Access the full text.
Sign up today, get DeepDyve free for 14 days.
Loading next page...
/lp/springer-journals/depth-distribution-of-photosynthetic-pigments-and-diatoms-in-the-4bnkaeitHy
References (43)
-
Angela Wulff, K. Sundbäck, C. Nilsson, L. Carlson, B. Jonsson (1997)
Effect of sediment load on the microbenthic community of a shallow-water sandy sedimentEstuaries, 20
-
G. Underwood, J. Kromkamp (1999)
Primary Production by Phytoplankton and Microphytobenthos in EstuariesAdvances in Ecological Research, 29
-
C. Totti (2003)
Influence of the Plume of the River Po on the Distribution of Subtidal Microphytobenthos in the Northern Adriatic Sea, 46
-
K. Sundbäck, A. Miles (2002)
Role of microphytobenthos and denitrification for nutrient turnover in embayments with floating macroalgal mats: a spring situationAquatic Microbial Ecology, 30
-
A. Wulff, C. Nilsson, K. Sundbäck, S.-Å. Wängberg, S. Odmark (1999)
UV effects on microbenthos – a four-month field experimentAquatic Microbial Ecology, 19
-
C. J. F. ter Braak (1994)
Canonical community ordinationPart 1. Basic theory and linear methods, Ecoscience 1
-
J. Nelson, J. Eckman, C. Robertson, R. Marinelli, R. Jahnke (1999)
Benthic microalgal biomass and irradiance at the sea floor on the continental shelf of the South Atlantic Bight: Spatial and temporal variability and storm effectsContinental Shelf Research, 19
-
J. Thioulouse, D. Chessel, S. Dolédec, J. Olivier (1997)
ADE-4: a multivariate analysis and graphical display softwareStatistics and Computing, 7
-
G. Cadée, J. Hegeman (1974)
Primary production of the benthic microflora living on tidal flats in the Dutch Wadden SeaNetherlands Journal of Sea Research, 8
-
S. Dolédec, D. Chessel (1994)
Co‐inertia analysis: an alternative method for studying species–environment relationshipsFreshwater Biology, 31
-
B. F. J. Manly (1997)
Distance matrices and spatial data. In Randomization, Bootstrap and Monte Carlo Methods in Biology -
V. Brotas, M. Plante-Cuny (1998)
Spatial and temporal patterns of microphytobenthic taxa of estuarine tidal flats in the Tagus Estuary (Portugal) using pigment analysis by HPLCMarine Ecology Progress Series, 171
-
Hugh MacIntyre, J. Cullen (1995)
Fine-scale vertical resolution of chlorophyll and photosynthetic parameters in shallow-water benthosMarine Ecology Progress Series, 122
-
L. Cahoon, R. Laws, Carrie Thomas (1994)
Viable diatoms and chlorophylla in continental slope sediments off Cape Hatteras, North CarolinaDeep-sea Research Part Ii-topical Studies in Oceanography, 41
-
L. J. Stal, P. Caumette (1994)
Microbial Mats. Structure, Development and Environmental Significance. NATO ASI Series G: Ecological Sciences -
P. Leavitt (1993)
A review of factors that regulate carotenoid and chlorophyll deposition and fossil pigment abundanceJournal of Paleolimnology, 9
-
R. Stevenson, E. Stoermer (1981)
QUANTITATIVE DIFFERENCES BETWEEN BENTHIC ALGAL COMMUNITIES ALONG A DEPTH GRADIENT IN LAKE MICHIGAN 1, 2Journal of Phycology, 17
-
H. Yap
Benthic energy dynamics in a southern Baltic ecosystem -
C. Barranguet, M. Plante-Cuny, Eliane Alivon (1996)
Microphytobenthos production in the Gulf of Fos, French Mediterranean coastHydrobiologia, 333
-
C. Braak (1994)
Canonical community ordination. Part I: Basic theory and linear methodsEcoscience, 1
-
(1996)
Response of benthic microbial mats -
S.W. Wright, S. W. Jeffrey (1997)
Phytoplankton Pigments in Oceanography -
Hugh MacIntyre, R. Geider, Douglas Miller (1996)
Microphytobenthos: The ecological role of the “secret garden” of unvegetated, shallow-water marine habitats. I. Distribution, abundance and primary productionEstuaries, 19
-
C. Braak, P. Verdonschot (1995)
Canonical correspondence analysis and related multivariate methods in aquatic ecologyAquatic Sciences, 57
-
W. Admiraal, H. Peletier, H. Zomer (1982)
Observations and experiments on the population dynamics of epipelic diatoms from an estuarine mudflatEstuarine Coastal and Shelf Science, 14
-
A. Wulff, C. Nilsson, K. Sundbäck, S. Wängberg, S. Odmark (1999)
UV radiation effects on microbenthos - a four month field experimentAquatic Microbial Ecology, 19
-
E. Peters (1996)
Prolonged darkness and diatom mortality: II. Marine temperate speciesJournal of Experimental Marine Biology and Ecology, 207
-
S. Wright, S. Jeffrey (1997)
High-resolution HPLC system for chlorophylls and carotenoids of marine phytoplankton -
P. Leavitt, S. Carpenter (1990)
Aphotic pigment degradation in the hypolimnion: Implications for sedimentation studies and paleolimnologyLimnology and Oceanography, 35
-
L. Cahoon (2002)
THE ROLE OF BENTHIC MICROALGAE IN NERITIC ECOSYSTEMS -
S. Odmark, A. Wulff, S. Wängberg, C. Nilsson, K. Sundbäck (1998)
Effects of UVB radiation in a microbenthic community of a marine shallow-water sandy sedimentMarine Biology, 132
-
K. Sundbäck, F. Linares, F. Larson, A. Wulff, A. Engelsen (2004)
Benthic nitrogen fluxes along a depth gradient in a microtidal fjord: The role of denitrification and microphytobenthosLimnology and Oceanography, 49
-
C. Barranguet, P. Herman, J. Sinke (1997)
Microphytobenthos biomass and community composition studied by pigment biomarkers: importance and fate in the carbon cycle of a tidal flatJournal of Sea Research, 38
-
G. Underwood, J. Phillips, Karen Saunders (1998)
Distribution of estuarine benthic diatom species along salinity and nutrient gradientsEuropean Journal of Phycology, 33
-
R. Goericke, J. Montoya (1998)
Estimating the contribution of microalgal taxa to chlorophyll a in the field--variations of pigment ratios under nutrient- and light-limited growthMarine Ecology Progress Series, 169
-
J. Teal (1962)
Energy Flow in the Salt Marsh Ecosystem of GeorgiaEcology, 43
-
K. Sundbäck, B. Jönsson (1988)
Microphytobenthic productivity and biomass in sublittoral sediments of a stratified bay, southeastern KattegatJournal of Experimental Marine Biology and Ecology, 122
-
F. Jochem (1999)
Dark survival strategies in marine phytoplankton assessed by cytometric measurement of metabolic activity with fluorescein diacetateMarine Biology, 135
-
K. Sundbäck, P. Nilsson, C. Nilsson, B. Jönsson (1996)
Balance Between Autotrophic and Heterotrophic Components and Processes in Microbenthic Communities of Sandy Sediments: A Field StudyEstuarine Coastal and Shelf Science, 43
-
R. Cormack, A. Underwood (1997)
Experiments in Ecology.Journal of Ecology, 85
-
V. Gall, G. Blanchard (1995)
Monthly HPLC measurements of pigment concentration from an intertidal muddy sediment of Marennes-Oléron Bay, FranceMarine Ecology Progress Series, 121
-
K. Sundbäck, L. Carlson, C. Nilsson, B. Jonsson, A. Wulff, S. Odmark (1996)
Response of benthic microbial mats to drifting green algal matsAquatic Microbial Ecology, 10
-
S. Vilbaste, K. Sundbäck, C. Nilsson, J. Truu (2000)
Distribution of benthic diatoms in the littoral zone of the Gulf of Riga, the Baltic SeaEuropean Journal of Phycology, 35
- Publisher
- Springer Journals
- Copyright
- Copyright © 2005 by Springer
- Subject
- Life Sciences; Freshwater & Marine Ecology; Ecology; Zoology
- ISSN
- 0018-8158
- eISSN
- 1573-5117
- DOI
- 10.1007/s10750-004-1417-x
- Publisher site
- See Article on Publisher Site
Abstract
The depth distribution of photosynthetic pigments and benthic marine diatoms was investigated in late spring at three different sites on the Swedish west coast. At each site, sediment cores were taken at six depths (7–35 m) by scuba divers. It was hypothesized that (1) living benthic diatoms constitute a substantial part of the benthic microflora even at depths where the light levels are <1% of the surface irradiance, and (2) the changing light environment along the depth gradient will be reflected in (a) the composition of diatom assemblages, and (b) different pigment ratios. Sediment microalgal communities were analysed using epifluorescence microscopy (to study live cells), light microscopy and scanning electron microscopy (diatom preparations), and HPLC (photosynthetic pigments). Pigments were calculated as concentrations (mg m−2) and as ratios relative to chlorophyll a. Hypothesis (1) was accepted. At 20 m, the irradiance was 0.2% of surface irradiance and at 7 m, 1%. Living (epifluorescent) benthic diatoms were found down to 20 m at all sites. The cell counts corroborated the diatom pigment concentrations, decreasing with depth from 7 to 25 m, levelling out between 25 and 35 m. There were significant positive correlations between chlorophyll a and living (epifluorescent) benthic diatoms and between the diatom pigment fucoxanthin and chlorophyll a. Hypothesis (2) was only partly accepted because it could not be shown that light was the main environmental factor. A principal component analysis on diatom species showed that pelagic forms characterized the deeper locations (25–35 m), and epipelic–epipsammic taxa the shallower sites (7–20 m). Redundancy analyses showed a significant relationship between diatom taxa and environmental factors – temperature, salinity, and light intensities explained 57% of diatom taxa variations.
Journal
Hydrobiologia – Springer Journals
Published: Jul 15, 2004