2014 Modul 3 Plankton

PLANKTONOLOGI

M O D U L 3 :

METODA PENGUKURAN PRODUKTIVITAS PRIMER DI LAUT DAN SAMUDRA,

ANALISIS DAN INTEPRETASIOleh : MUHAMMAD ZAINURI

1. Ultraplankton, berukuran < 5 m2. Nanoplankton, berukuran diantara 5 - 60 m3. Microplankton, berukuran diantara 60 - 500 m4. Mesoplankton, berukuran diantara 0.5 - 1 mm5. Macroplankton, berukuran diantara 1 - 10 mm 6. Megaloplankton, berukuran > 10 mm

Cushing et al. ( 1958 ) :

PLANKTON BERDASARKAN UKURAN

1. Ultrananoplankton, berukuran < 2 m2. Nanoplankton, berukuran diantara 2 - 20 m3. Microplankton, berukuran diantara 20 - 200 m4. Mesoplankton, berukuran diantara 200 m - 2 mm5. Macroplankton, berukuran diantara 2 - 20 mm6. Mikronekton, berukuran diantara 20 - 200 mm7. Megaloplankton (Plankton Gelatin), berukuran > 20 mm

Omori dan Ikeda (1992) :

PLANKTON BERDASARKAN UKURAN

Plankton dan Jaring - Jaring Makanan :

Phytoplankton :Produser Primer

Autotrof

Zooplankton :Konsumer Primer

Produser SekunderHeterototrof

I k a n :Konsumer Primer

dan SekunderHeterototrof

Plankton dan Piramida Makanan :

Phytoplankton :Produser Primer

Autotrof

Zooplankton :Konsumer Primer

Produser SekunderHeterototrof

I k a n :Konsumer Primer

dan SekunderHeterototrof

MORPHOMETRI PLANKTON

The study of food-chains, through which matter and energy flow,

requires accurate assessments of one or both variables in respective gravimetric or energitics units

Study tentang jaring – jaring makanan, dimana terjadi perpindahan / arus bahan dan energi, membutuhkan suatu tolok ukur yang cukup akurat seperti pendekatan gravimetrik atau energi

Dumont et. al. ( 1 9 7 5 ) :


Although compartementalized ecosystem models require consistent units of energy or biomass, less theoretical research in

aquatic ecology also benefits from precise quantitative estimates of their

variables.

Meskipun sistem pengkotakan dalam model membutuhkan unit energi atau biomass yang konsisten, namun banyak sekali teori penelitian tidak memanfaatkan sistim kuantifikasi yang jelas terhadap variabel – variabel yang digunakan.

Dumont et. al. ( 1 9 7 5 ) :


This statement may seem self-evident, but standing crops and production are too frequently expressed in terms of

numbers of organisms per unit of volume or surface area

Pernyataan tersebut seperti membuktikan terhadap dirinya sendiri, dimana panen dan produksi sering diekspresikan dalam term jumlah biota per unit volume atau luas area.

Dumont et. al. ( 1 9 7 5 ) :

MENGAPA MORPHOMETRI ?

Body sizes is one of the most obvious features of any animal and one of the

most important

Ukuran tubuh adalah salah satu pandangan atau gambaran utama tentang seekor biota

Cohen et. al. ( 1 9 9 3 ) :

MENGAPA MORPHOMETRI ?

Size influences how much energy an animal needs, how much food it can

gathered, and which other organisms can try to eat it, among other aspects

of life history.

Ukuran tubuh akan mempengaruhi seberapa banyak jumlah energi dibutuhkan oleh seekor biota, dan seberapa jumlah pakan harus diperoleh, dan biota – biota jenis apa yang yang memangsa, selain berbagai aspek dari siklus hidup.

Cohen et. al. ( 1 9 9 3 ) :

Genus :Keratella

Quadrata Group

Formula Perhitungan :a * b * c

Konsep :Epipedik Paralela

b

c

a : Panjangb : Lebarc : Tinggi

Formula Sederhana :Bila b = 0.7 a

c = 0.33 aMaka v = 0.22 a 3

Penghitungan Appendik dalam % dari Volume Tubuh

Parameter Ukur untuk Formula :a * b * c

5 % dari b * v * x

dimana : panjang duri ekor

x =

panjang tubuh

ab

c


Genus :Keratella

Cochlearis Group

Formula Perhitungan :0.13 a * b 2

Konsep :½ Kerucut : ( r 2 π a ) / 6

a : Panjangb : Lebar


Maka v = 0.02 a 3

ab

Genus :Keratella

Cochlearis Group

a : Panjangb : Lebar

Parameter Ukur untuk Formula :a = bb = 2 r

ab

Genus :Notholca

Formula Perhitungan :0.13 ( 3 abc + 4 c 3 )

Konsep :Segmen Ellipsoid

1/6 χ h ( 3 ρ1 ρ2 + h 2 )



c = 0.2 aMaka v = 0.035 a 3

ca

b

Genus :Notholca

Parameter Ukur untuk Formula :

a = 2 ρ1b = 2 ρ2c = h


ca

b

Genus :Ploesoma

Formula Perhitungan :0.52 a b c

Konsep : Ellipsoid Umum

( 4 r1 r2 r3 π ) / 3



c = 0.4 aMaka v = 0.1 a 3

Untuk P. hudsoni

a

bc

Genus :Ploesoma


Konsep : Ellipsoid Umum

( 4 r1 r2 r3 π ) / 3



c = 0.66 aMaka v = 0.23 a 3

untuk P. triacanthum

a

bc

Genus :Ploesoma


a = 2 r1b = 2 r2c = 2 r3


a

bc

Genus :Polyarthra

Formula Perhitungan :a * b * c

Konsep : Epipedik Paralel



c = 0.4 amaka v = 0.28 a 3

ab

c

Penghitungan Appendik dalam % dari Volume Tubuh


a * b * c

10 % volume tubuh


ab

c

Genus :Pompholyx


Konsep : Silinder : r 2 π h



c = 0.5 amaka v = 0.15 a 3

a

bc

Genus :Pompholyx

Parameter Ukur untuk Formula :r 2 = a b / 4

h = c / 2


a

bc

Genus :Synchaeta

Formula Perhitungan :0.23 a b2

Konsep : Kerucut : r 2 π h / 3



c = 0.6 amaka v = 0.1 a 3

a

b

Genus :Synchaeta


a = hb = 2 r


a

b

Genus :Testudinella


Konsep : Silinder : r 2 π h


Formula Sederhana :Bila b = a

c = 0.2 amaka v = 0.08 a 3

a

bc

Genus :Testudinella

Parameter Ukur untuk Formula :r 2 = a b / 4

h = c / 2

10 % volume tubuh


a

bc

Genus :Trichocerca

Formula Perhitungan :0.52 a b 2

Konsep : Silinder + Kerucut : r 2 π h + [( r 2 π h )] /

3


Formula Sederhana :Bila a & b harus

diukurmaka v = 0.52 ab 2

ab

Genus :Trichocerca

Penghitungan Appendik dalam % dari Volume

Tubuh0.6 % * volume tubuh

* panjang tubuh


ab


h = a / 2r = b / 2

p : Kelilings : Luas Permukaan

p

a : Tinggib : Kemiringan

sb

a

d : Diameterh : Tinggi

d

h

F = P 2

A = H / d dimana H dS = h * d = A d 2P = 2 ( h + d ) = 2 d ( A + 1 )P = P 2 / ( 4 π S ) = ( A + 1 ) 2 / π A

PENDEKATAN PENGUKURAN PRODUKTIVITAS PRIMER BERDASARKAN KANDUNGAN KLOROFIL

STRUKTUR KIMIAWI KLOROFIL

http://en.wikipedia.org/wiki/File:Chlorophyll-a-3D-vdW.png

http://en.wikipedia.org/wiki/File:AYool_SEAWIFS_annual.png

Chlorophyll a Chlorophyll b Chlorophyll c1 Chlorophyll c2 Chlorophyll d

Molecular formula

C55H72O5N4Mg C55H70O6N4Mg C35H30O5N4Mg C35H28O5N4Mg C54H70O6N4Mg

C3 group -CH=CH2 -CH=CH2 -CH=CH2 -CH=CH2 -CHO

C7 group -CH3 -CHO -CH3 -CH3 -CH3

C8 group -CH2CH3 -CH2CH3 -CH2CH3 -CH=CH2 -CH2CH3

C17 group -CH2CH2COO-Phytyl

-CH2CH2COO-Phytyl

-CH=CHCOO

H

-CH=CHCOO

H

-CH2CH2COO-Phytyl

C17-C18 bond Single Single Double Double Single

Occurrence Universal Mostly plants Various algae Various algae Cyanobacteria

KLOROFIL A KLOROFIL B

KLOROFIL C1

KLOROFIL C2KLOROFIL D

http://en.wikipedia.org/wiki/File:Chlorophyll_a.svg

http://en.wikipedia.org/wiki/File:Chlorophyll_b.svg

http://en.wikipedia.org/wiki/File:Chlorophyll_d.svg

http://en.wikipedia.org/wiki/File:Chlorophyll_c1.svg

http://en.wikipedia.org/wiki/File:Chlorophyll_c2.svg

http://en.wikipedia.org/wiki/File:Chlorophyll_ab_spectra.png

Absorbance spectra of free chlorophyll a (green) and b (red) in a solvent. The spectra of chlorophyll molecules are slightly modified in vivo depending on specific pigment-protein interactions.

Measurement of the absorption of light is complicated by the solvent used to extract it from plant material, which affects the values obtained,

In diethyl ether, chlorophyll a has approximate absorbance maxima of 430 nm and 662 nm, while chlorophyll b has approximate maxima of 453 nm and 642 nm The absorption peaks of chlorophyll a are at 665 nm and 465 nm. Chlorophyll a fluorescens at 673 nm (maximum) and 726 nm. The peak molar absorption coefficient of chlorophyll a exceeds 105 M−1 cm−1, which is among the highest for organic compounds.

http://en.wikipedia.org/wiki/Absorbance

http://en.wikipedia.org/wiki/Diethyl_ether

http://en.wikipedia.org/wiki/Fluorescence

http://en.wikipedia.org/wiki/Molar_absorptivity

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