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Page 1: Estimating Phytoplankton Absorption Spectra with the Bricaud and Stramski Model:
Page 2: Estimating Phytoplankton Absorption Spectra with the Bricaud and Stramski Model:

Estimating Phytoplankton Absorption Spectra with the Bricaud and Stramski Model:

How Robust is the Model?

Andy Canion

July 16, 2004

Page 3: Estimating Phytoplankton Absorption Spectra with the Bricaud and Stramski Model:

Spectral Decomposition

atot = aw + aCDOM + aΦ + aNAP

These can all be determined with Spectrophotometry

Page 4: Estimating Phytoplankton Absorption Spectra with the Bricaud and Stramski Model:

SpectrophotometrySpectrophotometry

a(λ) = 2.303*100 [ODfilter – ODblank – ODnull] pathlengh*β

-Cary 50 Spectrophotometer

-Single Beam

-Measures in Optical Density (OD) not absorption coefficient (a(m^-1))

-Corrections:

Null, Blank, OD conversion, β

Page 5: Estimating Phytoplankton Absorption Spectra with the Bricaud and Stramski Model:

Spectral Decomposition

atot = aw + aCDOM + aΦ + aNAP

Only These Can Be determined with an AC9

ap

How do we decompose particulate absorption?

Page 6: Estimating Phytoplankton Absorption Spectra with the Bricaud and Stramski Model:

Spectral Decomposition

atot = aw + aCDOM + aΦ + aNAP

Only These Can Be determined with an AC9

ap

How do we decompose particulate absorption?

Modeling!

Page 7: Estimating Phytoplankton Absorption Spectra with the Bricaud and Stramski Model:

Model From Bricaud and Stramski (1990)

aNAP(λ) = ap(λ) – aΦ(λ)

aNAP(λ) = Ae(-Sλ)

2) Ae(-580 S) – 0.92Ae(-692.5 S) = ap(580) – 0.92ap(692.5)

1) 0.99Ae(-380 S) – A(-505 S) = 0.99ap(380) – ap(505)

-Two Equations with two unknowns

-You only need the particulate absorption spectrum

Page 8: Estimating Phytoplankton Absorption Spectra with the Bricaud and Stramski Model:

My Approach:

The variability in phytoplankton absorption spectra measured in the spectrophotometer using the Kishino methanol extraction method

VS.

The variability for calculated phytoplankton absorption spectra using different slopes for the non-algal particle spectrum (S= 0.012, 0.011, 0.009, 0.007)

Page 9: Estimating Phytoplankton Absorption Spectra with the Bricaud and Stramski Model:

300 400 500 600 700 800-0.02

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0.02

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wavelength(lambda)

a(m

-1)

CruiseAB 4m

apanap(modeled)anap(measured)aphi(modeled)aphi(measured)

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300 400 500 600 700 800-1

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wavelength (lambda)

a (m

- 1)

Measured aphi with Standard Deviation

Measured aΦ spectra (normalized to total aΦ) with Standard Deviation (red). Standard Deviation ~3.16X10-4

Page 11: Estimating Phytoplankton Absorption Spectra with the Bricaud and Stramski Model:

400 450 500 550 600 650 7000

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7x 10

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wavelength(lambda)

a(m

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Calculated aphi (cruise 4m sample, sd in red)

Calculated aΦ spectra using different values of aNAP slope with Standard Deviation (red).

Standard Deviation ~5.05X10-4

Page 12: Estimating Phytoplankton Absorption Spectra with the Bricaud and Stramski Model:

300 400 500 600 700 800-2

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7x 10

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wavelength(lambda)

a(m

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Calculated aphi (cruise 4m sample, sd in red)

-What the previous graph actually looks like-

Page 13: Estimating Phytoplankton Absorption Spectra with the Bricaud and Stramski Model:

400 450 500 550 600 650 7000

0.1

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Wavelength(lambda)

Per

cent

Err

or

Percent Error for changes in aNAP slope

Percent Error for Changes in aNap slope Highest curve is dock sample A

Page 14: Estimating Phytoplankton Absorption Spectra with the Bricaud and Stramski Model:

400 450 500 550 600 650 700-0.02

0

0.02

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wavelength(lambda)

a(m

- 1)

Cruise 4m ac9

apaphiaphi(spec)

Calculated aphi from ac9 cruise data compared to spectrophotometer

Page 15: Estimating Phytoplankton Absorption Spectra with the Bricaud and Stramski Model:

400 450 500 550 600 650 7000

0.02

0.04

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0.1

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wavelength(lambda)

a(m

- 1)

Cruise 10m AC9

apaphiaphi(spec)

Calculated aphi from ac9 cruise data compared to spectrophotometer

Page 16: Estimating Phytoplankton Absorption Spectra with the Bricaud and Stramski Model:

Conclusions

-Problems with AC9 Cruise Data are likely the cause of big differences in aΦ

-Model is robust for spectrophotometer data

-Assumptions of the Model:

Minimal absorption by accessory pigments at 380nm, 505nm, 580nm, 692nm

380:505 ratio and 580:692 ratio are both ~1 for aΦ

Wavelength pairs are far enough apart to estimate slope of ap accurately

How could these be broken?

-Even though this model was developed for the open ocean, it still works in a tidal estuary.

Page 17: Estimating Phytoplankton Absorption Spectra with the Bricaud and Stramski Model:

A Pretty Picture for Curt