Darío Cano & Enric Terradellas

Behavior of the humidity and the convergence of mass in the surroundings of the Madrid Barajas airport in days with mountain breezes.

Behavior of the humidity and the horizontal mass convergence in the surroundings of the Madrid Barajas

airport in days with mountain breezes.

Darío Cano & Enric Terradellas


The experience in the simulations of fog events at Madrid airporthas been evidencied that the vertical moutions and the humidity advection near of the soil are very importantparameters not well simulated by the LAM.

In order to solve this problem it is necesary to obtain climatological values in each specific place.


The aerea of study

Madrid

Precipitable Water

SEVIRI (LPW data)

Divergence of mass6 anemocinemographes located in the airport.

AVAILABLE DATA


Coordinates (in km) of the anemocinemographs.

F = div V horiz

C A B E C E R A 1 8 R( 0 .0 , 6 .9 )

C A B E C E R A 3 6 L ( 0 .0 , 3 .7 )

C A B E C E R A 1 8 L ( 1 .1 , 2 .7 )C A B E C E R A 1 5

( 0 .5 , 2 ..3 )

C A B E C E R A 3 6 R ( 1 .0 , 0 .0 )

C A B E C E R A 3 3 ( 1 .6 , 0 .5 )

E J E X

E J E Y

P O LIG O N O C O N V É R TIC E SE N C A D A C A B E C E R A

NCABECERA 18R

(0.0, 6.9)

CABECERA 36L (0.0, 3.7)

CABECERA 18L (1.1, 2.7)CABECERA 15

(0.5, 2..3)

CABECERA 36R (1.0, 0.0)

CABECERA 33 (1.6, 0.5)

EJE X

EJE Y

POLIGONO CON VÉRTICESEN CADA CABECERA

N

The divergence is obtained from data recorded by 6 wind sensors every 10 ‘.

If ρ =ct then the horizontal divergence is the flow across the area that contains the polygon that the sensors delimit.

Airport map and polygon used in the calculation of the flow.


Convergence of mass in Madrid

AVAILABLE DATA

Uso de herramientas de seguimiento, desarrolladas en SAF para el diagnóstico de nieblas en la Meseta Sur de la Península Ibérica:Behavior of the humidity and the convergence of mass in the surroundings of the Madrid Barajas airport in days with mountain breezes.

LPW “ precipitable water by layers”

The LPW provide information on the water vapor contained in a vertical column of unit cross-section area in three layers in the troposphere:

•Boundary Layer (BL): 1013hPa-840 hPa •Middle Layer (ML): 840hPa-437hPa •High Layer (HL): <437hPa



The mountains breeze is the main mesoβ signal not well represented in LAM. The katabatic flows are a very important mechanisme in the formation of fog.In this work we select mountain breeze days followingtwo criteria:

1./ The wind is from the North during the nigth (less than 5 Kts) and from the South during the day.

2./ Clear days.

Madrid

AlmagroAlbacete

In clear days, a moderate flow ( ~10 Kts) from the South- West invades the valleys, go up to the mountains. At the botton of the valley there is a horizontal mass divergence that originates a downard motion. In the top of the mountains there is a convergence.


Mountain Breezes in Madrid

Uso de herramientas de seguimiento, desarrolladas en SAF para el diagnóstico de nieblas en la Meseta Sur de la Península Ibérica:Use of Nowcasting tools , developed in SAF for the diagnosis of fogs in the South Plateau of the Iberian Peninsula.

Breezes of mountains: Katabatic flow

Madrid

AlmagroAlbacete

In clear nights, a weak flow (< 5 Kts) from the East invades the valleys, comming from the mountains. At the botton of the valley there is a mass convergence that originates ascent motion. At the top of the mountains there is a returned descendent warm flow.

150 Km

1,5 KmWarm slope zone



Average divergence in breezes days over Barajas airport

-0,01

-0,005

0

0,005

0,01

00:0

0:00

01:0

0:00

02:0

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03:0

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HOUR

DIV

ER

GE

NC

E (

S-1

) DICIEMBREENERO

FEBREO

MARZO

ABRIL

MAYO

NOVIEMBREOCTUBRE

There is a very evident diurnal cycle in the evolution of thehorizontal divergence in surface:

Nocturnal convergence and diurnal divergence



The nocturnal convergence has the same value during all year.

The diurnal divergence increases in summer days.

Average Divergence in days with mountain breezes over Barajas airport

-0,01

-0,005

0

0,005

0,01

00:0

0:00

01:0

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02:0

0:00

03:0

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HOUR

DIV

ER

GE

NC

E (

S-1

)

winter(nov;dic;ene) spring (feb;mar;abr;may) outon (sept;oct)


Specific Humidity in surface

Average specific humidity in days with breezes over Madrid -Barajas

0,0020,0030,0040,0050,0060,0070,008

00:0

0:00

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HORA

HU

M E

SP

CF

g/K

g DICIEMBRE

ENERO

FEBREO

MARZO

ABRIL

MAYO

OCTUBRE

AGOSTO

SEPTIEMBRE

JUNIO

A diurnal oscillation is detected in the evolution of the specific humidity.

There are two different evolutions:one in winter (nov, dec, jan, feb) and another one the rest of the year.


Specific Humidity in surface

AVERAGE SPECIFIC HUMIDITY IN DAYS WITH BREEZE

0,002

0,003

0,004

0,005

0,006

0,007

00:0

0:00

01:0

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HOURS

HU

M E

SP

CF

g/K

g

WINTER(nov,dec,jan,feb) SPRING(mar,apr,may) OCTOBER

The behavior in winter is characterized by nocturnal decreasing of humidity and increase of humidity during daytime.

The behavior the rest of the year is characterized by a nocturnal decreasing and another arround noon. There are two periods where the humidity increases: one at dawn and another Starting at 18 UTC.



1.- The variation can be explained by the mountain-breeze cycle. At night, the upward motion transports humidity from low to medium levels. The air at the bottom of the valley becomes relatively dry. After stopping the upward motion, the humidity is advected back downwards.

2.- All the variation (about 1 mm) is due to the exchange between low and medium levels. The exchange air-surface (evaporation/condensation) is small (about 0.1 mm).

0

1

2

3

4

5

6

0 3 6 9 12 15 18 21 0hora

LP

W (

mm

)

0,003

0,004

0,005

0,006

SP

EC

F H

UM

(g

/Kg

)

AVERAGE BPW IN WINTER (nov,dic,ene,feb)

MPW WINTER

specific humidity in winter



2

3

4

5

6

7

8

0 3 6 9 12 15 18 21 0

hora

LP

W (

mm

)

0,004

0,005

0,006

SP

EC

F H

UM

(g

/Kg

)

AVERAGE BPW IN SPRINT (mar,abr,may)

MPW SPRING

specific hum spring

1.- During the night the low levels behave as katabatic in winter.

2.- At dawn, the humidity decreases in the low levels but increases near the surface probabily by mixture mechanisms.

2.- When the anabatic is established there is a decrease, the water is transported up through the mountain slopes and dry air moves down over the center of the Valley.

3.-In the Afternoon the increase of water in the low levels must be advected from the surroundings, not from the middle level.



BPW

Conceptual model of the anabatic cell

During the early morning there is a decrease of BPW, the water is transported up through the mountain slopes and dry air moves down over the center of the Valley. There is an increase or MPW.

From 9 to 12 UTC the BPW increases due to the South advection.

Conceptual model of the anabatic cell



BPW

When the anabatic flow stops, the ground inversion and the katabatic flow are established. A rapid decrease of humidity is observed in the low level. The katabatic advects dry air from the mountains.

Conceptual model of katabatic cell



BPW


conclusions

1.- A diurnal cycle is detected in the evolution of the horizontal mass divergence at surface.

2.- A diurnal cycle is detected in the humidity behavior.

3.- The main features of this behavoir can be explained by the mountain breeze model.

Documents

Darío Cano & Enric Terradellas