jgr-oceans, october 2013 issue
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Combining Observations & Numerical Model Results to Improve Estimates of Hypoxic Volume within the Chesapeake Bay
JGR-Oceans, October 2013 issue
Aaron Bever, Marjy Friedrichs, Carl Friedrichs, Malcolm Scully, Lyon Lanerolle
OUTLINE / SUMMARY
1. Relation to US-IOOS Modeling Testbed program and general methods.
2. Use 3D models to examine uncertainties in interpolating hypoxic volume.
• Observed DO have coarse spatial resolution = spatial error
• Observed DO are not a “snapshot” = temporal error
3. Use 3D models to improve EPA-CBP interpolations of hypoxic volume.
p.1 of 21
Relationship to US-IOOS Modeling Testbed:
Part of Coastal & Ocean Modeling Testbed (COMT) Project headed by Rick Luettich (UNC), funded by NOAA US-IOOS Office
COMT Mission: Accelerate the transition of scientific and technical advances from the modeling research community to improve federal
agencies’ operational ocean products and services
Initial Phase: Estuarine Hypoxia, Shelf Hypoxia and Coastal Inundation Modeling Testbeds; Cyber-infrastructure to advance
interoperability and archiving
Combining Observations & Numerical Model Results to Improve Estimates of Hypoxic Volume within the Chesapeake Bay
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• Compare relative skill and strengths/weaknesses of various Chesapeake Bay models
• Assess how model differences affect water quality simulations
• Recommend improvements to agency operational products associated with managing hypoxia
General COMT Estuarine Hypoxia modeling methods:
p.3 of 21
Combining Observations & Numerical Model Results to Improve Estimates of Hypoxic Volume within the Chesapeake Bay
Five hydrodynamic models configured for the Bay
p.4 of 21
TODAY’S TALK
Five hydrodynamic models configured for the Bay
p.4 of 21
o ICM: EPA-CBP model; complex biologyo BGC: NPZD-type biogeochemical modelo 1eqn: Simple one equation respiration
(includes SOD)o 1term-DD: depth-dependent respiration
(not a function of x, y, temperature, nutrients…)
o 1term: Constant net respiration(not a function of x, y, temperature, nutrients OR depth…)
Five dissolved oxygen (DO) models configured for the Bay
p.5 of 21
o ICM: EPA-CBP model; complex biologyo BGC: NPZD-type biogeochemical modelo 1eqn: Simple one equation respiration
(includes SOD)o 1term-DD: depth-dependent respiration
(not a function of x, y, temperature, nutrients…)
o 1term: Constant net respiration(not a function of x, y, temperature, nutrients OR depth…)
TODAY’S TALK
Five dissolved oxygen (DO) models configured for the Bay
p.5 of 21
Today’s talk = Four combinations:
o CH3D + ICM EPA-CBP modelo CBOFS + 1termo ChesROMS + 1termo ChesROMS + 1term+DD
Coupled hydrodynamic-DO models
-- Physical models are similar, but grid resolution differs-- Biological/DO models differ dramatically-- All models run for 2004 and 2005 and compared to EPA Chesapeake Bay Program DO observations
p.6 of 21
-- The models all have significant skill (normalized RSMD < 1) in reproducing observed bottom dissolved oxygen (DO).-- The four models all reproduce observations of bottom DO about equally well.-- Unlike observations, model output is continuous in space and time.-- So use the continuous model output to estimate uncertainties caused by CBP interpolations of discontinous observed data.
Model skill: Bottom DOTotal RMSD2 = Bias2 + unbiased RMSD2
p.7 of 21
Combining Observations & Numerical Model Results to Improve Estimates of Hypoxic Volume within the Chesapeake Bay
JGR-Oceans, October 2013 issue
Aaron Bever, Marjy Friedrichs, Carl Friedrichs, Malcolm Scully, Lyon Lanerolle
OUTLINE
1. Relation to US-IOOS Modeling Testbed program and general methods.
2. Use 3D models to examine uncertainties in interpolating hypoxic volume.
• Observed DO have coarse spatial resolution = spatial error
• Observed DO are not a “snapshot” = temporal error
3. Use 3D models to improve EPA-CBP interpolations of hypoxic volume.
p.8 of 21
Four Types of Hypoxic Volume Estimates
Interpolation Method used for #1 - #3: CBP Interpolator Tool HV = DO < 2 mg/L
#1) Observations Of 99 CBP stations (red dots), 30-65
are sampled each “cruise” Each cruise takes 1 to 2 weeks
#2) Modeled Absolute Match: Same 30-65 stations are “sampled” at
same time/place as observations are available
#3) Modeled Spatial Match: Same stations are “sampled” in
space, but samples are taken synoptically (i.e., all at once in time)
#4) Integrated 3D Model: Hypoxic volume is computed from
integrating over all model grid cells(“CBP” = EPA Chesapeake Bay Program)
p.9 of 21
CH3D-ICM
ChesROMS+1term
Observations-derived
= Absolute Match
Hypoxic Volume Estimates• When observations
and model are interpolated in same way, the match is reasonably good
p.10 of 21
CH3D-ICM
ChesROMS+1term
Data-derived
= Absolute MatchCH3D-ICM
ChesROMS+1term
Observations-derived
Hypoxic Volume Estimates• When observations
and model are interpolated in same way, the match is reasonably good
• But interpolated HV underestimates actual HV for every cruise
p.11 of 21
CH3D-ICM
ChesROMS+1term
Observations-derived
Hypoxic Volume Estimates
p.12 of 21
• When observations and model are interpolated in same way, the match is reasonably good
• But interpolated HV underestimates actual HV for every cruise
• Much of this disparity could be due to temporal errors (red bars)
• When observations and model are interpolated in same way, the match is reasonably good
• But interpolated HV underestimates actual HV for every cruise
• Much of this disparity could be due to temporal errors (red bars)
• Same pattern across all 4 models for both 2004 & 2005
p.13 of 21
Spatial errors show interpolated HV is almost always too low (up to 5 km3)
The temporal errors from non-synoptic sampling can be as large as spatial errors (~5 km3)
Similar patterns across all 4 models for both 2004 & 2005
p.14 of 21
Combining Observations & Numerical Model Results to Improve Estimates of Hypoxic Volume within the Chesapeake Bay
JGR-Oceans, October 2013 issue
Aaron Bever, Marjy Friedrichs, Carl Friedrichs, Malcolm Scully, Lyon Lanerolle
OUTLINE
1. Relation to US-IOOS Modeling Testbed program and general methods.
2. Use 3D models to examine uncertainties in interpolating hypoxic volume.
• Observed DO have coarse spatial resolution = spatial error
• Observed DO are not a “snapshot” = temporal error
3. Use 3D models to improve EPA-CBP interpolations of hypoxic volume.
p.15 of 21
Blue triangles = 13 selected CBP stations
Improving observation-derived hypoxic volumes
Reduce Temporal errors:
1. Choose subset of 13 CBP stations
2. Routinely sampled within 2.3 days of each other
3. Characterized by high DO variability
p.16 of 21
Blue triangles = 13 selected CBP stations
Improving observation-derived hypoxic volumes
Reduce Temporal errors:
1. Choose subset of 13 CBP stations
2. Routinely sampled within 2.3 days of each other
3. Characterized by high DO variability
But why 13 stations?
p.16 of 21
Improving observation-derived hypoxic volumes
Modeled Integrated 3D
vs.Spatial Match for
Different Station Sets
p.17 of 21
Improving observation-derived hypoxic volumes
p.18 of 21
Reduce Spatial errors:
1. For each model and each cruise, derive a correction factor as a function of interpolated HV that “corrects” this 13-station Spatial Match HV to equal the Integrated 3D HV.
Reduce Spatial errors:
1. For each model and each cruise, derive a correction factor as a function of interpolated HV that “corrects” this 13-station Spatial Match HV to equal the Integrated 3D HV. 2. Apply correction factor to HV time-series
3. Scaling-corrected “interpolated” HV more accurately represents true HV
Before Scaling
AfterScaling
Improving observation-derived hypoxic volumes
p.19 of 21
Interannual (1984-2012) corrected (i.e., scaled) time series of observed Hypoxic Volume
p.20 of 21
Time-series of corrected hypoxic volume for 1984-2012 are provided within JGR article (annual maximum HV, annual duration of HV, annual cumulative HV), and corrected HV for every CBP cruise is provided in JGR electronic supplement.
Information from multiple models (2004-2005) has been used to assess uncertainties in present CBP interpolated hypoxic volume estimates
• Temporal uncertainties: up to ~5 km3
• Spatial uncertainties: up to ~5 km3
These are significant, given maximum HV is ~10-15 km3
A method for correcting interpolated HV time series for temporal and spatial errors has been presented, based on the 3D structure of multiple model DO results
• 13 stations (sample in 2 days) do as well for HV as 40-60 or more• Corrected HV for 1984-2012 are downloadable from JGR website
Summary/Conclusions
Combining Observations & Numerical Model Results to Improve Estimates of Hypoxic Volume within the Chesapeake Bay
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