Lake Groß-Zimmern core B/97-BK 8, depth 28.95 m (Eocene of Germany)

Where: Hesse, Germany (49.9° N, 8.8° E: paleocoordinates 47.3° N, 4.6° E)

• coordinate stated in text

• hand sample-level geographic resolution

When: Middle Eocene (47.8 - 37.7 Ma)

• Palynozone PZ 2a, with the fagaceous pollen Tricolporopollenites cingulum/liblarensis as dominant elements.

•The pollen and spore taxa are also known from the nearby lacustrine record of Messel (see Thiele-Pfeiffer 1988), which is of latest early Eocene to early middle Eocene age (Lenz et al. 2015). It can be assumed that the lacustrine sequence at Groß-Zimmern is of a similar age. Accordingly, the palynomorph assemblage fits best to zones Hu4 to Ho2 of Pflug (1986) and 14 to 15 of Krutzsch (1966), which correspond to a middle Eocene (Lutetian/Bartonian) age.

•Punctilongisulcites microechinatus occuring in this sample is restricted to the middle Eocene.

Environment/lithology: crater lake; shale

• Maar lake with a diameter of 250-400 m, with shallow to moderately deep water. PZ 2 documents the first deposition of the terminal stafe of the recolonisation phase. The palynomorph assemblage is typical for inland sites of Western and Central Europe during the Eocene. However, various pollen of Myricaceae indicate that they were another common element of the vegetation. Pollen of Ulmaceae indicate their important role in the pioneer vegetation of the volcanic substrate during the recolonisation phase
• Bituminous shale with indistinct lamination, siderite laminae and sand.

Size class: microfossils

Preservation: original sporopollenin

Collection methods: core, chemical, mechanical, hydrochloric, hydroflouric

• Samples were crushed into small fragments and homogenised. A standard sample size of 4 g was used to minimise variations of reaction parameters such as sample surface area (Ellin and McLean 1994). Together with the sample material, 10 ml of 45% hydrofluoric acid (HF) were filled into a digestion vessel. Six vessels were used at the same time for digestion in the microwave system. The sealed vessels were treated by a standardised process with 15 minutes of heating at 110 °C using 1000-watt power and 45 minutes of cooling. Afterwards, the residue was mixed with 0.5 g of boric acid (H3BO3) to neutralise excess HF thereby improving safety for sample handling (Wilson et al. 2006). The residue in the vessels was then heated again for 5 minutes to 160° C by applying a power of 1000 watt. Following another cooling period of 45 minutes, the residues could be transferred into larger containers, which were filled with demineralised water and regularly decanted until neutralisation. After sieving through a 10 μm mesh screen, the residues were briefly oxidised by applying hydrogen peroxide (H2O2). Subsequently, the residues were sieved again, mixed with 5% potassium hydroxide (KOH) solution, and heated to 80 °C for 10 minutes in the MARS VI system. At the end of sample processing, the remaining residue was provided with a small amount of 35% hydrochloric acid (HCl) to solve remaining fluorides. After final sieving, the residues were transferred into crimp-top vials

•and 2 drops of 35% HCl were added to provide a slightly acidic environment that prevents fungal infestation.

•Slides and residues are housed at the Senckenberg Research Institute and Natural History Museum, Frankfurt am Main, Germany.

Primary reference: J. Mutzl, O. K. Lenz, V. Wilde, K. J. Krahn, M. Moshayedi and M. Hinderer. 2023. Vegetation dynamics in a disturbed lacustrine record: The Eocene maar lake of Groß-Zimmern (Hesse, Germany). Palaeobiodiversity and Palaeoenvironments 103:249-276 [P. Jardine/H. Morck]more details

Purpose of describing collection: paleoecologic analysis

PaleoDB collection 235251: authorized by Phillip Jardine, entered by Hannah Morck on 14.06.2024

Creative Commons license: CC BY (attribution)

Taxonomic list

• Palynomorphs, that could not be identified, were counted as 'Varia', which is similar to the other more or less coeval maar lake fillings of Messel (Lenz and Wilde 2018).
unclassified
  -
Polypodiopsida
  - Polypodiaceae
Algae
  - Botryococcaceae
Botryococcus spp. Kutzing 1849
  - Zygnemataceae
Ovoidites spp. Krutzsch 1959
Equisetopsida
 Cupressales - Pinidae
Monocolpopollenites
  -
Angiospermae
 Fagales - Juglandaceae
 Fagales - Betulaceae
Polyporopollenites spp. Thomson and Pflug 1953 birch
 Rosales - Ulmaceae
 Malpighiales - Euphorbiaceae
 Malvales - Tiliaceae
Dicotyledoneae
 Ericales - Ericaceae
Angiospermae
 Proteales - Proteaceae
 Proteales -
Plicatopollis
  -
Plicatopollis spp. Krutzsch 1962
Subtriporopollenites
  -
Tetracolporopollenites
  -
Tetracolporopollenites spp. Pflug and Thomson 1953