SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2806426114> ?p ?o ?g. }

Showing items 1 to 100 of ±174 with 100 items per page.

W2806426114 endingPage "224" @default.
W2806426114 startingPage "208" @default.
W2806426114 abstract "We studied the distribution and stable carbon-isotopic (δ13C) composition of various lipid biomarkers in suspended particulate matter (SPM) from the water column of Lake Chala, a permanently stratified crater lake in equatorial East Africa, to evaluate their capacity to reflect seasonality in water-column processes and associated changes in the lake's phytoplankton community. This lake has large seasonal variation in water-column dynamics (stratified during wet seasons and mixing during dry seasons) with associated phytoplankton succession. We analyzed lipid biomarkers in SPM collected monthly at 5 depths (0–80 m) from September 2013 to January 2015. Seasonal variation in total phytoplankton biovolume is strongly reflected in the concentration of phytadienes, a derivative of the general photosynthetic pigment chlorophyll. The wax and wane of several specific biomarker lipids between June and December 2014 reflect pronounced phytoplankton succession after deep mixing, starting with a long and sustained chlorophyte bloom (reflected by C23:1, C25:1 and C27:1 n-alkenes, and C21 and C23 n-alkanes), followed by a peak in diatoms between July and October (loliolide and isololiolide), and then eustigmatophytes (C30 and C32 1,15 diols) once stratification resumes in October. Peak abundance of the C19:1 n-alkene during shallow mixing of the water column in January–February 2014 can be tentatively linked to the seasonal distribution of cyanobacteria. The concentration, seasonal variability, and low δ13C values of the C28 fatty acid in the SPM suggest that this biomarker is produced in the water column of Lake Chala instead of having the typically assumed vascular plant origin. The δ13C signature of particulate carbon and all aquatic biomarkers become increasingly more negative (by up to 16‰) during mixing-induced episodes of high productivity, whereas enrichment would be expected during such blooms. This reversed fractionation may be attributed to chemically enhanced diffusion, which generates depleted HCO3− under high pH (>9) conditions, as occur in the epilimnion of Lake Chala during periods of high productivity. The influence of this process can potentially explain previously observed 13C-depleted carbon signatures in the paleorecord of Lake Chala, and should be considered prior to paleorecord interpretation of organic-matter δ13C values derived (partially) from aquatic organisms in high-pH, i.e. alkaline, lakes." @default.
W2806426114 created "2018-06-13" @default.
W2806426114 creator A5014649903 @default.
W2806426114 creator A5017403875 @default.
W2806426114 creator A5027439376 @default.
W2806426114 creator A5034816300 @default.
W2806426114 creator A5036570311 @default.
W2806426114 creator A5037177419 @default.
W2806426114 creator A5043015956 @default.
W2806426114 creator A5056603547 @default.
W2806426114 creator A5080576011 @default.
W2806426114 creator A5091383554 @default.
W2806426114 date "2018-07-01" @default.
W2806426114 modified "2023-09-28" @default.
W2806426114 title "Seasonal variability in the abundance and stable carbon-isotopic composition of lipid biomarkers in suspended particulate matter from a stratified equatorial lake (Lake Chala, Kenya/Tanzania): Implications for the sedimentary record" @default.
W2806426114 cites W1966384168 @default.
W2806426114 cites W1966986152 @default.
W2806426114 cites W1967968324 @default.
W2806426114 cites W1987231342 @default.
W2806426114 cites W1990162765 @default.
W2806426114 cites W1995336154 @default.
W2806426114 cites W2004865302 @default.
W2806426114 cites W2007156670 @default.
W2806426114 cites W2009607369 @default.
W2806426114 cites W2011772702 @default.
W2806426114 cites W2012592735 @default.
W2806426114 cites W2012792340 @default.
W2806426114 cites W2014360231 @default.
W2806426114 cites W2020388968 @default.
W2806426114 cites W2022224685 @default.
W2806426114 cites W2026315105 @default.
W2806426114 cites W2032329450 @default.
W2806426114 cites W2034575670 @default.
W2806426114 cites W2046629365 @default.
W2806426114 cites W2047666400 @default.
W2806426114 cites W2050031565 @default.
W2806426114 cites W2051179627 @default.
W2806426114 cites W2051190725 @default.
W2806426114 cites W2057844670 @default.
W2806426114 cites W2064609931 @default.
W2806426114 cites W2065068767 @default.
W2806426114 cites W2067308263 @default.
W2806426114 cites W2068656127 @default.
W2806426114 cites W2068729218 @default.
W2806426114 cites W2071024129 @default.
W2806426114 cites W2072688820 @default.
W2806426114 cites W2074030909 @default.
W2806426114 cites W2077144391 @default.
W2806426114 cites W2078204587 @default.
W2806426114 cites W2078546248 @default.
W2806426114 cites W2081322789 @default.
W2806426114 cites W2083625331 @default.
W2806426114 cites W2083879582 @default.
W2806426114 cites W2085441873 @default.
W2806426114 cites W2091802718 @default.
W2806426114 cites W2093448607 @default.
W2806426114 cites W2095617481 @default.
W2806426114 cites W2097705442 @default.
W2806426114 cites W2098316088 @default.
W2806426114 cites W2100319964 @default.
W2806426114 cites W2103710355 @default.
W2806426114 cites W2103793094 @default.
W2806426114 cites W2111493552 @default.
W2806426114 cites W2114877674 @default.
W2806426114 cites W2116463846 @default.
W2806426114 cites W2123112390 @default.
W2806426114 cites W2126022287 @default.
W2806426114 cites W2128429941 @default.
W2806426114 cites W2135640445 @default.
W2806426114 cites W2137056018 @default.
W2806426114 cites W2138812961 @default.
W2806426114 cites W2139229457 @default.
W2806426114 cites W2139364700 @default.
W2806426114 cites W2152677021 @default.
W2806426114 cites W2159046029 @default.
W2806426114 cites W2162535433 @default.
W2806426114 cites W2164138186 @default.
W2806426114 cites W2166873340 @default.
W2806426114 cites W2168509438 @default.
W2806426114 cites W2169868455 @default.
W2806426114 cites W2170519544 @default.
W2806426114 cites W2300091028 @default.
W2806426114 cites W2322352733 @default.
W2806426114 cites W2324257888 @default.
W2806426114 cites W2402446742 @default.
W2806426114 cites W2520727160 @default.
W2806426114 cites W2716143540 @default.
W2806426114 cites W2774056847 @default.
W2806426114 cites W4236768654 @default.
W2806426114 doi "https://doi.org/10.1016/j.quascirev.2018.05.023" @default.
W2806426114 hasPublicationYear "2018" @default.
W2806426114 type Work @default.
W2806426114 sameAs 2806426114 @default.
W2806426114 citedByCount "45" @default.
W2806426114 countsByYear W28064261142018 @default.
W2806426114 countsByYear W28064261142019 @default.
W2806426114 countsByYear W28064261142020 @default.
W2806426114 countsByYear W28064261142021 @default.