Material examined.—Treskelen, sample ZPAL Br. 12/Cr. 55, PMO 170.908A-D.

Remarks.—Varying parts of encrusting zoaria of Fistulipora-like bryozoans were observed in several thin sections. Morphological characters include short tubular autozooecia budding from substrate and bending at their bases towards the colony surface, slightly oval apertures with well developed lunaria, and small vesicles arranged usually in 2–3 rows between autozooecia. Due to insufficient material a more precise identification cannot be presented.

Type species: Coscinium cyclops Keyserling, 1846, Early Permian of Timan, Russia.

Material examined.—Measurements based on 10 zoaria in the following samples: Hyrnefjellet (scree), thin sections PMO 170.892A-B, as well as 11 thin sections from samples ZPAL Br. 12/H10, G16; Treskelen, sample ZPAL Br. 12/Cr. 55, thin section PMO 170.908B and one thin section ZPAL Br. 12/Cr. 55; Gipsvika, thin sections PMO 170.919A-G.

Description.—Bifoliate frondescent colonies with oval and circular fenestrules and anastomosing branches with zooecia opening on both sides of branches. The branches are lensshaped in cross section being bifoliate compressed perpendicular to branch surfaces. Width of branches varies between 2.86 and 3.00 mm, thickness 1.53–2.51 mm. The fenestrules are 2.00–2.81 mm long and 1.66–1.92 mm wide. Vesicular, blister-like tissue is developed between autozooecial tubes. Massive stereom is developed near colony surface. Apertures are ovate in outline being 0.22–0.23 mm long and 0.16–0.20 mm wide. The apertures carry a weakly developed lunarium. There are about 3.5–5 apertures along colony per 2 mm and 4.5–5 diagonally. Distance between apertural centers is about 0.40–0.55 mm.

Remarks.—The current material, as well as previously described material from Gipsvika (Nakrem 1994a) closely resemble the description and measurements of C. cyclops from the Asselian—Artinskian of Timan (Morozova and Kruchinina 1986). Coscinium hermidensis Ernst and Minwegen 2006, from the Late Carboniferous of Spain (Ernst and Minwegen 2006) differs from C. cyclops only in having slightly narrower fenestrules (0.9 mm wide) and may be a synonym of C. cyclops.

Measurements.—See Table 1.

Stratigraphic and geographic range.—First appearance in the late Asselian, more common in the Sakmarian—Artinskian of Timan-Pechora, Russia and Lower Permian the Urals (Morozova and Kruchinina 1986). Occurrence on Svalbard: Asselian—early Sakmarian, middle-upper part of the Tyrrellfjellet Member, and the Treskelodden Formation.

Material examined.—Hyrnefjellet, samples and three thin sections ZPAL Br. 12/H10, H30, H32, ; Treskelen, samples and three thin sections ZPAL Br. 12/Cr. 44, Cr. 45, Cr. 55.

Remarks.—Fragments of Goniocladia are only observed in oblique sections, and specific identification is not possible

Diagnosis (from Astrova 1978, translation by DA. Brown).—Zoaria laminar, unilamellar, sometimes bilamellar-symmetrical, tabulate, and branching. Zooecial orifices rounded-polygonal, circular or oval. Walls in the exozone weakly, and sometimes unevenly thickened, fused, with longitudinally-fibrous and obliquely-laminar microstructure. Diaphragms incomplete, less frequently complete. Exilazooecia numerous, their accumulation frequently forming maculae. Acanthozoocia uniform, commonly small, sometimes absent.

Etymology: The genus name is erected in honour of the Austrian palaeontologist Franz Toula ( 1845–1920), who conducted the first thorough investigation and description of fossil Bryozoa from Svalbard. Through the years 1873–1875 he published three papers on “PermoCarbon-Fossilien” from southern and western Spitsbergen, and he described many new species.

Type species: Toulapora svalbardense (Nakrem, 1994a) from the Asselian-early Sakmarian, middle-upper part of the Tyrrellfjeilet Member, Rejmyrefjellet, Spitsbergen.

Diagnosis.—Encrusting unilamellar zoaria. Zooecial walls evenly thickened, not beaded, at places crenulated. Autozooecial apertures oval, rounded, indented by a row of small acanthostyles. Diaphragms thin, usually absent, or extremely rare. Exilazooecia, without diaphragms, commonly distributed around each autozooecium. Acanthostyles of two sizes; sparcely distributed large ones, and a row of regularly distributed small ones inflecting each zooecial aperture; both types with a clear central calcitic rod. Zooecial walls laminated.

Comparison.—Toulapora is superficially similar to Hinaclema Sakagami and Sugimura, 1987 first described from the Early Carboniferous (Viséan) of Japan, subsequently reported from the Viséan of Uzbekistan (Schastlivtseva 1991) and the Tournaisian of Mongolia (Gorjunova 1996). Diagnostic characters of Hinaclema include lamellar or multilamellar encrusting zoarium with hollow axial area, thin endozone and absence of diaphragms in auto- and exilazooecial tubes, (large) acanthostyles of one size present (Sakagami and Sugimura 1987). Sakagami and Sugimura (1987) also mention “Other very small ‘acanthoecia’ (micropore?) … nearly not observable” in the type species Hinaclema hinaensis Sakagami and Sugimura, 1987, but these are not visible in their illustrations, and if present are clearly different from the row of small acanthostyles bordering each aperture in Toulapora.

Remarks.—Toulapora is tentatively placed in family Crustoporidae Dunaeva and Morozova, 1967, as suggested for Hinaclema by Schastlivtseva (1991), but contrary to the original placement of Hinaclema in family Heterotrypidae Ulrich, 1890 by Sakagami and Sugimura (1987). Toulapora deviates from the diagnosis of Crustoporidae in having both large and small acanthostyles and in the scarcity of zooecial diaphragms.

It can be added that Gorjunova (1996) in a revision of Hinaclema placed that genus within the order Cystoporida, suborder Ceramoporina. In the same publication she also pointed out that the Svalbard material published as Hinaclema svalbardensis Nakrem, 1994a should not be placed within genus Hinaclema.

Stratigraphic and geographic range.—Lower Permian of central Spitsbergen (Svalbard): Tyrrellfjellet Member (Wordiekammen Formation) of Sakmarian age, and upper part of the Gipshuken Formation of late Artinskian age.

1994a Hinaclema svalbardensis sp. nov.; Nakrem 1994a: 65–66, figs. 8D–H, 9.

1994b ?Hinaclema sp.; Nakrem 1994b: fig. 2d.

Type material: Holotype REF-4–15.0m, PMO A42600/1 (petrographic thin section); paratypes REF-4–15.0m, PMO 138.126 (rock specimen) and PMO A42600/2-4 (petrographie thin sections) all from the Rejmyrefjellet locality; thin sections PMO 170.941 and 170.942 from the Gipsvika (Sakmarian) locality.

Type locality: Rejmyrefjeilet, Spitsbergen.

Type horizon: Gipshuken Formation, 15 m below the top of the formation, late Artinskian.

Material examined.—Measurements based on 9 zoaria in the following samples: Gipsvika (Sakmarian), thin sections PMO 170.929,170.941,170.942; Rejmyrefjellet (Artinskian), 15 m below top of the Gipshuken Formation, thin sections PMO A42600/1-4, 138.126. Oblique zoaria in a sample from the Tyrrellfjellet Member at Rejmyrefjellet were not measured (thin section 138.124).

Diagnosis.—As for genus.

Description (emended from Nakrem 1994a).—Zoarium encrusting, encrusting layer 0.44–0.80 mm in thickness. The endozone is indistinguishable from the exozone. The autozooecia meet zoarial surface at about 90° in longitudinal section (exozonal part); proximal (endozonal) portion of zooecia sometimes are oriented parallel to zoarial growth direction. Rare diaphragms observed in autozooecia, not in exilazooecial tubes. Zooecial walls are evenly thickened, not beaded, but at places crenulated; a dark central zone is visible in deep tangential section. The zooecial apertures are oval, 0.17–0.24 mm long and 0.13–0.17 mm wide. Distance between centers of adjacent apertures usually 0.24–0.30 mm in all directions. Abundant exilazooecia, average 0.038 mm long and 0.033 mm wide are developed between autozooecia. 12–16 small acanthostyles, average 0.014 mm in diameter are developed around each autozooecial aperture. Scattered larger acanthostyles average 0.075 mm in diameter; but up to 0.10 mm in shallowest section, are also developed, 0–3 per autozooecial aperture.

Measurements.—See Table 2.

Stratigraphic and geographic range.—Sakmarian—late Artinskian, upper part of the Tyrrellfjellet Member of the Gipsvika section, and the upper part of the Gipshuken Formation of the Rejmyrefjellet section.

Type species: Cellepora urii Fleming, 1828, Early Carboniferous of Scotland.

Material examined.—Hyrnefjellet, sample ZPAL 12/H8, thin section PMO 170.950A; Treskelen, sample ZPAL Br. 12/Cr. 55, thin sections PMO 170.908A-D.

Remarks.—The identification is based on one fairly large zoarium displaying irregular branching growth with a colony diameter <10 mm. The exozone is very narrow, 0.40–0.57 mm wide. There is constantly one (rarely two) perforated diaphragm in the inner exozone. Both large and small acanthostyles are present. Measurements resemble those presented for Tabulipora ellesmerensis Sakagami, 1998, described from the Lower Permian of Ellesmere Island (Arctic Canada).

Type species: Rhombotrypella astragaloides Nikiforova, 1933, Middle Carboniferous of the Donetz Basin, Ukraine.

Material examined.—Treskelen, sample and one thin section ZPAL Br. 12/Cr. 34.

Remarks.—Only a single oblique cross section of a Rhombotrypella colony was observed being 1.7 mm in diameter with an exozone width of 0.28 mm and an endozone 1.10 mm in diameter. Zooecial apertures may be estimated from the oblique section to be about 0.20 × 0.14 mm. Square zooecial tubes in the endozone number 2–2.5 per 1 mm. These insufficient observations cannot provide a species identification, but the measurements are closest to Rhombotrypella arbuscula (Eichwald, 1860) known from the Artinskian—Kungurian of Timan-Pechora (Russia) (Morozova and Kruchinina 1986) and the Kungurian Vøringen Member (Kapp Starostin Formation) of Spitsbergen (Nakrem 1995).

Type species: Dyscritella robusta Girty, 1911, Early Carboniferous (Mississippian, Chester) of Arkansas, North America.

Material examined.—Treskelen, sample and one thin section ZPAL Br. 12/Cr. 45, Hyrnefjellet, sample and one thin section ZPAL Br. 12/H20.

Remarks.—Fragmented zoaria with oval apertures 0.21 × 0.18 mm with an irregular outline due to bordering acanthostyles. Exilazooecia are commonly developed between autozooecia. Acanthostyles of only one size, 0.043–0.057 mm in diameter. Diaphragms not observed.

Type species: Rhabdomeson progracile Wyse Jackson and Bancroft, 1995, Lower Carboniferous, England.

Material examined.—Gipsvika, thin section PMO 170.911A. See also occurrences listed in Nakrem (1994a: 72).

Remarks.—Specimens of Rhabdomeson were encountered in some randomly oriented sections, and identified due to the characteristic hollow central canal. Zoaria about 0.65 mm in diameter; hollow canal about 0.40 mm in diameter. Lack of properly oriented sections has prevented identification to species level.

Material examined.—Treskelen, sample and two thin sections ZPAL Br. 12/Cr. 46.

Remarks.—Oblique sections through an endozonal fragment is tentatively placed in the genus Rhabdomeson. The genus identification is based on the regular development of zooecia, and the possible presence of a central hollow canal in a zoarium being about 1 mm in diameter.

Type species: Ceriopora nodosa Fischer von Waldheim, 1837, Carboniferous, Russia, by subsequent designation (ICZN 1994, Wyse Jackson 1993).

Remarks.—Kruchinina (1980) erected the genus Ascoporella with Geintzella borealis Stuckenberg, 1895, from the Sakmarian of Belaya River, Timan, Russia as type species. Ascoporella is incorrectly described as a new genus in Morozova and Kruchinina (1986: 65), and Ascopora grandis Kruchinina, 1973 is erroneously assigned as type species. In the original description of Ascoporella by Kruchinina in 1980, and the repeated description by Morozova and Kruchinina in 1986 Ascoporella is distinguished from Ascopora in having thicker branches, a wider bundle of parallel zooecial in the endozone and often unevenly thickened or beaded exozonal zooecial walls. The number of parallel zooecial in the central bundle ranges from 15 to 30 as observed in longitudinal thin sections. It is difficult to accept these characters as being diagnostic for Ascoporella as the illustrated specimens in Kruchinina (1980) and Morozova and Kruchinina in (1986) deviate strongly from the definitions. In these publications the following can be observed from the illustrations: Ascoporella grandis (Kruchinina, 1973) has 10–13 parallel zooecial in the central bundle and the walls are not beaded. Ascopora borealis (Stuckenberg, 1895) has indeed beaded walls, 13–15 parallel zooecial in the central bundle, but a zoarium diameter of 13–18 mm (measured from the original material in Nikiforova 1938: pl. III, VI) instead of 30–40 mm as given by Morozova and Kruchinina (1986). Ascoporella enormis Kruchinina, 1980 is the only species that fulfills the diagnostic characters being 40–45 mm in diameter, having 20–22 parallel zooecial in the central bundle and having thickened or beaded exozonal zooecial walls.

Material examined.—Measurements based on 5 zoaria in the following samples: Hyrnefjellet, sample ZPAL Br. 12/H10, thin section PMO 170.906; sample and two thin sections ZPAL Br. 12/H30; Gipsvika, thin sections PMO 170.911A, 170.932B, C.

Description.—Cylindrical dichotomically branching colonies averaging 2 mm in diameter. Exozone 0.52 mm wide. Axial bundle of parallel zooecia about 0.52 mm in diameter with 4 to 5 parallel zooecial tubes as observed from longitudinal sections. One distinct proximal hemiseptum is present in zooecial tubes in the transition between the exozone and the endozone. Apertures elongated oval, about 0.28 mm long and 0.12–0.13 mm wide. There are 3.5–4 apertures per 2 mm along colony and 6.3–7.1 diagonally. Distance between apertures longitudinally average 0.53 mm. Large acanthostyles 0.10–0.14 mm in diameter, stylets are present in ridges between apertural rows. Zooecial wall in exozone is about 0.10–0.12 mm in thickness; endozonal wall about 0.006–0.010 mm.

Measurements.—See Table 3.

Stratigraphic and geographic range.—Occurrence on Svalbard: Asselian, middle part of the Tyrrellfjellet Member, and the Treskelodden Formation. Gzhelian of the Urals, Russia (Shul'ga-Nesterenko 1955).

Material examined.—Measurements based on 9 zoaria in the following samples: Treskelen, sample and one thin section ZPAL Br. 12/Cr. 55; Hyrnefjellet, samples ZPAL Br. 12/H4 (thin section PMO 170.893A), ZPAL Br. 12/H8 (thin section PMO 170.904B), ZPAL Br. 12/H1 1 (thin section PMO 170.896); Gipsvika, thin sections PMO 170.911D, 170.911E, 170.914, 170.928, 170.945.

Description.—Ascopora with cylindrical bifurcating branches of varying diameter (2.25–4.75 mm). Exozone about 0.40– 1.20 mm wide, axial bundle of parallel zooecial tubes 0.75–1.00 mm in diameter containing 6–7 parallel tubes as observed in longitudinal sections. Two proximal hemisepta are usually present in zooecial tubes in exozone. Apertures elongated oval, sometimes slit-like, 0.26–0.32 mm long and 0.09–0.15 mm wide. The apertures are arranged in rows with ridges between; 3.1–4.5 per 2 mm along colony and 5.9–6.7 diagonally. Distance between apertural centers longitudinally average 0.50 mm. Two large acanthostyles are present adjacent to each aperture. A row of stylets, as observed in shallow tangential section, is present on the ridges between apertural rows. Zooecial wall in exozone is 0.13–0.14 mm in thickness; endozonal wall about 0.010 mm.

Remarks.—Nikiforovas original material was re-investigated by Morozova and Kruchinina (1986) and the identification herein is mainly based on their revision. Accordingly, A. sterlitamakensis is distinguished from A. magniseptata in having larger and more spaced apertures, a wider axial bundle of parallel zooecia, and also acanthostyles of greater diameter.

One 20 mm long specimen was identified with growth basis preserved, but no visible hard substrate (Fig. 6K). A possible hard substrate may have been dissolved or lost otherwise, or more likely, this specimen grew in a soft bottom sediment. This unusual preservation indicates deposition in calm lowenergy waters.

Measurements.—See Table 4.

Stratigraphic and geographic range.—Occurrence on Svalbard: Asselian, middle part of the Tyrrellfjellet Member, and the Treskelodden Formation. Sakmarian of Timan-Pechora and the Urals, Russia (Morozova and Kruchinina 1986).

Material examined.—Five partial zoaria in the following samples: Hyrnefjellet, samples ZPAL Br. 12/G14 (thin sections PMO 170.895A-C), ZPAL Br. 12/G15 (thin section PMO 170.891), and sample and one thin section ZPAL Br. 12/G14. For measurements, see Table 5.

Ascopora cf. sterlitamakensis is distinguished in displaying multiple regenerated growth layers, with an exozone up to 3.3 mm wide, but in many other charcters similar to A. sterlitamakensis. This growth pattern is very much like the description of Tabulipora borealis (Stuckenberg, 1895) by Nikiforova (1938: 221–222, p1. 4: 1, 2), subsequently re-assigned as Ascoporella borealis by Morozova and Kruchinina (1986). Some specimens have an unusually widened exozone, up to 5.25 mm wide with no signs of overgrowth. Circular cavities/openings, up 0.17–0.20 mm in diameter, are observed in the exozone of these colonies with extraordinary exozone. These holes are herein interpreted as being the results of bioerosion by unknown parasites drilling into the calcitic exozone of the bryozoan zoaria (Fig. 6L). Some cavities are later filled in with sediments and skeletal debris, e.g., coral and echinoderm fragments (Fig. 6N).

Material examined.—Measurements based on 12 zoaria (including material from Nakrem 1994a) in the following samples: Gipsvika, thin sections PMO 170.933, 170.936. See also occurrences listed in Nakrem (1994a: 80).

Description.—Zoarium ramose with thick branches averaging 6.8 mm in diameter. Exozone average 1.08 mm wide; endozone average 4.11 mm in diameter. Axial bundle diameter 1.75–2.35 mm. The axial bundle comprises 9–10 parallel zooecial tubes as viewed in longitudinal section. Zooecial apertures elongated, 0.26–0.36 mm long and 0.12–0.16 mm wide. There are 3.3–3.8 zooecial apertures in 2 mm along colony; 5.6–6.7 diagonally. There are 2–3 hemisepta present in exozonal zooecial tubes (Fig. 8J). One large acanthostyle is developed in the area between zooecial apertures protruding above colony surface (Fig. 8E); diameter 0.08–0.13 mm. Small, infrequent pores are also present in exozonal walls. Exozonal walls are generally 0.11–0.12 mm thick as measured between adjacent apertures in tangential section. Endozonal walls are 0.11–0.12 mm thick.

Remarks.—The described specimens compare well with the illustrations and descriptions given by Kruchinina (1973) and Morozova and Kruchinina (1986) in branch diameter and number of parallel zooecia in the central bundle, but the Spitsbergen material has a significantly narrower axial bundle diameter. It should be remarked that the axial bundle was described as containing 15–22 parallel zooecial tubes, but the illustrations given (Kruchinina 1973: pl. 28: 1c, identical to Morozova and Kruchinina 1986: pl. 22: 1c) display a maximum of 11 parallel zooecia. The number of parallel zooecial tubes counted from these illustrations is actually lower than the minimum figure given in the generic diagnosis of their genus Ascoporella and we have chosen to place this species in Ascopora.

Comparison.—A. grandis is distinguished from A. borealis (Stuckenberg, 1895) and A. enormis Kruchinina, 1986 (both Artinskian species from Timan) in having smaller branch diameter, and fewer parallel zooecia in the axial bundle. A. grandis is distinguished from all other species in the current study in its wide axial bundle and number of parallel zooecia in the axial bundle.

Measurements.—See Table 6.

Stratigraphic and geographic range.—Occurrence on Svalbard: Late Asselian, middle part of the Tyrrellfjellet Member. Sakmarian (Ilibei Horizon) of Timan-Pechora, Russia (Morozova and Kruchinina 1986).

1994a? Ascoporella sp. A; Nakrem 1994a: 80, figs. 13C, 17A–C.

Etymology: The species name is in honour of Professor Krzysztof Birkenmajer (Institute of Geological Sciences of the Polish Academy of Sciences, Kraków) in recognition of his scientific achievements in the geology of Svalbard.

Type material: Holotype PMO 170.913, paratype PMO 170.913.

Type locality: Gipsvika, Spitsbergen, Svalbard.

Type horizon: Wordiekammen Formation, Tyrrellfjellet Member. Permian, Cis-Uralian, late Asselian—early Sakmarian.

Material examined.—Measurements based on 15 zoaria in the following samples: Hyrnefjellet, sample ZPAL Br. 12/G15 (thin section PMO 170.899), sample ZPAL Br. 12/H7 (thin sections PMO 170.903A-G), sample ZPAL Br. 12/H8 (thin section PMO 170.949); Gipsvika, thin sections PMO 170.9111B, 170.911C, 170.911F, 170.912, 170.913.

Diagnosis.—Robust zoaria with a wide endozone and axial bundle, up to 8 parallel zooecia in the axial bundle.

Description.—Robust branching species of Ascopora with branch diameter verying between 3.75 and 7.00 mm. Exozone width varies between 0.80 and 1.75 mm. There are usually 2 hemisepta present in exozonal zooecial tubes.Variation in branch diameter and exozone width is generally caused by several growth generations. Endozone average 2.50 mm, with an axial bundle varying between 0.75 and 1.25 mm. There are 5 to 8 parallel zooecia in the axial bundle as viewed in parallel section. Zooecial apertures are elongated being 0.24–0.30 mm long and 0.10–0.14 mm wide. Distance between aperture centers along colony is 0.40–0.60 mm and 0.30–0.40 diagonally. There are 3.3 to 5 apertures along colony per 2 mm and 5 to 6.7 diagonally. Acanthostyles are sometimes up to 0.15–0.16 mm in diameter, averaging 0.11 mm. Stylets, 0.02–0.04 mm in diameter, are developed in the walls between apertures (Fig. 7H).

Comparison.—A. birkenmajeri is distinguished from all other species in the current study by the diameter of the axial bundle and the number of parallel zooecia in the axial bundle. The endozone shows great variation in diameter, but is on average narrower than the one in A. grandis, and wider than the endozones of the other species described in the current study.

Remarks.—Several growth generations can be observed in many zoaria (170.903A-G). Locally the exozone is developed as solid stereom without apertures, or very small (“dwarfed”) or closed off apertures.

Measurements.—See Table 7.

Stratigraphic and geographic range.—Occurrence on Svalbard: Asselian, middle part of the Tyrrellfjellet Member, Gipsvika, and the Treskelodden Formation, Hyrnefjellet.

Type species: Rhombopora lepidodendroides Meek, 1872 Late Carboniferous, Nebraska, USA.

Material examined.—Treskelen, sample and two thin sections ZPAL Br. 12/Cr. 44; Hyrnefjellet, samples and two thin sections ZPAL Br. 12/H10 and H34; Gipsvika, thin section PMO 170.911B.

Remarks.—Fragments of Rhombopora occur in many thin sections, but reliable orientations are lacking and rather few measurements could be made. Colonies have diameters ranging between 0.88 and 1.07 mm and exozones widths 0.28 and 0.30 mm. Zooecia in endozone observed in transverse section have a rather square outline. The most similar species is Rhombopora optima Gorjunova, 1975, from the Artinskian of Pamir, but better material is required for a more conclusive identification.

Type species: Coscinium dichotomum Stuckenberg, 1895, Early Permian of Timan, Russia.

Material examined.—Treskelen, sample and one thin section ZPAL Br. 12/Cr. 64; Hyrnefjellet, sample and two thin sections ZPAL Br. 12/H10.

Remarks.—Fragments of Timanodictya colonies are observed in oblique orientations. The genus identification is based on the presence of a median lamina and the abundant small microstylets in the extrazooidal skeleton. Branch width is about 1 mm with slightly oval zooecial apertures 0.12 × 0.13 mm. Aperture center distance is about 0.29–0.31 mm along colony, 0.35–0.36 mm diagonally. These measurements are not sufficient for specific identifications.

Type species: Fenestella praevirgosa Shul'ga-Nesterenko, 1951, Gzhelian of the East European Platform, Russia.

Material examined.—Gipsvika, thin section PMO 170.935.

Description.—Fabifenestella with relatively small fenestrules and robust branches and dissepiments as compared with other species of this genus. There are 14–19 branches per 10 mm across colony and 14–15 dissepiments per 10 mm along colony. Branches 0.28–0.31 mm wide carrying scattered nodes (0.10 mm × 0.03 mm). Dissepiments 0.13–0.15 mm wide. Fenestrules 0.50–0.56 mm long and 0.26–0.32 mm wide. Apertures circular 0.10–0.11 mm in diameter. There are 17–19 apertures per 5 mm along branch; 2–2.5 bordering each fenestrule. Distance between apertural centers 0.26–0.30 mm along branch. Zooecial chambers fabiform in shallow tangential section; elongated-pentagonal in median to deep section. F. quadratopora occurs in the Sakmarian of the Russian Platfdorm, Russia (Shul'ga Nesterenko 1936).

Measurements.—See Table 8.

Type species: Fenestella medvedkensis Shul'ga-Nesterenko, 1951, Kasimovian of the East European Platform, Russia.

Material examined.—Gipsvika, thin section PMO 170.943, 170.915B.

Description.—Rectifenestella with minute meshwork and narrow branches and dissepiments. There are 20–22 branches per 10 mm across colony and 18–20 dissepiments per 10 mm along colony. Branches 0.24–0.30 mm wide carrying 4–5 nodes (0.05 mm × 0.10 mm) per 1 mm. Distance between node centers 0.18–0.26 mm. Dissepiments 0.12–0.18 mm wide. Fenestrules 0.38–0.44 mm long and 0.18–0.24 mm wide. Apertures circular 0.10–0.12 mm in diameter or slightly oval measuring 0.10 mm × 0.12 mm. There are 18–22 apertures per 5 mm along branch; 2–2.5 bordering each fenestrule. Distance between apertural centers 0.22–0.28 mm along branch. Zooecial chambers fabiform in shallow tangential section; pentagonal in median to deep section.

Measurements.—See Table 9.

Stratigraphic and geographic range.—Occurrence on Svalbard: Asselian, middle part of the Tyrrellfjellet Member. Sakmarian—Artinskian of the Russian Platform, Russia (Morozova and Kruchinina 1986); Lower Permian of China (Yang and Lu 1983).

Material examined.—Treskelen, sample and one thin section ZPAL Br. 12/Cr. 34; Gipsvika, thin sections PMO 170.915A and B, 170.938B. See also occurrences listed in Nakrem (1994a: 93).

Description.—Delicate meshwork with 21–28 fenestrules along colony and 25–29 branches across colony per 10 mm. Branches about 0.21 mm thick and 0.23 mm wide with a straight low carina carrying 5–6 nodes per 1 mm. Nodes are about 0.05 mm long and 0.03 mm wide being 0.16–0.21 mm apart. Dissepiments 0.07–0.12 mm wide. Fenestrules 0.26–0.34 mm long and 0.12–0.20 mm wide. Apertures circular in outline, 0.06–0.09 mm in diameter. There are usually 25–27 apertures per 5 mm along branch. Distance between apertural centers along colony 0.17–0.22 mm; 2 or 2.5 apertures border each fenestrule. Zooecial chambers are pentagonal in outline in median tangential section.

Remarks.—R. submicroporata is distinguished from R. microporata by smaller apertures (0.06–0.09 vs. 0.07 mm in diameter) and narrower and more closely spaced branches and dissepiments. A fragmentary specimen assigned as Rectifenestella cf. submicroporata (Shul’ga-Nesterenko 1952) (one ZPAL thin section from Hyrnefjellet) is separated by having more robust branches and dissepiments and the following measurements: 23–25 branches per 10 mm, width of branch 0.28–0.30 mm, width of dissepiments 0.25–0.26 mm.

Measurements.—See Table 10.

Stratigraphic and geographic range.—Occurrence on Svalbard: Late Asselian—early Sakmarian, middle and upper part of the Tyrrellfjellet Member, and late Artinskian-early Kungurian, Vøringen Member of the Kapp Starostin Formation. Asselian of the Urals, Russia (Shul’ga-Nesterenko 1952).

Type species: Fenestella wortheni Hall, 1857, Mississippian (Warsaw) of Illinois, USA.

Material examined.—Treskelen, sample and one thin section ZPAL Br. 12/Cr. 45, Gipsvika, thin section PMO 170.929.

Remarks.—The current material of Archimedes is distinguished from other fenestellids by the growth shape of the zoarium. Zooecial measurements are insufficient for a detailed description. Czarniecki (1964) described Archimedes aff. magnus Condra and Elias, 1944 from coral horizon IV, Treskelen, but it is not possible to tell whether the current specimens can be attributed to the same taxon. Czarniecki (1964) did not provide zooecial observations, and it is not possible to revise his identification. Nakrem (1994a: 98— 100) described other occurrences of Archimedes from the Upper Carboniferous of the inner Isfjorden area, not considered to be con-specific with the material from Treskelen.

Type species: Retepora pluma Phillips, 1836, Early Carboniferous of Yorkshire, England.

Material examined.—Hyrnefjellet, sample and one thin section ZPAL Br. 12/H10.

Remarks.—Main branch 0.71 mm wide, secondary branches 0.61 mm wide. Zooecial apertures oval, 0.12–0.13 × 0.15– 0.16 mm. Distance between aperture centers along main branch is 0.37–0.39 mm equaling 12.8–13.5 per 5 mm. Zooecial chamber is elongated parallelogram shaped, no internal septa are observed. Nodes are present along main branch, 0.25–0.26 mm apart. Material and measurements are not sufficient to establish a conclusive specific identification, but the most similar species is Penniretepora disposita (Trizna, 1939) known from the Sakmarian—Artinskian of Bashkiria, Russia (Trizna 1939).

Material examined.—Treskelen, sample and one thin section ZPAL Br. 12/Cr. 44.

Description.—Main branch 0.26 mm wide. 13–14 secondary branches (0.24 mm wide) per 10 mm. 20–21 zooecial apertures per 5 mm on both main and secondary branches. Circular zooecial aperture with a diameter of 0.07–0.08 mm.

Remarks.—The investigated material is too rare to establish a specific identification. The dimensions are most similar to different Carboniferous species, e.g., some species described by Shishova (1959).

Type species: Polypora helenae Shul'ga-Nesterenko, 1951, Moscovian of the East European Platform, Russia.

Material examined.—Gipsvika, thin section PMO 170.916, acetate peel 170.944.

Description.—Shulgapora with large, elongated fenestrules and slender branches producing a relatively open meshwork. There are 4–5 branches per 10 mm across colony and most commonly 4.5–5 fenestrules per 10 mm along colony. Branches bearing 5–6 rows of apertures are 1.25–1.50 mm wide. Branch surfaces are pierced by numerous small stylets. Dissepiments are 0.50–0.75 mm wide. Fenestrules are 1.15–1.80 mm long and 0.75–1.15 mm wide. Apertures are distinctly ovate, measuring 0.20–0.22 × 0.15–0.16 mm. There are 5–6 apertures per fenestrule. Distance between apertural centres is 0.34–0.42 along branch. Autozooecial chambers are rhomboid or less commonly hexagonal in median to deep tangential section.

Cyclozooecia (heterozooecia) up to 0.16 mm in diameter as measured deeper into the zooarium with an aperture diameter of 0.10 mm; these open on reverse side on branch. Cyclozooecia are locally also developed on obverse side of branches. S. porosa occurs in Sakmarian—Artinskian of Timan-Pechora (Morozova and Kruchinina 1986).

Measurements.—See Table 11.

Type species: Polypora dendroides M’Coy, 1844, Viséan of Ireland.

Material examined.—Treskelen, samples and two thin sections ZPAL Br. 12/Cr. 45 and Cr. 46; Hyrnefjellet, samples and three thin sections ZPAL Br. 12/H8, H10, H20; Gipsvika, thin sections PMO 170.916, 170.927,170.944, 170.947.

Remarks.—Fragments of Polypora, too small for measurements or identification are observed in most samples. The genus identification is based mainly on cross-sections where more than two rows of zooecia are developed.