land surface memory & hydrological cycle over the u.s. west coast states & monsoon region...
DESCRIPTION
Motivation Improve soil moisture data for CPC’s drought & flood monitoring tools Improve weather & climate prediction with more accurate land initial conditions Improve land surface model via data validation& model intercomparisons Provide a long time series of realistic land surface data for land surface hydrological cycle, land memory & predictablity studies Coupled atmosphere-land-ocean modeling Develop new tools to use land surface data for climate monitoring & prediction …TRANSCRIPT
Land surface memory & hydrological cycle over the U.S. west coast states & monsoon region
Yun Fan and Huug van del DoolCPC/NCEP/NOAA
http://www.cpc.ncep.noaa.gov/soilmst/index.htm
Outline• Motivation • Noah Land Surface Model & Data• Results
– Land surface hydrological cycle– Land memory studies
• Summary
Motivation
•Improve soil moisture data for CPC’s drought & flood monitoring tools
•Improve weather & climate prediction with more accurate land initial conditions
•Improve land surface model via data validation& model intercomparisons
•Provide a long time series of realistic land surface data for land surface hydrological cycle, land memory & predictablity studies
•Coupled atmosphere-land-ocean modeling
•Develop new tools to use land surface data for climate monitoring & prediction
• …
Current CPC soil moisture monitor & climate prediction activities:– Drought & flood monitoring – Empirical forecast tools (Constructed Analog) – GFS forecast & climate prediction
Motivation & Background
)()()()()( tGtRtEtPdt
tdW
CPC Leaky Bucket Model (Huang et al 1996)
Where W(t) is soil water content, P(t) precipitation, E(t) evaportranspiration, R(t) net streamflow divergence, G(t) net groundwater loss. The ‘balance’ of the above equation is defined as the ‘budget’ (should equal dw/dt).
Forcing Data: -CPC daily temperature updates -CPC daily precipitation updates (Higgins & Shi) -Monthly precipitation and temperature from NCDC
Data Coverage: -73 years (1931-yesterday) on 344 US climate divisions
Motivation & Background (cont’)
Motivation & Background (cont’)
http://www.cpc.ncep.noaa.gov/soilmst/index.htm
•Flexible soil layers:
–user specified number and thickness (2-N). –Default is four soil layers (10, 30, 60, 100 cm thick)
•Soil hydraulics and parameters follow Cosby et al.•Canopy resistance follows Jarvis et al.•Satellite-based annual cycle of vegetation greenness globally:
–5-year monthly climatology (NESDIS AVHRR NDVI-based)
•Flexible vegetation and soil classes and their parameters
–easily modified via namelist I/O. Default: 12 SiB veg classes and 9 Zobler soil classes (i.e. ISLCP-I)
•Freeze/thaw soil physics follows Koren et al.•Snowpack density and water-equivalent content modeled
–Patchy/fractional snow cover treated as function of snowdepth & veg type
•Plug-compatible “drop-in” coding structure–link via one subroutine call and one argument list & no common blocks
Noah Land Surface Model Noah LSM
Characteristics
Retrospective LDAS (1948-1998) Input & OutputINPUT:
T2m, u10, v10, P*, q, S, IR, Precip
OUTPUT (orders 25 variables):Energy Mass
a S S IR IR GF SH LH Precip E (LH) R
Runoff, River flow, Tskin Snow10 cm T, W, Wliq
30 cm T, W, Wliq
Interface fluxes60 cm T, W, Wliq
1 m T, W, Wliq
bare soilopen watersnowcanopy
snowmeltcoverdepth surface
surface
surface
subsurface
Infiltration
17
Noah Land Surface Model SpinNoah Land Surface Model Spin--upup
Starting Retrospective LDAS RunStarting Retrospective LDAS Run(1948 (1948 -- 1998)1998)
Data Coverage (1948 – present)
Some Preliminary Results
19481998
1948 1949 3.5 years spin-up
Initialization of Retrospective US LDAS Run
???present
Data validation
Data validation
Land Surface Water Budget & Soil Moisture Evolution
P(t) - E(t) - R(t) – G(t)
Land Surface Water Budget Over Coterminous USA
P(t) - E(t) - R(t) – G(t)
Mon W P E R+G P-E-R-G 1 581.2 (294.2) 52.0 5.5 31.8 14.6 2 592.5 (304.0) 49.8 10.3 33.3 6.2 3 600.0 (308.8) 62.9 24.5 39.1 -0.7 4 595.6 (302.0) 59.4 42.8 30.2 -13.7 5 582.8 (289.8) 70.9 64.8 21.2 -15.1 6 564.6 (276.8) 66.2 75.7 14.2 -23.8 7 538.4 (260.1) 64.8 77.8 10.4 -23.5 8 520.1 (250.0) 62.2 67.6 9.0 -14.3 9 514.3 (248.3) 61.4 49.3 8.8 3.3 10 520.2 (253.3) 51.7 31.9 9.1 10.8 11 539.8 (266.8) 58.0 14.0 13.5 30.5 12 565.8 (282.6) 58.5 4.5 27.3 26.8
Year 559.0 (278.1) 59.8 39.1 20.7 0.0
averaged over 125W-75W, 30N-48N
Table.1 US monthly values of all components of land surface hydrology (mm/mon)
)()()()()( tGtRtEtPdt
tdW
Land Surface Water Budget Over western coast states
P(t) - E(t) - R(t) – G(t)
Mon W P E R+G P-E-R-G 1 595.1 (305.7) 99.0 -1.4 60.1 39.7 2 622.4 (324.4) 79.6 1.3 63.7 15.2 3 636.2 (330.5) 74.5 15.9 70.3 -10.4 4 624.9 (317.4) 47.1 33.3 44.7 -31.6 5 595.2 (293.5) 36.1 53.4 21.5 -39.6 6 554.7 (266.0) 26.3 63.1 8.5 -45.6 7 504.6 (233.1) 13.5 61.9 2.5 -51.0 8 463.4 (207.4) 18.6 43.8 1.3 -26.5 9 450.0 (201.4) 26.3 26.6 1.4 -1.5 10 460.2 (211.8) 44.7 14.6 3.9 25.7 11 507.0 (247.2) 93.3 3.7 19.4 72.3 12 563.8 (284.5) 97.2 -3.0 46.6 53.5
Year 548.1 (268.6) 54.7 26.1 28.7 -0.1
averaged over 125W-115W, 32N-49N
Table.2 US west coast states monthly values of all components of land surface hydrology (mm/mon)
)()()()()( tGtRtEtPdt
tdW
Land Surface Water Budget Over US Monsoon Region
P(t) - E(t) - R(t) – G(t)
Mon W P E R+G P-E-R-G 1 407.6 (206.5) 19.7 11.1 1.1 7.6 2 414.3 (212.0) 18.6 13.9 1.6 3.2 3 415.1 (211.1) 20.8 21.7 2.1 -3.0 4 404.7 (199.7) 12.2 25.7 1.2 -14.6 5 389.6 (185.3) 15.3 29.6 0.8 -15.2 6 375.9 (172.8) 17.8 28.7 0.7 -11.5 7 372.9 (171.0) 49.3 40.8 1.6 6.9 8 380.8 (179.5) 55.4 47.4 2.0 6.0 9 383.3 (182.0) 38.3 35.1 1.4 1.910 384.6 (183.0) 24.7 22.5 0.8 1.311 388.3 (186.5) 19.5 12.8 0.7 6.012 397.7 (195.6) 24.2 9.4 0.9 13.9
Year 392.9 (190.4) 26.3 24.9 1.2 0.2
averaged over 115W-103W, 31N-37N
Table.3 US monsoon region monthly values of all components of land surface hydrology (mm/mon)
)()()()()( tGtRtEtPdt
tdW
Standard Deviation of Land Surface Water Budget components & Soil Moisture from 1960-1998
Land Surface Memory for the Coterminous USA
Land Surface Memory for US
Land Surface Memory for West Coast States
Land Surface Memory for US Monsoon Region
Soil moisture correlation: the west coast states vs all US areas
Soil moisture correlation: the US monsoon region vs all US areas
Evaporation correlation: the US monsoon region vs all US areas
Soil moisture & lag precip & surface temperature correlation: the west coast states vs all US areas
Soil moisture & lag precip & surface temperature correlation: the US monsoon region vs all US areas
• In general, on a continental scale, the maximum of soil moisture (W) is in winter and the minimum is in summer, with some regional exceptions.
• For the precipitation (P), the west coast states have a strong seasonal cycle, with maximum in winter and minimum in summer. In US monsoon region P & Florida it peaks in summer, while in some area precipitation does not vary too much over the course of the annual cycle.
• Evaporation (E) shows a pronounced seasonal cycle: maximum in warm season and minimum in cold season, while the runoff (surface runoff+subsurface runoff) (R) is opposite, with maximum in cold season and minimum in warm season (exception: mountain areas wait till spring melt).
• Land surface hydrological cycle: most part of the states - land surface water is recharged during the cold season and discharged during the warm season, with some exceptions: the northern part states, snow melt plays an important role for land surface water recharge in the spring. In the US monsoon area discharged in the spring & recharges in the summer.
• Evolution of land surface memory: depends on time & space.
• Impact of land surface memory: • The west coast states has more large scale structure • US monsoon region seems more localized
Summary