Pim de Klerk Palynology

Photographs of pollen grains from plants in NE Siberia

 

Pim de Klerk: Staatliches Museum für Naturkunde, Karlsruhe, Germany, pimdeklerk@email.de

Bastian Niemeyer: Alfred-Wegener-Institute, Helmholtz-Centre for Polar and Marine Research, Potsdam, Germany, bastian.niemeyer@awi.de

Elena Raschke: Arctic and Antarctic Research Institute, St. Petersburg, Russia, rozochka19@yandex.ru

Larisa Savelieva: Institute of Earth Sciences, St. Petersburg State University, Russia, savelieval@mail.ru

Annette Teltewskoi: Institute of Botany and Landscape Ecology, Greifswald University, Germany, a.teltewskoi@uni-greifswald.de

Martin Theuerkauf: Institute of Geography and Geology, Greifswald University, Germany, martin.theuerkauf@uni-greifswald.de

Hans Joosten: Institute of Botany and Landscape Ecology, Greifswald University, Germany, joosten@uni-greifswald.de

Appendix to:

De Klerk, P., Teltewskoi, A., Theuerkauf, M., Joosten, H. (2014):

Vegetation patterns, pollen deposition and distribution of non-pollen palynomorphs in an ice-wedge polygon near Kytalyk (NE Siberia), with some remarks on Arctic pollen morphology

Polar Biology 37: 1393-1412

The final publication is available at Springer via  http://dx.doi.org/10.1007/s00300-014-1529-3

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Pollen grains of Betula exilis, with slightly protruding pores (1) and prominently protruding pores (2); grain sizes and exine thickness vary greatly (3); photos by Larisa Savelieva/Elena Raschke, from: Savelieva et al. (2013)

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Pollen grains of Duschekia fruticosa (Alnaster fruticosus, Alnus viridis ssp. fruticosa), with slightly protruding pores and only one, rather incospicuous arcus-like structure between the left and upper-left pores (4), and with prominently protruding pores with two well developed and three incospicuous arcus (5); grain sizes and exine thickness are variable; photos by Larisa Savelieva/Elena Raschke, from: Savelieva et al. (2013)

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Pollen grains of Ledum palustre (6) and Vaccinium vitis-ideae (7); photos by Larisa Savelieva/Elena Raschke, from: Savelieva et al. (2013)

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Pollen grains of Larix, pollen from completely developed cones (8, 9, 10) display severe damages including modifications of the pollen grain wall structure (10); photos by Bastian Niemeyer

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Pollen grains of Pedicularis lapponica; photos by Larisa Savelieva/Elena Raschke, from: Savelieva et al. (2013)

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Grain of the pollen type RUBUS CHAMAEMORUS (sensu Beug 2004); from ice-wedge polygon mire Lhc11 near Kytalyk, peat section j20.10, sample at 7 cm depth; stacked photo by Martin Theuerkauf

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The pollen type RUMEX AQUATICUS T. (sensu Fægri & Iversen 1989), in the Kytalyk area produced by Rumex arcticus; both tricolporate grains (14) and tetracolporate grains occur (15); the pollen grain wall is scabrate (16); from ice-wedge polygon mire Lhc11 near Kytalyk, peat section j20.10, sample at 15 cm depth; stacked photos by Martin Theuerkauf

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Pollen grain of Valeriana capitata; the echinae are often small and inconspicuous; photo by Larisa Savelieva/Elena Raschke, from: Savelieva et al. (2013)

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Unidentified 3-colpate pollen type with a scabrate wall structure; from ice-wedge polygon mire Lc04 near Chokurdakh, peat section h16; sample at 7 cm depth; stacked photo by Martin Theuerkauf

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Drawings of four different morphological types of Assulina muscorum tests. Types 1 and 2 have the greatest width in their upper third, and types  3 (asymmetrical) and type 4 (symmetrical) have the greatest width in the centre of the tests; redrawn after Schönborn & Peschke (1990)

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ASSULINA MUSCORUM TYPE 2 (20) with the largest width in the upper third of the shell, and ASSULINA MUSCORUM TYPE 4 (21) with the largest width in the centre; from ice-wedge polygon mire Lc04 near Chokurdakh, surface sample u23; photos by Martin Theuerkauf

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Pollen grains of Saxifraga cernua with a prevailing scabrate pollen wall structure and hardly detectable rugulae/striae; photos by Larisa Savelieva/Elena Raschke, from: Savelieva et al. (2013)

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Pollen grains of Glyceria declinata with a slightly ovalish shape (24), and with a roundish shape (25); the pollen grains are variable in size; stacked photos by Martin Theuerkauf

    Beug, H.J. (2004): Leitfaden der Pollenbestimmung für Mitteleuropa und angrenzende Gebiete. Verlag Dr. Friedrich Pfeil, München.

    Fægri, K. & Iversen, J. (1989): Textbook of pollen analysis (revised by Fægri, K., Kaland, P.E. & Krzywinski, K.). Wiley, Chichester.

    Savelieva, L.A., Raschke, E.A. & Titova, D.V. (2013): Photographic atlas of plants and pollen of the Lena River Delta. St-Petersburg State University, St-Petersburg.

    Schönborn, W. & Peschke, P. (1990): Evolutionary studies on the Assulina-Valkanovia complex (Rhizopoda, Testaceafilosia) in Sphagnum and soil. Biol. Fertil. Soils 9: 95-100.

 

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