Vol.31, No.03. 2020
Table of Contents
ISSN:1674-9928
CN:31-2050/P
RESEARCH-ARTICLE
Preliminary investigations on Arctic microalgae by joint application of fluorescent instruments
Correspondence: zhangfang@pric.gov.cn
ORCID:
Vol. 23, Issue 3, pp. 128-132 (2012) • DOI
Abstract
Basic Infomations
References
Attachments
Cited By
Abstract
Author Address:
1. Key Laboratory for Polar Science of State Oceanic Administration, Polar Research Institute of China, Shanghai 200136,China
1 Rat'kova T N, Wassmann P. Seasonal variation and spatial distribution of phyto- and protozooplankton in the central Barents Sea. J Mar Syst, 2002, 8: 47–75
2 Hoffmann L J, Peeken I, Lochte K, et al. Different reactions of Southern Ocean phytoplankton size classes to iron fertilization. Limnol Oceanogr, 2006, 51: 1217–1229
3 Zhang F, Su R, Wang X, et al. A fluorometric method for the discrimination of harmful algal bloom species developed by wavelet analysis. J Exp Mar Bio Eco, 2009, 368: 37–43
4 Yentsch C S, Yentsch C M. Fluorescence spectral signatures- characterization of phytoplankton populations by the use of excitation and emission- spectra. J Mar Res, 1979, 37: 471–483
5 Yentsch C S, Phinney D A. Spectral fluorescence: an taxonomic tool for studying the structure of phytoplankton populations. J Plankton Res, 1985, 7: 617–632
6 Babichenko S, Leeben A, Poryvkina L, et al. Variability of Chlorella sp. Int J Remote Sens, 2001, 33: 403–414
7 Westberry T K, Siegel D A. Phytoplankton natural fluorescence variability in the Sargasso Sea. Deep-Sea Res I, 2003, 50: 417–434
8 Su R G, Hu X P, Zhang C S, et al. Differentiation of algal populations by in vivo fluorescence. Environ Sci, 2007, 28(7): 1529–1533
9 Wang Z Y, Wang J T. The application of chlorophyll fluorescence detection techniques in the study of phytoplankton nutrient limitation. Mar Sci, 2008, 32(12): 97–101
10 Kim H H. New algae mapping technique by the use of an airborne laser fluorosensor. Applied Optics, 1973, 12: 1454–1459
11 Seppälä J, Balode M. Spatial distribution of phytoplankton in the Gulf of Riga during spring and summer stage. J Marine Syst, 1999, 23: 51–67
12 Ren B W, Zhao W H, Wang J T, et al. Three dimensional fluorescence excitation- emission matrix spectrum of dissolved organic substance in marine microalgaes growth process. Spectro Spectral Anal, 2008, 28(5): 1130–1134
13 Serôdio J, Vieira S, Cruz S, et al. Short-term variability in the photosynthetic activity of microphytobenthos as detected by measuring rapid light curves using variable fluorescence. Marine Biology, 2005, 146: 903–914
14 Seppälä J. Fluorescence properties of Baltic Sea phytoplankton. The Faculty of Biosciences of the University of Helsink, 2009
15 Sosik H M, Chisholm S W. A chlorophyll fluorescence from single cells: interpretation of flow cytometric signals. Limnol Oceanog, 34(8): 1749–1761
16 Jiao N Z, Yang Y H. Ecological studies on Prochlorococcus in China seas. Chin Sci Bull, 2002, 47: 485–491
17 Jiao N Z, Yang Y H, Hong N, et al. Dynamics of autotrophic picoplankton and heterotrophic bacteria in the East China Sea. Cont Shelf Res, 2005, 25: 1265–1279
18 Liu H, Suzuki K, Minami C, et al. Picoplankton community structure in the subarctic Pacific Ocean and the Bering Sea during summer 1999. Mar Ecol Prog Ser, 2002, 237: 1–14
19 Olson R J, Zettler E R, Anderson O K. Discrimination of eukaryotic phytoplankton cell types from light scatter and autofluorescence properties measured by flow cytometry. Cytometry, 1989, 10: 636–643
20 Zhang Q Q, Lei S H, Wang X L, et al. Discrimination of phytoplankton classes using characteristic spectra of 3D fluorescence spectra. Spectrochim Acta A, 2006, 63: 361–369
21 Li H Y, Zhang Q Q, Zhu C J, et al. Assessment of phytoplankton class abundance using in vivo synchronous fluorescence spectra. Anal Biochem, 2008, 377: 40–45
22 Zhang F, Su R G, Wang X L, et al. Identifying phytoplankton in seawater based on discrete excitation-emission fluorescence spectra. J Phycol, 2010, 46: 403–411
23 Zhang F, Su R G, He J F, et al. Study on fluorometric discrimination of phytoplankton based on time-series vectors of wavelet transform. Molecular and Biomolecular Spectroscopy Spectrochim Acta A, 2010, 75: 578–584
24 McMinn A, Hegseth E N. Quantum yield and photosynthetic parameters of marine microalgae from the southern Arctic Ocean, Svalbard. J Mar Biol Ass UK, 2004, 84: 865–871
25 Ban A, Aikawa S, Hattori H, et al. Comparative analysis of photosynthetic properties in ice algae and phytoplankton inhabiting Franklin Bay, the Canadian Arctic, with those in mesophilic diatoms during CASES 03-04. Polar Biosci, 2006, 19: 11–28
26 Cucci T L, Shumway S E, Newell R C, et al. Flow cytometry: a new method for characterization of differential ingestion, digestion and egestion by suspension feeders. Mar Ecol Prog Ser, 1985, 24: 201–204
27 Sun S C, Lu J, Zhang L H. Applications of flow cytometer in ecological studies of nano- and pico- phytoplankton. Chin J Ecol, 2000, 19(1): 72–78
28 Lu L, Su R G, Wang X L, et al. Study on the characters of phytoplankton chlorophyll fluorescence excitation spectra based on fourth-derivative. Spectro Spectral Anal, 2007, 27(11): 2307–2312
29 Kashino Y, Kudoh S, Hayashi Y, et al. Strategies of phytoplankton to perform effective photosynthesis in the North Water. Deep-Sea Res Ⅱ, 2002, 49: 5049–5061
Friend Links
Related Journals
Related Links
