH15-101 5 NOVEMBER 2019 31

1.1.5.3. Surface Climograms. Climatology can aid in dust forecasting, the surface
climogram product can provide a two-dimensional view of the likelihood of reduced
visibility due to dust at any hour and month of the year (refer to paragraph 1.1.4.2.2. for
details.)
1.1.5.4. Forecasting haboobs from ongoing thunderstorms. First, determine if elevated
instability is present (represented by a “best lifted index” less than 0), then look for high
mid-level moisture (e.g., high relative humidity between 700 and 500 mb) and steep (dry
adiabatic) lapse rates between the surface and approximately 18,000 feet. If all these factors
are present, find the strongest wind at any level aloft where the wet bulb potential
temperature is less than the surface potential temperature by at least 4°C; this wind may be
brought to the surface.
1.1.5.5. Forecasting haboobs from collapsing thunderstorms. Thunderstorm collapse is
most likely after sunset when buoyancy diminishes. To determine haboob potential, first
find the cloud base height of the thunderstorm. The higher it is (particularly greater than
10,000 feet), the weaker the potential haboob. Rapidly warming cloud tops in infrared
satellite imagery are indicative of an imminent collapse.
1.1.5.6. Autumn dust storm forecast process.
1.1.5.6.1. Determine the mission scenario. Determine the time period of interest;
you’ll be interested in any dust events that may occur during this time period which
may rapidly restrict visibility or negatively impact any missions scheduled or ongoing
in your AOR.
1.1.5.6.2. Examine thunderstorm and blowing dust climatology. Refer to AFW-WEBS
and the 14th Weather Squadron to determine the climatological likelihood of dust
storms at your location.
1.1.5.6.3. Examine a recent dust source region database. Examine the most recent
analysis of dust source regions; couple climatology data with historical dust source
region information to determine where dust events are most likely to develop.
1.1.5.6.4. Examine a recent soil moisture profile. From AFW-WEBS, examine a 0.25
degree (25 km) resolution 0-10 cm soil moisture profile; locations shaded yellow, light
orange, or brown are considered dry. Consult a chart of local soil types determine which
soil is most likely to be lofted. Sandy soils drain easier than clay soils and will be more
prone to dust lofting, although lofting potential depends strongly on particle size as
well.
1.1.5.6.5. Analyze the synoptic environment. At the 200-300 mb level, look for long
wave troughs and ridges, as well as jet maxima (or jet streaks). Note the magnitude of
jet maxima and areas of divergence in the left front or right rear quadrants. At the 500
mb level, look for shortwave ridges and troughs embedded in the long wave pattern.
Also look for areas of positive or negative vorticity advection, and take note of
temperatures at 500 mb as indicators of warm or cold air aloft as well as dew points as
indicators of dry air aloft. Soundings are also useful when diagnosing mid-level
tem