Chapter 8
Vertical Motion and Clouds
DGCA CPL/ATPL Study Notes — Aviation Meteorology
Compiled by Capt. Pankaj Pahil
Source: IC Joshi — Aviation Meteorology
1. Causes of Vertical Motion
Definition: Vertical motion in the atmosphere — either upward (ascent) or downward (subsidence) — is driven by several mechanisms. Rising air leads to cooling, condensation and cloud/precipitation formation; sinking air produces warming and clear skies.
Five Main Causes
| Cause | Mechanism | Effect |
|---|
| Terrain (Orographic) | Air forced up windward slope; eddies/instability on leeward. Mountain waves on leeward with strong winds. | Nacreous Clouds form due to mountain waves transporting WV to upper stratosphere |
| Convection | Surface heating → air rises as thermals. Gliders use thermals. | CU and CB form; strong up/down draughts |
| Pressure Systems | Low/Cyclone → convergence → ascent; High/Anticyclone → divergence → subsidence | Lows = bad wx; Highs = fine wx |
| Frontal Zones | Warm front: gradual ascent over wide area; Cold front: sharp/abrupt uplift | WF: steady rain; CF: convection, TS, squally wx |
| Wind Shear | Vertical wind shear creates strong eddies. CAT at jet stream amplified by mountain waves. | Turbulence, CAT |
flowchart TD
A[Causes of Vertical Motion] --> B[Terrain/Orographic]
A --> C[Convection/Thermals]
A --> D[Pressure Systems]
A --> E[Frontal Zones]
A --> F[Wind Shear]
B --> G[Mountain Waves → Nacreous Clouds]
C --> H[CU & CB formation]
D --> I[Low → Ascent; High → Subsidence]
E --> J[WF: Gradual; CF: Abrupt uplift]
F --> K[CAT amplified near Jet Stream]
2. Convergence and Divergence
Convergence: Net horizontal inflow of air into a region. Air accumulates → ascent in lower levels → possible subsidence above tropopause (stratosphere acts as stable barrier). Lows, cyclones, depressions and troughs → convergence → bad weather, but better visibility except in precipitation.
Divergence: Net horizontal outflow of air from a region. Example: wind to W is Wly 10 kt and to E is Wly 20 kt → more outflow than inflow = divergence. Anticyclones and ridges → subsidence → fine weather but poor visibility conditions.
| Parameter | Convergence | Divergence |
|---|
| Air flow | Inflow | Outflow |
| Vertical motion (low level) | Ascent (Convection) | Subsidence |
| Pressure systems | Lows, Cyclones, Depressions, Troughs | Highs, Anticyclones, Ridges |
| Weather | Bad weather | Fine weather |
| Visibility | Better (except in precip) | Poor |
Mnemonic: CONvergence = CONdensation (bad wx). DIVergence = DIVe (air dives down) = Subsidence = Fine wx, hazy.
3. Clouds — Classification
Cloud: An aggregate of visible water droplets or ice particles. Clouds form by adiabatic lifting and cooling until air saturates. The level at which this occurs is the Lifting Condensation Level (LCL). Deposition = process by which water vapour directly changes into ice particles.
There are 10 major genera classified by Form (Stratiform, Cumuliform, Cirriform) and Height (High, Medium, Low).
Cloud Height by Region
| Level | Polar Region | Temperate Region | Tropical Region |
|---|
| High | 10,000–25,000 ft (3–8 km) | 16,000–45,000 ft (5–13 km) | 20,000–60,000 ft (6–18 km) |
| Medium | 6,500–13,000 ft (2–4 km) | 6,500–23,000 ft (2–7 km) | 6,500–25,000 ft (2–8 km) |
| Low | up to 6,500 ft (2 km) | up to 6,500 ft (2 km) | up to 6,500 ft (2 km) |
4. High Clouds
High clouds in tropics occur at 6–18 km, consist of ice crystals, some may cause precipitation confined to high/medium levels only. Give advance indication of impending weather.
Cirrus (CI)
White and fibrous, delicate filaments or patches, narrow bands. Composed of ice crystals. Do not cause precipitation or ice accretion.
Cirrostratus (CS)
Thin whitish veil of fibrous or smooth appearance. Covers almost whole sky. Produces Halo — a coloured circular ring around sun or moon with violet colour inside. When thick may cause any ice fall, remaining confined to high/medium levels. Hardly any ice accretion.
Cirrocumulus (CC)
Thin, white, wave-like very small puffs. Composed of ice crystals. Sky visible in between puffs. Do not cause precipitation; hardly any ice accretion.
Memory Aid — High Clouds (3 Cirro): CI CS CC = all ice crystals, no serious precip or icing. CS = produces HALO. CC = mackerel sky.
5. Medium Clouds
In tropics at 2–8 km. Contain water droplets and ice. Can cause snow and rain.
Altocumulus (AC)
White-grey clouds, patches, puffs, rounded masses, rolls, etc. Round masses generally well arranged in long waves, rows or lanes. Sky visible between puffs. Altocumulus Lenticularis = lens-shaped clouds at crests of mountain waves on leeward side of high mountains. No precipitation; may cause ice accretion.
Altostratus (AS)
Uniformly greyish or whitish cloud sheets/layers of fibrous appearance. Totally or partly cover the sky. If thin → see sun through it like ground glass. Optical phenomenon Corona occurs in AS. Thick AS: continuous rain or snow. Ice accretion possible below freezing temperatures.
Warning: Thick Altostratus causes continuous rain or snow. Ice accretion is possible below freezing temperatures in AS.
6. Low Clouds
In tropics below 2 km. Consist of water droplets or ice crystals.
Stratus (ST)
Grey cloud layer with uniform base. May stretch horizon to horizon. May give drizzle, ice prisms or snow grains. ST touching ground = fog. Ragged/patchy ST = Fracto Stratus.
Stratocumulus (SC)
Low clouds of large, irregular puffs or rolls, gray or whitish. Regularly arranged. No serious precipitation.
Nimbostratus (NS)
Dark and grey thick cloud layer. Causes continuous rain or snow. Thick enough to blot out the sun. Extends both medium and lower levels. Ice accretion possible below freezing. Ice Pallets fall from thick NS clouds especially in Warm Fronts. Ice pallets are transparent ice particles, spherical/irregular, about less than 5 mm dia.
Aviation Warning: NS = continuous rain/snow + ice accretion risk below freezing = avoid or be aware during approach/departure.
7. Clouds with Vertical Development
Cumulus (CU)
Detached clouds, dense with sharp outlines. Base dark, nearly horizontal. Develop vertically as rising mounds, domes or towers. Bulging upper part resembles a cauliflower. Sunlit parts brilliant white. Base sometimes ragged = Fracto Cumulus. A well-developed CU with great vertical extent = Towering Cumulus (TCU).
Fair Weather Cumulus
Limited vertical extent. Caused by thermal currents due to surface heating. Occur during daytime only, develop in forenoon, reach max in afternoon, dissipate in evening. Do not cause precipitation.
Cumulonimbus (CB)
Heavy and dense cloud of large vertical extent, like mountains or huge towers. Upper portion mostly smooth, fibrous and nearly flattened — spreads out like an anvil. Base often very dark. Low ragged cumulus fracto or stratus fractus sometimes present below. Virga = shaft of rain or snow falling from distant cloud which vapourises before reaching the ground.
CB causes ALL types of precipitation: RA, SH, GR, SN.
Hail may be experienced under the anvil of a CB.
CB is the most hazardous cloud for aviation and should be avoided.
Flying through active CB cloud should be avoided during TS. Severe turbulence, icing, lightning, hail possible 20–30 nm around a CB.
flowchart LR
CU[Cumulus CU] -->|grows| TCU[Towering Cumulus TCU]
TCU -->|further development| CB[Cumulonimbus CB]
CB --> P1[Rain RA]
CB --> P2[Showers SH]
CB --> P3[Hail GR]
CB --> P4[Snow SN]
CB --> P5[Virga]
CB --> P6[Anvil Top]
8. Very High Level Clouds
Nacreous Clouds (Mother of Pearl Clouds)
Infrequent. Mainly from Scotland and Scandinavia. Resemble Cirrus or Altocumulus Lenticularis. Show very strong irisation (rainbow coloured patches). May be composed of ice crystals or supercooled water droplets. Form in the upper Mesosphere.
Noctilucent Clouds
Resemble Cirrus but have bluish, silvery or orange/red colour. Occur in upper Mesosphere between 80–85 km. Visible soon after sunset or before sunrise between 72°N and 45°N, mostly around 55°N, in summers (late May–mid August). Thought to consist of ice particles (not meteoric dust, as originally believed).
9. Cloud Base, Amount & Ceiling
Reporting Cloud Base
In METAR, SPECI, TAF and Local Forecast: cloud base reported from Above Ground Level (AGL).
In Area Forecast Charts: cloud base from Above Mean Sea Level (AMSL).
Cloud Amount (Oktas)
| Oktas | 1–2 | 3–4 | 5–7 | 8/8 | Nil | Sky not visible |
|---|
| Term | FEW | SCT (Scattered) | BKN (Broken) | OVC (Overcast) | SKC (Sky clear) | Sky Obscured |
| Sky Condition | Fine | Fair | Partly cloudy | Cloudy | Fine | Sky Obscured |
Cloud Ceiling
Cloud Ceiling: Height, above ground or water surface, of the lowest layer of cloud below 6000 m (20,000 ft) covering more than half the sky (5/8 or more).
Cloud Amount in Imaginary Oktas
For expressing cloud amount, the sky is divided into eight imaginary parts. Each part is called one Okta.
Operational Significance: A cloud with a base below 1500 m (5000 ft) or at or below the highest minimum sector altitude, whichever is greater, is of operational significance.
10. Cloud Species
| Species | Description | Applicable Cloud Types |
|---|
| Fibrous | Filament form without tufts or hooks | Ci, CS, CC |
| Lenticularis | Elongated lens-shaped | AC, SC or CC |
| Castellaneous | Cumuliform protuberances connected by common base, arranged in lines | CI, CC, AC or CU |
| Fractus | Ragged | ST or CU |
| Congestus | Strong sprouting/great vertical development, bulging resembles cauliflower | CU |
| Calves | Cirrus at top, some protuberances begin to change to fibrous | CB (without distinct anvil) |
| Capillatus | Distinct anvil. Accompanied by SH, TS, SQ and GR. Produces well defined Virga. | CB |
Exam Tip: CB Capillatus = distinct anvil = all precipitation types. CB Calves = developing CB, no distinct anvil yet.
11. Condensation Trails (Contrails)
Condensation trails = visible streaks of condensed water vapour formed in the wake of a moving aircraft.
| Type | Description |
|---|
| Wing Tip Trails | Thin, transient, short-lived. Form near wing tips and propeller edges due to aerodynamic reduction of pressure, expansion and consequent adiabatic cooling and condensation. |
| Exhaust Trails | Form from condensation of moisture from aircraft exhaust at about 9 km and above. Long, persistent, visible. Reveal position and track of aircraft. |
| Distrails (Dissipation Trails) | Passage of aircraft through a cloud marked by clear lanes. The heat released by aircraft exhaust is sufficient to evaporate the cloud in its wake. |
12. Mintra, Drytra and Maxtra Levels
Mintra (Minimum Trail) Level (ML): Below this level, no condensation trails form. The flight level at which temperature is about –45°C gives a good estimate of ML at 100% RH for jet aircraft.
Drytra Level: When temperatures are very low, contrails form even when RH is 0%. It is usually about 2 km above the Mintra level. This is because moisture from the exhaust is sufficient to produce saturation.
Maxtra Level: This level lies in the stratosphere, above which no contrails form.
Contrail Layer Summary (bottom to top):
No contrails → Contrails Possible → Contrails Certain (Mintra Level → Drytra Level) → Contrails Possible → No contrails (Maxtra/Sea Level equivalent in stratosphere)
13. Flying in Clouds — Operational Significance
Stratiform Clouds (ST, AS)
Flying is generally smooth. In NS clouds during monsoon with thick AS and NS layers, visibility is reduced due to continuous precipitation. ST clouds reduce visibility and cause difficulty identifying the runway during landings. Ice accretion also occurs in AS and NS clouds above freezing levels.
Cumuliform Clouds (CU, CB)
CC and AC may cause bumpiness. Well developed CU, TCU and CB can cause severe turbulence, downdrafts, gusts, ice accretion, lightning, hail and strong up/down draughts. Flying through CB should be avoided during TS. Hail may be experienced in clear air below the anvil of a CB.
CB Avoidance Rules:
• Avoid flying through active CB
• Avoid flying under CB anvil — hail in clear air possible
• CB causes ALL: RA, SH, GR, SN, TS, severe turbulence, severe icing, lightning
• Operations should be avoided during TS
14. Practice Q&A
Q1. Drizzle occurs from (a) CS (b) ST (c) NS (d) CU
✅ Answer: (b) ST
Explanation: Stratus (ST) gives drizzle, ice prisms or snow grains. It does not give rain.
Distractors: CS (high cloud, no precip); NS (continuous rain, not drizzle specifically); CU (showers, not drizzle).
🎯 Instructor's Note: Drizzle = ST. Continuous rain = NS. Showers = CB/TCU.
Q2. Altostratus (AS) is (a) Low cloud of sheet type (b) A medium cloud of sheet type (c) A high cloud of large vertical growth
✅ Answer: (b) A medium cloud of sheet type
AS is a medium-level stratiform cloud. It is a uniformly grey/whitish sheet. In tropics: 2–8 km.
Low cloud = ST/SC/NS. High cloud with vertical growth = CB.
🎯 Alto = medium level prefix. Stratus = sheet. Therefore AS = medium sheet cloud.
Q3. Showers occurs from (a) CU (b) CB (c) AS (d) AC
✅ Answer: (b) CB
Showers (SH) are produced by Cumulonimbus (CB). CB produces RA, SH, GR, SN.
CU: Fair weather, no precip; AS: continuous rain; AC: no precip (or light precip).
🎯 SHowers from SHockers = CB.
Q4. Heavy icing is possible in (a) CI (b) CS (c) ST (d) CB
✅ Answer: (d) CB
CB contains supercooled water droplets, causing heavy icing especially in middle layers. Also rime and clear ice possible.
CI, CS: mainly ice crystals, negligible icing. ST: possible icing at/below freezing.
🎯 CB = ALL hazards including heavy icing.
Q5. To avoid icing in cloudy conditions, a pilot is advised to fly through a cloud which shows optical phenomena (a) Halo (b) Corona (c) With multi-coloured clouds
✅ Answer: (a) Halo
Halo is produced by CS (ice crystals). Ice crystal clouds cause negligible icing. Corona (in AS/AC) indicates supercooled water droplets = moderate icing risk.
Corona = water droplets = icing risk. Multi-coloured = irisations = water droplets = icing risk.
🎯 Halo = ice crystals = safe. Corona = water drops = ICING RISK.
Q6. Dark grey cloud causing continuous rain (a) AS (b) NS (c) SC (d) CB
✅ Answer: (b) NS
Nimbostratus is a dark, grey, thick cloud layer causing continuous rain or snow. Thick enough to blot out the sun.
AS: uniformly grey but lighter, may cause rain; SC: low puffs, no serious precip; CB: showers not continuous.
🎯 NS = Nimbus (rain) + Stratus (layer) = continuous rain from grey blanket.
Q7. A uniform layer of cloud resembling fog but not on the ground (a) AS (b) NS (c) ST
✅ Answer: (c) ST
Stratus is a grey cloud layer with uniform base, resembles fog. When ST touches the ground, it IS fog.
AS: medium level; NS: causes heavy rain; ST: low, fog-like.
🎯 ST touching ground = Fog. ST above ground = Stratus.
Q8. The clouds composed of ice crystals having feathery appearance (a) CI (b) CS (c) AS
✅ Answer: (a) CI
Cirrus clouds are white and fibrous — delicate filaments = feathery appearance. Composed entirely of ice crystals.
CS: thin whitish veil; AS: medium level grey sheet.
🎯 CI = Cirrus = fibrous/feathery = ice crystals. No precip, no icing.
Q9. NS clouds occur (a) At cold front (b) At warm front
✅ Answer: (b) At warm front
At warm fronts, gradual ascent produces AS and NS, giving widespread continuous rain ahead of the surface front.
Cold fronts produce CU and CB (showers and thunderstorms), not NS.
🎯 Warm Front = NS + continuous rain. Cold Front = CB + showers/TS.
Q10. Lenticular clouds indicate presence of (a) Warm Front (b) Cold Front (c) Mountain waves
✅ Answer: (c) Mountain waves
Altocumulus Lenticularis form at crests of mountain waves on the leeward side of high mountains. They are stationary despite strong winds.
Fronts produce layered/cumuliform clouds, not lens-shaped stationary clouds.
🎯 Lens-shaped stationary cloud over/downwind of mountain = MOUNTAIN WAVE = severe turbulence possible.
Q11. The lowest level from which condensation trails will not form is (a) Mintra Level (b) Drytra Level (c) Maxtra Level
✅ Answer: (a) Mintra Level
Mintra (Minimum Trail) Level = lowest level at which contrails can form. Below this = no contrails.
🎯 MINtra = MINimum level for contrails. Drytra = no need for humidity. MAXtra = maximum level, in stratosphere.
Q12. Cloud ceiling is the height of the cloud covering... (a) 3–4 oktas (b) 5/8 or more (c) 8/8
✅ Answer: (b) 5/8 or more
Cloud ceiling = height of lowest cloud layer below 6000 m covering 5/8 or more of sky (BKN or OVC).
3–4 = SCT (not ceiling); 8/8 = OVC (that IS a ceiling layer but so is BKN).
🎯 Ceiling = BKN (5–7/8) or OVC (8/8) below 20,000 ft.
Q13. AC cloud with cumuliform protuberances indicates (a) Stability (b) Instability (c) Neutrality
✅ Answer: (b) Instability
Castellaneous AC (ACCas) with tower-like cumuliform protuberances indicates atmospheric instability at medium levels — a precursor to afternoon thunderstorm development.
🎯 ACCas = morning sign of afternoon TS. Instability indicator at medium level.
Q14. Hail may be experienced under the anvil of a CB (a) True (b) False
✅ Answer: (a) True
Hail (GR) can fall in clear air below the anvil of a CB. The anvil spreads out horizontally and can carry hail considerable distances from the storm.
🎯 Never fly under a CB anvil — clear air hail is a serious hazard.
15. Master Reference Tables
All Numerical Values
| Parameter | Value |
|---|
| High clouds — tropics height range | 20,000–60,000 ft (6–18 km) |
| Medium clouds — tropics | 2–8 km (6,500–25,000 ft) |
| Low clouds — all regions | below 2 km (6,500 ft) |
| Cloud ceiling threshold | 6000 m / 20,000 ft |
| Cloud ceiling coverage threshold | 5/8 or more |
| Exhaust contrail level | 9 km and above |
| Mintra — ML temperature estimate | –45°C @ 100% RH |
| Drytra — above Mintra by | ~2 km |
| Ice pallets dia | <5 mm |
| Operationally significant cloud base | below 1500 m (5000 ft) |
| Noctilucent cloud altitude | 80–85 km |
| Noctilucent cloud latitude | 72°N–45°N, mostly 55°N |
Cloud Type Quick Reference
| Cloud | Level | Composition | Precipitation | Icing | Aviation Hazard |
|---|
| CI | High | Ice crystals | None | Negligible | Low |
| CS | High | Ice crystals | None | Negligible | Low (Halo visible) |
| CC | High | Ice crystals | None | Negligible | Low |
| AC | Medium | Water/ice | None (AC Len = none) | Possible | Low–Moderate |
| AS | Medium | Water/ice | Continuous rain/snow (thick) | Yes below 0°C | Moderate |
| ST | Low | Water drops | Drizzle | Possible | Moderate (vis) |
| SC | Low | Water drops | None serious | Possible | Low |
| NS | Low–Medium | Water/ice | Continuous rain/snow | Yes below 0°C | High |
| CU | Vertical | Water drops | None (fair wx) | Possible | Low (bumpiness) |
| TCU | Vertical | Water/ice | Rain, showers | Yes | High |
| CB | Vertical | Water/ice/hail | RA, SH, GR, SN | Severe | EXTREME — AVOID |
Okta/Cloud Amount Table
| Oktas | Term (METAR) | Sky Condition |
|---|
| 0 | SKC/NSC | Fine |
| 1–2 | FEW | Fine |
| 3–4 | SCT | Fair |
| 5–7 | BKN | Partly cloudy |
| 8 | OVC | Cloudy/Overcast |
| /// | Sky Obscured (VV///) | Sky Obscured |
Answer Key — Q&A Section
| Q | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 | 13 | 14 | 15 | 16 | 17 | 18 | 19 | 20 |
|---|
| A | b | b | b | d | a | b | c | a | b | c | a | b | b | a | b | c | c | b | a | a |
(Answers from textbook Q1–20: b b b d a b c a b c a b b a b c c b a a)
Quick Revision Summary — Chapter 8:
• 5 causes of vertical motion: Terrain, Convection, Pressure, Fronts, Wind Shear
• Convergence = ascent = bad wx; Divergence = subsidence = fine wx
• 10 cloud genera; 3 levels; classified by form and height
• High clouds (3 Ci-): ice crystals, no precip, no icing, CS produces HALO
• Medium (Alto-): AS = continuous rain if thick; AC = no precip; Corona in AS
• Low: ST = drizzle; NS = continuous rain; SC = no serious precip
• CB = ALL hazards — AVOID. Hail under anvil in clear air.
• Cloud base: AGL in METAR/TAF; AMSL in area charts
• Ceiling = BKN/OVC below 20,000 ft; Cloud amount in Oktas (0–8)
• Contrails: Wing tip (short), Exhaust (long, persistent ≥9 km), Distrails (clear lanes)
• Mintra (lowest level for contrails) → Drytra (2 km above) → Maxtra (stratosphere)
Capt. Pankaj Pahil