Presentation is loading. Please wait.

Presentation is loading. Please wait.

The Effect of the Terrain on Monsoon Convection in the Himalayan Region Socorro Medina 1, Robert Houze 1, Anil Kumar 2,3 and Dev Niyogi 3 Cloud and Precipitation.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "The Effect of the Terrain on Monsoon Convection in the Himalayan Region Socorro Medina 1, Robert Houze 1, Anil Kumar 2,3 and Dev Niyogi 3 Cloud and Precipitation."— Presentation transcript:

1 The Effect of the Terrain on Monsoon Convection in the Himalayan Region Socorro Medina 1, Robert Houze 1, Anil Kumar 2,3 and Dev Niyogi 3 Cloud and Precipitation Seminar, University of Washington, Seattle, 25 October 2007 1 University of Washington; 2 RAL, NCAR; 3 Purdue University

2 Precipitation distribution in relation to terrain Xie et al. (2006) Jun-Aug precipitation (mm/month) (Climatology from TRMM-PR data from 1997-2004) Orography (km) Bay of Bengal Arabian Sea Pakistan Afghanistan

3 MOTIVATION – MONSOON 2007 (Jun-Aug) Anomaly (%) Precipitation (mm)

4 MONSOON CONVECTION IN THE HIMALAYAN REGION – Three part study 1Houze, Wilton, and Smull (2007) – 3D structure of intense storms and their distribution in relation to topography and surrounding oceans 2Ulrike Romatschke (Ulli) – Is extending Houze et al. (2007) study  Cloud and Precipitation Seminar Nov 15 th 3Analyze numerical simulations to investigate the detailed role of the terrain – preliminary results

5 MONSOON CONVECTION IN THE HIMALAYAN REGION – Three part study 1Houze, Wilton, and Smull (2007) – 3D structure of intense storms and their distribution in relation to topography and surrounding oceans 2Ulrike Romatschke (Ulli) – Is extending Houze et al. (2007) study  Cloud and Precipitation Seminar Nov 15 th 3Analyze numerical simulations to investigate the detailed role of the terrain – preliminary results

6 Houze, Wilton, and Smull (2007) study Data from Precipitation Radar (PR) on the Tropical Rainfall Measuring Mission (TRMM) satellite (June-September 2002/2003) Found contiguous radar echoes that exceeded some size threshold Analyzed separately convective and stratiform radar echoes

7 Convective and stratiform radar reflectivity echoes Horizontal cross-section Vertical cross-section convective echo Vertical cross-section stratiform echo Houze (1997)

8 WesternCentral Eastern Deep Intense Convective Cores 40 dBZ echo 40 dBZ echo > 10 km in height > 10 km in height Wide Intense Convective Cores 40 dBZ echo 40 dBZ echo > 1000 km 2 area > 1000 km 2 area Broad Stratiform Echo > 50,000 km 2 > 50,000 km 2 Results of Houze et al. (2007):

9 Example of Deep Intense Convective Core (40 dbz echo >10 km in height) Example: Reflectivity at 0900 UTC 14 Jun 2002 10 m winds reanalysis at 1200 UTC 14 Jun 2002 Delhi sounding 00 UTC 14 Jun 2002 Houze et al. (2007) Orography

10 moist dry,hot Carlson et al. 1983

11 Western Central Eastern Deep Intense Convective Cores 40 dBZ echo 40 dBZ echo > 10 km in height > 10 km in height Wide Intense Convective Cores 40 dBZ echo 40 dBZ echo > 1000 km 2 area > 1000 km 2 area Broad Stratiform Echo stratiform echo stratiform echo > 50,000 km 2 > 50,000 km 2 Results of Houze et al. (2007):

12 Example of Wide Intense Convective Core (40 dbz echo >1000 km 2 in area) Example: Reflectivity at 2208 UTC 3 Sep 2003 Houze et al. (2007)

13 Western Central Eastern Deep Intense Convective Cores 40 dBZ echo 40 dBZ echo > 10 km in height > 10 km in height Wide Intense Convective Cores 40 dBZ echo 40 dBZ echo > 1000 km 2 area > 1000 km 2 area Broad Stratiform Echo stratiform echo stratiform echo > 50,000 km 2 > 50,000 km 2 Results of Houze et al. (2007):

14 Example of Broad Stratiform Echo (>50,000 km 2 in area) Example: Infrared satellite temperature and reflectivity at ~03 UTC 11 Aug 2002 Houze et al. (2007) 10 m winds reanalysis at 00 UTC 11 Aug 2002 Tengchong sounding

15 MONSOON CONVECTION IN THE HIMALAYAN REGION – Three part study 1Houze, Wilton, and Smull (2007) – 3D structure of intense storms and their distribution in relation to topography and surrounding oceans 2Ulrike Romatschke (Ulli) – Is extending Houze et al. (2007) study  Cloud and Precipitation Seminar Nov 15 th 3Analyze numerical simulations to investigate the detailed role of the terrain – preliminary results

16 MONSOON CONVECTION IN THE HIMALAYAN REGION – Three part study 1Houze, Wilton, and Smull (2007) – 3D structure of intense storms and their distribution in relation to topography and surrounding oceans 2Ulrike Romatschke (Ulli) – Is extending Houze et al. (2007) study  Cloud and Precipitation Seminar Nov 15 th 3Analyze numerical simulations to investigate the detailed role of the terrain – preliminary results

17 OBJECTIVES Evaluate if high-resolution models can predict the structures observed by Houze et al. (2007) Test the ideas put forward in that study: –Investigate why the intense convection is often observed over the foothills –Analyze the relative roles of orography and synoptics in systems observed in association with Bay of Bengal depressions

18 NUMERICAL SIMULATIONS Weather Research and Forecasting (WRF v2.1.1) model (runs conducted by Anil Kumar, NCAR/Purdue University) –NCEP Reanalysis used as initial and boundary conditions (6 hourly) –Bulk microphysical parameterization: WRF Single-Moment with 6 water substances Isolated deep convective system: dx 1 =9 km; dx 2 = 3 km (14 Jun 2002)  Simulation couldn’t capture system Wide intense convective system (3 Sep 2003) Broad stratiform system (11 Aug 2002) HYSPLIT model trajectories using NCEP reanalysis (http://www.arl.noaa.gov/ready/hysplit4.html)

19 Wide convective system simulation Time: 18-23 UTC 3 Sep 2003 (0030-0530 LST) Terrain and accumulated precipitation (mm) Domain 1: dx = 9 kmDomain 2: dx = 3 km Pakistan India

20 Wide convective system Evaluation at 2130 UTC 03 Sep 2003 (0400 LST, t=3.5 h) Observations Infrared satellite temperature (shaded, K) and low-resolution terrain (black contours, km) WRF-simulation Cloud top temperature (shaded, K) and terrain (black contours, m) PakistanIndiaPakistanIndia

21 Wide convective system Evaluation at 2130 UTC 03 Sep 2003 (0400 LST, t=3.5 h) Observations Infrared satellite temperature (shaded, K) and low-resolution terrain (black contours, km) WRF-simulation Cloud top temperature (shaded, K) and terrain (black contours, m) PakistanIndiaPakistanIndia

22 Wide convective system Evaluation at 2230 UTC 03 Sep 2003 (0500 LST, t=4.5 h) Observations Infrared satellite temperature (shaded, K) and low-resolution terrain (black contours, km) WRF-simulation Cloud top temperature (shaded, K) and terrain (black contours, m) PakistanIndiaPakistanIndia

23 Wide convective system Evaluation at 2300 UTC 03 Sep 2003 (0530 LST, t=5.0 h) Observations Infrared satellite temperature (shaded, K) and low-resolution terrain (black contours, km) WRF-simulation Cloud top temperature (shaded, K) and terrain (black contours, m) PakistanIndiaPakistanIndia

24 Wide convective system – Evaluation of reflectivity (22 UTC 3 Sep) Observations WRF-simulation

25 Wide convective system – Hypotheses testing HYPOTHESIS - Low-level moist southwesterly flow was capped by dry air flowing off the high Tibetan Plateau or the Afghan mountains Surface water vapor mixing ratio (g/kg) and windsBackward trajectories (HYSPLIT/NCEP) http://www.arl.noaa.gov/ready/hysplit4.html 0.5 km 2.5 km

26 Wide convective system – Hypotheses testing HYPOTHESIS - Low-level moist southwesterly flow was capped by dry air flowing off the Afghan mountains Surface dew point depression (°C)

27 Wide convective system – Hypotheses testing HYPOTHESIS - Low-level moist southwesterly flow was capped by dry air flowing off the Afghan mountains Soundings at 1800 UTC Dry side Moist side

28 Wide convective system – Hypotheses testing HYPOTHESIS - Convection started where the potentially unstable column was subjected to orographic lifting CAPE (J/kg) 1000 2000 3000

29 Wide convective system – Hypotheses testing HYPOTHESIS - Convection started where the potentially unstable column was subjected to orographic lifting Surface dew point depression (°C) and vertically integrated mixing ratio of precipitating hydrometeors (mm) at 1925 UTC (t=1.25 h)

30 Wide convective system – Hypotheses testing HYPOTHESIS - Convection started where the potentially unstable column was subjected to orographic lifting Mixing ratio (g/kg) of water vapor (shaded), cloud hydrometeors (dark red) and precipitating hydrometeors (dark blue) at 1815 UTC 4 8 12 16 18 20

31 Wide convective system – Hypotheses testing HYPOTHESIS - Convection started where the potentially unstable column was subjected to orographic lifting Mixing ratio (g/kg) of water vapor (shaded), cloud hydrometeors (dark red) and precipitating hydrometeors (dark blue) at 1830 UTC 4 8 12 16 18 20

32 Wide convective system – Hypotheses testing HYPOTHESIS - Convection started where the potentially unstable column was subjected to orographic lifting Mixing ratio (g/kg) of water vapor (shaded), cloud hydrometeors (dark red) and precipitating hydrometeors (dark blue) at 1845 UTC 4 8 12 16 18 20

33 Wide convective system – Hypotheses testing HYPOTHESIS - Convection started where the potentially unstable column was subjected to orographic lifting Mixing ratio (g/kg) of water vapor (shaded), cloud hydrometeors (dark red) and precipitating hydrometeors (dark blue) at 1900 UTC 4 8 12 16 18 20

34 Wide convective system – Role of the NW concave indentation of the terrain Dew point depression > 10°C CIN > 150 J/kg Temperature > 31°C ‘Idealized’ (highly smoothed) low-level variables CAPE > 1800 J/kgMixing ratio > 20 g/kg Relative Humidity (% ) - Shaded

35 CONCLUSIONS Convective systems High-resolution model was able to predict the observed structures (if the system is wide enough AND the model has enough resolution) In Wide Intense Convective storm, the terrain appears to play three main roles: –The NW concave indentation of the terrain increases the existing humidity gradients –Elevated layer of dry, warm air originates over the Afghan mountains and caps the moist low-level flow  allows buoyancy to build up –The convection is triggered at the small features of terrain (h<0.5 km): orographic lifting, convergence or both

36 Broad stratiform system simulation Time: 12 UTC 10 Aug – 03 UTC 11 Aug 2003 (1830-0930 LST) Terrain and accumulated precipitation (mm) Domain 1: dx = 27 kmDomain 2: dx = 9 km

37 Broad stratiform system – Evaluation of low-levels winds at 00 UTC 11 Aug 2002 Observations 10 m winds and wind speed (m/s) WRF-simulation Surface winds and wind speed (m/s) and terrain (red contours)

38 Broad stratiform system – Evaluation of IR temperature and reflectivity Observations WRF-simulation

39 Broad stratiform system – Sounding at Tengchong at 00 UTC 11 Aug 2002 ObservationsWRF-simulation

40 Broad stratiform system – Role of the Bay of Bengal Depression ‘Idealized’ (highly smoothed) low-level variables Rainrate > 5 mm/hrWind speed > 5m/s Mixing ratio > 21 g/kg LOW SLP

41 PRELIMINARY CONCLUSIONS – Broad stratiform system The high-resolution model was able to predict the observed structures The Bay of Bengal depression provides low- level moisture and cross-barrier flow Low-level flow channeled between individual ranges and impinges into the NE indentation of the Himalayas

42

43 Concluding remark…. Schultz et al. 2000 “In diagnosing precipitation processes, assessing the mechanism for forcing ascent should be the primary concern. The degree of instability… merely modulates the response to the forcing”

44 Wide convective system – Role of the NW concave indentation of the terrain Dew point depression > 10°C CIN > 150 J/kg Temperature > 31°C ‘Idealized’ (highly smoothed) low-level variables CAPE > 1800 J/kgMixing ratio > 20 g/kgEquivalent potential temperature > 364 K

45

46

47

48

49

50 Wide convective system – Hypotheses testing HYPOTHESIS - Convection started where the potentially unstable column was subjected to orographic lifting CAPE (for parcel with max theta_e, J/kg)CIN (for parcel with max theta_e, J/kg)

51 Wide convective system Evaluation at 1830 UTC 03 Sep 2003 Observations Infrared satellite temperature (shaded, K) and low-resolution terrain (black contours, km) WRF-simulation Cloud top temperature (shaded, K) and terrain (black contours, m) PakistanIndiaPakistanIndia

52 Wide convective system Evaluation at 1900 UTC 03 Sep 2003 Observations Infrared satellite temperature (shaded, K) and low-resolution terrain (black contours, km) WRF-simulation Cloud top temperature (shaded, K) and terrain (black contours, m) PakistanIndiaPakistanIndia

53 Wide convective system Evaluation at 2100 UTC 03 Sep 2003 (XXX LST, t=X h) Observations Infrared satellite temperature (shaded, K) and low-resolution terrain (black contours, km) WRF-simulation Cloud top temperature (shaded, K) and terrain (black contours, m) PakistanIndiaPakistanIndia

54 Broad stratiform system simulation Terrain and accumulated precipitation (mm)

55 Broad stratiform system – Hypotheses testing HYPOTHESIS – The flow over the terrain enhances the mesoscale precipitation areas Vertically integrated precipitating mixing ratio over 15 h (mm)

56 Broad stratiform system – Hypotheses testing HYPOTHESIS – The flow over the terrain enhances the mesoscale precipitation areas Cloud water mixing ratio and vertical velocity

57 Stratiform case

58 Broad stratiform system – Evaluation of 200 mb winds at 00 UTC 11 Aug 2002 Observations wind speed (m/s) WRF-simulation wind speed (m/s) and terrain (red contours)

59 Wide convective system – Hypotheses testing HYPOTHESIS - Convection started where the potentially unstable column was subjected to orographic lifting Mixing ratio (g/kg) of water vapor (shaded), cloud hydrometeors (dark red) and precipitating hydrometeors (dark blue) at 1800 UTC 4 8 12 16 18 20

Download ppt "The Effect of the Terrain on Monsoon Convection in the Himalayan Region Socorro Medina 1, Robert Houze 1, Anil Kumar 2,3 and Dev Niyogi 3 Cloud and Precipitation."

Similar presentations

Robert Houze University of Washington (with contributions from B. Smull) Winter MONEX Summer MONEX Presented at: International Conference on MONEX and.

Robert Houze University of Washington (with contributions from B. Smull) Winter MONEX Summer MONEX Presented at: International Conference on MONEX and.
Generation mechanism of strong winds in the left-rear quadrant of Typhoon MA-ON (2004) during its passage over the southern Kanto district, eastern Japan.

Generation mechanism of strong winds in the left-rear quadrant of Typhoon MA-ON (2004) during its passage over the southern Kanto district, eastern Japan.
Blocking in areas of complex topography Mimi Hughes Alex Hall Rob Fovell UCLA and its influence on rainfall distribution.

Blocking in areas of complex topography Mimi Hughes Alex Hall Rob Fovell UCLA and its influence on rainfall distribution.
R. A. Houze, Jr., U. Romatschke K. L. Rasmussen AGU Fall Meeting, Remote Sensing of Natural Hazards, San Francisco, 9 Dec 2011 Mesoscale Aspects of Storms.

R. A. Houze, Jr., U. Romatschke K. L. Rasmussen AGU Fall Meeting, Remote Sensing of Natural Hazards, San Francisco, 9 Dec 2011 Mesoscale Aspects of Storms.
Precipitation Over Continental Africa and the East Atlantic: Connections with Synoptic Disturbances Matthew A. Janiga November 8, 2011.

Precipitation Over Continental Africa and the East Atlantic: Connections with Synoptic Disturbances Matthew A. Janiga November 8, 2011.
Precipitation in the Olympic Peninsula of Washington State Robert Houze and Socorro Medina Department of Atmospheric Sciences University of Washington.

Precipitation in the Olympic Peninsula of Washington State Robert Houze and Socorro Medina Department of Atmospheric Sciences University of Washington.
Structure of mid-latitude cyclones crossing the California Sierra Nevada as seen by vertically pointing radar Socorro Medina, Robert Houze, Christopher.

Structure of mid-latitude cyclones crossing the California Sierra Nevada as seen by vertically pointing radar Socorro Medina, Robert Houze, Christopher.
A brief synopsis of Johnson and Mapes: Mesoscale Processes and Severe Convective Weather From Severe Convective Storms sections 3.3b, 3.3c.1, 3.4 By Matt.

A brief synopsis of Johnson and Mapes: Mesoscale Processes and Severe Convective Weather From Severe Convective Storms sections 3.3b, 3.3c.1, 3.4 By Matt.
Radar signatures in complex terrain during the passage of mid-latitude cyclones Socorro Medina Department of Atmospheric Sciences University of Washington.

Radar signatures in complex terrain during the passage of mid-latitude cyclones Socorro Medina Department of Atmospheric Sciences University of Washington.
A WRF Simulation of the Genesis of Tropical Storm Eugene (2005) Associated With the ITCZ Breakdowns The UMD/NASA-GSFC Users' and Developers' Workshop,

A WRF Simulation of the Genesis of Tropical Storm Eugene (2005) Associated With the ITCZ Breakdowns The UMD/NASA-GSFC Users' and Developers' Workshop,
Synoptic, Topographic, and Diurnal Effects on Summer Convection in South America Ulrike Romatschke University of Washington, University of Vienna Robert.

Synoptic, Topographic, and Diurnal Effects on Summer Convection in South America Ulrike Romatschke University of Washington, University of Vienna Robert.
Scientific Objectives and Required Facilities Socorro Medina, Robert Houze, and Stacy Brodzik TIMREX Planning Meeting, Tainan, Taiwan, 9 November 2007.

Scientific Objectives and Required Facilities Socorro Medina, Robert Houze, and Stacy Brodzik TIMREX Planning Meeting, Tainan, Taiwan, 9 November 2007.
Robert A. Houze, Jr., Darren C. Wilton, and Bradley F. Smull University of Washington Robert A. Houze, Jr., Darren C. Wilton, and Bradley F. Smull University.

Robert A. Houze, Jr., Darren C. Wilton, and Bradley F. Smull University of Washington Robert A. Houze, Jr., Darren C. Wilton, and Bradley F. Smull University.
Pakistan Flood 2010: P. J. Webster R. A. Houze, Jr. P. J. Webster R. A. Houze, Jr. International Weather & Climate Events of 2010, AMS Annual Meeting,

Pakistan Flood 2010: P. J. Webster R. A. Houze, Jr. P. J. Webster R. A. Houze, Jr. International Weather & Climate Events of 2010, AMS Annual Meeting,
What we have learned about Orographic Precipitation Mechanisms from MAP and IMPROVE-2: MODELING Socorro Medina, Robert Houze, Brad Smull University of.

What we have learned about Orographic Precipitation Mechanisms from MAP and IMPROVE-2: MODELING Socorro Medina, Robert Houze, Brad Smull University of.
MAP and IMPROVE II Experimental Areas SHARE Workshop, Boulder, 5 May 2005.

MAP and IMPROVE II Experimental Areas SHARE Workshop, Boulder, 5 May 2005.
The Effect of the Terrain on Monsoon Convection in the Himalayan Region Socorro Medina 1, Robert Houze 1, Anil Kumar 2,3 and Dev Niyogi 3 Conference on.

The Effect of the Terrain on Monsoon Convection in the Himalayan Region Socorro Medina 1, Robert Houze 1, Anil Kumar 2,3 and Dev Niyogi 3 Conference on.
Rapid Update Cycle Model William Sachman and Steven Earle ESC452 - Spring 2006.

Rapid Update Cycle Model William Sachman and Steven Earle ESC452 - Spring 2006.
U.S.-Taiwan Meeting, Boulder, 30 October 2006 Study of Intense Convection over Taiwan: Some Food for Thought R. Houze Study of Intense Convection over.

U.S.-Taiwan Meeting, Boulder, 30 October 2006 Study of Intense Convection over Taiwan: Some Food for Thought R. Houze Study of Intense Convection over.
Extreme Convection Near the Himalayas and Andes Gerald R. North Symposium, Texas A&M University, College Station, June 8, 2009 Robert A. Houze, Jr. Ulrike.

Extreme Convection Near the Himalayas and Andes Gerald R. North Symposium, Texas A&M University, College Station, June 8, 2009 Robert A. Houze, Jr. Ulrike.

Similar presentations

Ads by Google