Type species.—Acrotreta primaea Walcott, 1902, from the lower to middle Cambrian Pioche Shale, Nevada, USA.

1902 Acrotreta primaea Walcott, p. 593.

1912 Acrotreta primaea; Walcott, p. 700, pl. 69, figs. la–f.

1966 Hadrotreta primaea; Rowell, p. 13, pl. 1, figs. 1–12.

1980 Hadrotreta primaea; Rowell, p. 7, pl. 4, figs. 8–12, pl. 5, figs. 1–10, pl. 6, figs. 1–9.

1990 Hadrotreta primaea; Roberts and Jell, figs. 22–24, table 3.

2007 Hadrotreta primaea; Holmer and Popov, p. 113, fig. 57.1a–f.

Hypotype.—A dorsal valve (UCR 7312/1), Cadiz Formation, California, USA (Fig. 2.1, 2.2).

Description.—Dorsal valve subcircular in outline, of 6.89 mm width, 5.82 mm length (Fig. 2.1, 2.2). Shell gently convex, most strongly convex posteromedially, becoming gradually flattened anteriorly, with maximum width at midlength (Fig. 2.1, 2.2). Dorsal pseudointerarea small, occupying ∼27% of total valve width, with faint median groove and propareas (Fig. 2.3). Dorsal median buttress strongly developed, extending 33% of valve length; strongly developed ridge-like median septum originating at approximate distal end of median buttress, extending ∼67% of total valve length; terminal portion of median septum forming subtriangular platform-like swelling (Fig. 2.1–2.3, double-tailed arrows). Elongate impressions of anterocentral muscle scars on lateral edge of median septum (Fig. 2.2, 2.3, arrows). Cardinal muscle scars weakly impressed, extending anterolaterally from lateral edge of median groove, occupying 20% of total length, 46% of valve width (Fig. 2.2, doubled-headed arrow). Epithelial cell molds on different shell layers, ∼7.22–12.57 µm in diameter (Fig. 2.4, 2.5).

Materials.—One dorsal valve (UCR 7312/1) recovered from the Cadiz Formation. Three dorsal valves (ELI SMS 1, 3, 5) and three ventral valves (ELI SMS 8, 9, 10) collected from the basal Emigrant Formation, Split Mountain, Nevada.

Remarks.—After the genus Acrotreta was erected by Kutorga in 1848, the type material of the type species Acrotreta subconica Kutorga, 1848 was lost and there was a lack of detailed information concerning interior characters, type locality, and type horizon. As a result, the genus was subsequently used worldwide as a ‘waste basket’ for almost any conical acrotretides from the Cambrian-Ordovician. Holmer and Popov (1994) revised the type species and related lingulate brachiopods and suggested that Acrotreta is restricted to the Ordovician, because none of the numerous Cambrian records of the genus (see, e.g., Walcott, 1912) can be retained within the taxon. Rowell (1966) erected the genus Hadrotreta as monotypic; its diagnosis and description were based on the etched topotype material of Acrotreta primaea.

Hadrotreta primaea has been described from the Pioche Shale of Nevada (Rowell, 1980) and the Coonigan Formation of western New South Wales, Australia (Roberts and Jell, 1990). The etched material of Hadrotreta primaea from the basal Emigrant Formation (Fig. 2.6–2.11) highly resembles the shale-hosted material, whereas the former has better-developed anterocentral muscle scars (Fig. 2.6, 2.7, arrows), a platform-like swelling at the termination of the dorsal median septum (Fig. 2.6, 2.8, double-tailed arrows), a ventral intertrough (Fig. 2.9) and most importantly a moderately high cape-like ventral apical process (Fig. 2.10, tailed arrow). Specimens from the lower Cambrian of South Australia referred to Hadrotreta primaea by Brock & Cooper (1993) were later assigned to Vandalotreta djagoran (Kruse, 1990) by Holmer et al. (1996). In 2014, Percival and Kruse reassigned the material to Kostjubella Popov, Holmer, and Gorjansky, 1996. ?Hadrotreta primaea has been described from the Harkless Formation, southern Nevada (Skovsted and Holmer, 2006), although the lack of internal information for the ventral valve hampered its accurate affinity.

Hadrotreta primaea differs from Hadrotreta taconica (Walcott, 1887) from the Forteau Formation of southern Labrador and western Newfoundland by having a more-pronounced, boss-like anterior termination of dorsal median ridge, and shorter dorsal pseudointerarea (Skovsted et al., 2017). Hadrotreta primaea is similar to Hadrotreta timchristiorum Popov et al., 2015 from the Himalaya (Popov et al., 2015), although the latter has a narrower and shallower ventral intertrough. The epithelial cell molds are reminiscent of those in etched material in their overall impression and average diameter, but those from acid-etched carbonate material better preserve the hexagonal network (Fig. 2.11).

Type species.—Obolus labradoricus Billings, 1861 from the lower Cambrian of Labrador, Canada.

1884 Kutorgina prospectensis Walcott, p. 19, pl. 9, fig. 1, 1a, b.

1886 Kutorgina prospectensis; Walcott, p. 106, pl. 9, fig. 3, 3a.

1897 Iphidea prospectensis; Walcott, p. 234.

1905 Iphidella prospectensis; Walcott, p. 307.

1912 Micromitra (Paterina) prospectensis; Walcott, p. 352, pl. 2, fig. 4, 4a.

1980 Paterina prospectensis; Mount, fig. 2.

2020a Paterina prospectensis; Liang et al., fig. 1a, b, e, f.

Hypotype.—A dorsal valve (UCR 10/2006), lower Cambrian Latham Shale, California, USA (Fig. 3.3).

Description.—Shell ventribiconvex, subcircular in outline (Fig. 3.1–3.12). Shells relatively large, of 4.89–8.87 mm length, 5.99–11.2 mm width, with maximum width at midlength. Ventral valve convex, with apex at posterior part (Fig. 3.1–3.8). Ventral posterior margins oblique, well-illustrated in examined specimens (Fig. 3.1–3.8). Pseudointerarea and homeodeltidium poorly preserved. Dorsal valve less convex, with well-defined, nearly straight hinge line (Fig. 3.9–3.12). Dorsal valve larger than ventral valves in current collection. Shell interior not observed. External ornamentation on both valves consisting of regular, fine, concentric fila. Concentric growth lines spaced regularly (10–12 per mm; Fig. 3.13, 3.14), sometimes interrupted by nick points, forming sets of drapes (Fig. 3.4, 3.15).

Materials.—Four dorsal (UCR 7002/300, 10/3366, 7271/6, and 4079/10/1) and eight ventral valves (UCR 10/3381, 10/3354, 10/2006, 7002/298, 10/3362, 10/3351, 10/8/34, and 10/3369), including one complete conjoined shell (UCR 10/3369) and one dorsal valve with soft-part preservation (UCR 7002/300; Liang et al., 2020a), recovered from the lower Cambrian Latham Shale.

Remarks.—Paterina prospectensis was originally assigned to Kutorgina Billings, 1861 and Iphidea Billings, 1872 by Walcott, but he later transferred it to Micromitra Meek, 1873, based on its concentrically striated ornamentation. Later, it was known as Paterina prospectensis (see Mount, 1976, 1980; Gaines and Droser, 2002). The specimens studied here show distinct ornamentation of concentric growth fila and are markedly different from the surface ornamentation of Micromitra (Williams et al., 1998). Another prominent difference between Paterina and Micromitra is that the former has an open delthyrium whereas the latter has a homeodeltidium (Laurie, 2000). Both genera belong within the class Paterinata, in which Paterina has a slightly earlier first appearance datum (FAD) and became extinct in the late Ordovician (Williams et al., 1998).

The most comparable well-known species is Paterina zenobia Walcott, 1924, which is only known from the Burgess Shale (e.g., Topper et al., 2015). Both P. prospectensis and P. zenobia share a similar subcircular outline with a straight hinge line, although P. zenobia generally attains a larger size, reaching a maximum of 15 mm width and 14 mm length (Topper et al., 2015). The two species are also similar in the way they preserve the long marginal setae fringing the shell valve. Topper et al. (2015) suggested that the sessile life strategy of P. zenobia might have included mimicry; the occurrence of P. prospectensis might suggest that this had already developed by Stage 4 (Liang et al., 2020a). The poorly preserved open delthyrium and internal structures of the flattened material of P. prospectensis preclude further comparison. Other occurrences in the early Cambrian of Laurentia are difficult to compare in detail to P. prospectensis. Paterina sp. indet. from the Forteau Formation of southern Labrador and western Newfoundland, Canada has been kept under open nomenclature without formal description (Skovsted et al., 2017). The ventral valves of P. mediocris Poulsen, 1932 from the Ella Island Formation, northeastern Greenland, share a similar overall morphology and general concentric fila with P. prospectensis, but the ventral valve of the latter is more convex and has a more oblique posterior margin (Skovsted and Holmer, 2005).

Paterina? suspiciosa Aksarina, 1975 from the Parahio Formation, Tethyan Himalaya, shows concentric ornament typical for Paterina, but also retains a homeodeltidium, which is otherwise absent in other species of the genus characterized by an open delthyrium. Paterina sp. indet. from the same formation is more subrectangular in outline, but the lack of a ventral valve impedes further comparison (Popov et al., 2015). Paterina has also been reported from England, USA, France, and Spain (Termier and Termier, 1974; Laurie, 1987, 2000; Liñán and Mergl, 1982), however, the lack of internal musculature and vascular systems for the material of P. prospectensis prohibits further detailed comparison.

Type species.—Trematis pannulus White, 1874 from the lower to middle Cambrian Pioche Shale, Nevada, USA.

1874 Trematis pannulus White, p. 6.

1912 Micromitra (Iphidella) pannula; Walcott, p. 361.

1942 Dictyonina pannula; Cooper, p. 228.

1976 Dictyonina pannula; Mount, fig. 28.

Holotype.—A dorsal valve (USNM 15331a), lower to middle Cambrian Pioche Shale, Nevada, USA (Rowell, 1980).

Description.—Shell semicircular to rounded rectangular, unequally biconvex, slightly flattened or compressed, but somewhat profiled laterally (Fig. 4.1–4.4). Ventral valve ovate to subquadrate, small, of 1.2 mm length, 1.9 mm width (Fig. 4.1, 4.2). Umbo bearing a prominent metamorphic shell, ∼600 µm in diameter (Fig. 4.1, 4.2). Dorsal valve gently convex at umbo, flattened laterally and anteriorly, with nearly straight posterior margin (Fig. 4.3, 4.4). Dorsal valve relatively large, of 5.56 mm length, 7.75 mm width (Fig. 4.3, 4.4). Ornament of fine radiating rows of subhexagonal pits arising near umbo, increasing in size moderately by intercalation anteriorly; 8–10 concentric growth bands recognizable, alternatingly widening toward marginal edge (Fig. 4.3, 4.4). Diameter of pits 20–50 µm (Fig. 4.5–4.7). Ventral and dorsal interior not observed.

Materials.—One ventral (UCR 7073/1) and one dorsal valve (UCR 9925/9) recovered from the Cadiz Formation.

Remarks.—Dictyonina pannula is the type species of the genus. The holotype is a poorly preserved dorsal valve (USNM 15331a) that retains a small part of the original shell typified by the characteristic pitted ornament. The precise stratigraphic level from which the holotype came is unknown. It was collected in the Pioche District and previous studies show that only one species of Dictyonina occurs in the lower and middle Cambrian rocks of that area (Rowell, 1980).

Species of the Cambrian paterinate brachiopod Dictyonina from the lower to upper Cambrian are characterized by fine radiating rows of subhexagonal pits increasing in size distally (Laurie, 2000). This pitted ornament also represents a significant character in the younger, related genus Dictyonites from the Lower–Upper Ordovician, but Dictyonites has a more deeply pitted and perforated shell and pits increasing significantly in size distally (Laurie, 2000). The oldest known mickwitziid brachiopod Kerberellus marcouensis Devaere, Holmer, and Clausen in Devaere et al., 2015 was previously described as Dictyonina? sp. indet. due to its ornamentation with radiating rows of subhexagonal pits. However, the latest revision of the problematic Kerberellus marcouensis suggested that the two species only share superficial similarities; Kerberellus marcouensis is characterized by large, radially ovoid, hourglass-shaped extensions that are interpreted as tubes (canals) running through a thick shell, the most significant character of the mickwitziid brachiopods, whereas the fine radiating rows in Dictyonina correspond to subhexagonal pits in the organophosphatic shell (Devaere et al., 2015).

Dictyonina hexagona (Bell, 1941) from the middle Cambrian of Montana, has hexagonal external pits, but these are much finer and the ventral valve has a more prominent umbo extending well behind the hinge line of the valves. Specimens of D. hexagona illustrated by Koneva (1986) from the middle Cambrian of southern Kazakhstan have a less-prominent ventral umbo and coarser pitted ornament than the American material and are morphologically closer to D. pannula. Dictyonina australis Roberts and Jell, 1990 from the Coonigan Formation, western New South Wales resembles D. pannula but has a less-defined umbo, coarser diamond-shaped pits, and prominent radial ribs (Roberts and Jell, 1990).

The pitted ornament of Dictyonina pannula is shallow and consequently is readily affected by abrasion or diagenetic effects. Wright (1981) discussed the development of pits in Dictyonina, noting an increase in breadth and a reduction of definition with age. The formation and function of the coarsely pitted ornamentation in Ordovician linguliform brachiopods has been extensively discussed by Holmer et al. (2017), however, those for Cambrian paterinides still remains poorly understood.

Type species.—Lingula? monilifera Linnarsson, 1869 from the lower Cambrian (Series 2, Stage 4) Mickwitzia Sandstone Member of the File Haidar Formation near Lugnås, Västergötland (Sweden).

1908 Mickwitzia occidens Walcott, p. 54, pl. 7, fig. 1.

1912 Mickwitzia occidens; Walcott, p. 331, pl. 6, fig. 4.

1976 Mickwitzia occidens; Mount, fig. 3.

1977 Mickwitzia occidens; Rowell, p. 79, pl. 1, fig. 12.

1980 Mickwitzia occidens; Mount, fig. 3.

1992 Mickwitzia muralensis Walcott, 1913; McMenamin, p. 181, figs. 4.1, 5.4, 5.6.

non 2002 Mickwitzia cf. Mickwitzia occidens; Holmer et al., text-figs. 2, 3.

2003 Mickwitzia occidens; Skovsted and Holmer, fig. 2.

non 2003 Mickwitzia cf. Mickwitzia occidens; Skovsted and Holmer, p. 3, figs. 3–5, 7–12.

non 2005 Mickwitzia cf. Mickwitzia occidens; Skovsted and Holmer, p. 327, pl. 1, figs. 9–13.

2007 Mickwitzia occidens; Holmer and Popov, fig. 1711d–i.

non 2007 Mickwitzia sp. cf. Mickwitzia occidens; Holmer and Popov, figs. 1712, 1713.

2010 Mickwitzia occidens; English and Babcock, fig. 4a, b.

2011 Mickwitzia occidens; Hollingsworth and Babcock, fig. 5.6, 5.7.

2015 Mickwitzia occidens; Butler et al., figs. 3–13.

2020a Mickwitzia occidens; Liang et al., fig. 1c, d, g.

Holotype.—An exfoliated valve (USNM 51518a), lower Cambrian (= Series 2), Silver Peak quadrangle, Esmeralda County, Nevada, U. S. Geological Survey locality 174c (Walcott, 1908, pl. 7, fig. 1; reillustrated by Rowell, 1977, pl. 1, fig. 12). According to Rowell (1977) and Mount (1980), the holotype was collected from the Harkless Formation in the lower part of the Bonnia-Olenellus Zone.

Description.—Outline of dorsal valve ovoid with apex at posterior margin (Fig. 4.8), more or less flat in lateral profile as other shale-hosted specimens. Size large, of 23 mm length, 26 mm width. Reticulate-pustulose ornament, typical of all known species of Mickwitzia, well defined (Fig. 4.9, 4.10). Concentric growth lines and radial costellae radiating from apex at posterior margin, with ∼16 fila and 20 costellae per mm (Fig. 4.9, 4.10). Smooth metamorphic shell, ∼500 µm in diameter, in posterior part of dorsal valve (Fig. 4.9).

Material.—One dorsal valve (UCR 10/8/1) recovered from the Latham Shale.

Remarks.—Mickwitzia remains an enigmatic taxon. Although it has an overall brachiopod-like appearance with two bilaterally symmetrical valves, it exhibits no character diagnostic for any know group of brachiopods, making it a hotly debated topic for nearly a century. Although Mickwitzia is neither new to paleontology nor rare in the lower Cambrian strata (e.g., Schmidt, 1888; Walcott, 1912; Rowell, 1977; McMenamin, 1986; Nemliher, 2001; Balthasar, 2004; Skovsted et al., 2009; Butler et al., 2015; Liang et al., 2020a, b), its phylogenetic position has never been satisfactorily resolved. Holmer and Popov (2007) included Mickwitzia and Heliomedusa Sun and Hou, 1987 within the informal grouping of mickwitziid-like stem-group brachiopods. The taxonomic composition and phylogenetic position of this informal grouping need to be further investigated.

Detailed research in last two decades has greatly enhanced our understanding of mickwitziids. Balthasar (2004) suggested a close relationship between Mickwitzia muralensis (Mural Formation, Canada) and paterinids due to similarities in their strati-form shell microstructure, parvicostellate ornament, and posterior margin of juvenile and early-mature shells. Skovsted et al. (2009) reported an unnamed new species of Mickwitzia from Australia; the morphology of the dorsal valve apex and the extended cones on the internal surface indicate a close affinity with Mickwitzia muralensis from the lower Cambrian of British Columbia, and extend the known range of the pivotal stem group brachiopod Mickwitzia to East Gondwana. Butler et al. (2015) described Mickwitzia occidens from the Indian Springs Lagerstätte (Cambrian Stage 3), Nevada and suggested that the inwardly pointing cones are not consistent with the setalbearing structure as previously thought. Furthermore, the presence of acrotretid-like shell structures and shell-penetrating setae in Mickwitzia occidens strengthen the previously proposed close relationship between stem-group brachiopods and tommotiids. Liang et al., (2020b) restudied Heliomedusa orienta from the Chengjiang Konservat-Lagerstätte and indicated its reticulate-pustulose ornament, tubular structure, and its marginal mantle setae and shell penetrative setae closely related to the type species Mickwitzia monilifera.

The specimen of Mickwitzia occidens collected from the Latham Shale is remarkably similar to specimens of Heliomedusa orienta from the Chengjiang Lagerstätte in size, morphology, preservation of setae, and the reticulate-pustulose ornament. Besides, the preservation mode also bears some overall similarities to the Chengjiang-type preservation in weathering and replication of the shell and soft parts as iron oxides. The occurrence of Heliomedusa-like Mickwitzia in the Latham Shale represents an important stratigraphic extension of this taxon in North America, making it reasonable to suggest that the FAD of mickwitziids in Laurentia and Gondwana could be diachronous (Liang et al., 2020a). Although it is possible that Mickwitzia is a senior synonym of Heliomedusa, there remain difficulties in making detailed taxonomic comparisons between shale-hosted and three-dimensional material, and more material preserved in the Latham Shale is needed to test this hypothesis.

Type species.—Orthisina festinata Billings, 1861, from unnamed Cambrian Stage 4 (Bonnia–Olenellus Zone) of USA and Canada.

1980 Nisusia fulleri; Mount, fig. 4.

1981 Nisusia fulleri Mount, figs. 1, 2.

Holotype.—A dorsal valve (UCR 10/2031), Latham Shale of California, USA (Mount, 1981).

Description.—Shell transversely semioval in outline (Fig. 5.1–5.7), of 2.68–7.04 mm length, 3.82–7.59 mm width. Hinge line shorter than maximum width at midlength. Cardinal extremities slightly acute to almost rectangular; anterior commissure rectimarginate (Fig. 5.1, 5.3). Dorsal valve moderately and evenly convex, slightly carinate, with maximum convexity at posterior part; lateral slopes planar to gently concave. Umbo small, gently incurved (Fig. 5.1, 5.3). Thick costellae ornamenting shell surface, with median costellae most thickened; number of costellae increasing by intercalation and separated by narrow interspaces; hollow spines distributed in interspaces, ∼60 µm in diameter, separated by 300 µm (Fig. 5.1–5.4), presenting on some broken shells (Fig. 5.5, 5.6). Cross striation on radial costellae, more prominent at distal 14% shell length where costellae become thicker. In total, ∼12 ribs per 3 mm along anterior margin of mature individual. Dorsal interior not observed.

Materials.—Two slabs (UCR 10/2031 and 10/2023) of specimens, including at least five valves, recovered from the Latham Shale.

Remarks.—Nisusia has most commonly been regarded as a poorly defined ‘waste basket’ taxon, due to the fact that the morphology of many species described in the first half of the previous century are inadequately known. However, Holmer et al., (2019) recently reviewed the phylogeny and distribution of nisusioid brachiopods and restricted Nisusia to species provided with radiating costellae bearing hollow spines. Holmer et al. (2019) also suggested that most of the taxa (mainly from Laurentia) from the lower Cambrian (unnamed stages 3–4) that have been assigned to Nisusia, belong neither to Nisusia nor to Nisusioidea, and presently only 19 taxa, plus one described under open nomenclature, can be assigned to Nisusia with some degree of confidence, whereas the generic affinities of five more species require further study.

Nisusia fulleri from the Latham Shale was excluded from the genus due to insufficient description and illustrations, and was considered to be a nomen dubium (Holmer et al., 2019). The new information on N. fulleri provided here substantiates the presence of thick costellae and hollow spines (Fig. 5.1–5.6), thus making it reasonable to bring the species back to the Nisusia group.

To date, four of the five nisusiid species documented from the unnamed Cambrian Series 2, including Eoconcha austini Cooper, 1951, Nisusia festinata (Billings, 1861), Nisusia ancauchensis Benedetto and Foglia, 2012, and Nisusia fulleri described herein, are from Laurentia, suggesting that this continent was probably the major center of early Cambrian nisusiid dispersal (Holmer et al., 2019). Nisusia fulleri is closely similar to the type species N. festinata, with the latter being spinocostellate and appears to have costellae of more even size and a narrower, deeper sulcus. Shell valves of N. ancauchensis, from olistolith (unnamed Cambrian Stage 4, Bonnia–Olenellus Zone), Quebrada Ancaucha, Argentina, is more convex and is ornamented with wider costellae (Benedetto and Foglia, 2012).

Type species.—Wimanella simplex Walcott, 1908 from the lower Cambrian of eastern British Columbia, Canada.

1886 Orthis? highlandensis Walcott, p. 119, pl. 8, fig. 3, 3a, 3b.

1905 Billingsella highlandensis; Walcott, p. 237.

1932 Wimanella highlandensis; Schuchert and Cooper, p. 50.

1981 Nisusia fulleri; Mount, fig. 2.

Holotype.—One valve (USNM 15355c), eastern side of anticline near Pioche, Nevada (Mount, 1974a, who did not characterize it as dorsal or ventral).

Description.—Shell subrectangular to trapezoidal in outline, ∼16.37 ± 2.10 mm in width, with length/width ratio of 0.77 (N = 3) (Fig. 5.8–5.10). Rectangular to gently obtuse cardinal extremities; maximum width at midlength or slightly anterior to hinge line. Ventral valve moderately and evenly convex with broad shallow sulcus. Shell surface marked by prominent radial ribs and weak concentric growth lines. Radial ribs originating at 1/5–1/7 valve length from posterior margin, widening gradually to margin with increment; total number of ribs 40–140; new ribs appearing by intercalation and separated by interspaces. Ribbing impressed on internal molds. Cardinal area of ventral valve unknown except that its plane extends backward at angle of ∼10° or 15° to plane of shell margin.

Materials.—Three ventral valves (UCR 10/2019B, 7307-13, and 7307/5) recovered from the Cadiz Formation.

Remarks.—Species of Wimanella are characterized by their smooth nonplicate shells (that Walcott previously referred to Billingsella Hall and Clarke, 1892). Wimanella is known from several lower to middle Cambrian areas, including North America, Australia, Siberia, and eastern China (e.g., Mount, 1974b; Roberts and Jell, 1990; Benedetto and Foglia, 2012). The species from the Cadiz Formation was previously regarded as Nisusia fulleri by Mount (1981), however, they differ significantly in that W. highlandensis is more trapezoidal in outline, and N. fulleri has thicker striae and a more elevated umbo. Wimanella tricavata Roberts and Jell, 1990 from the middle Cambrian Coonigan Formation of New South Wales can be differentiated by its subequally biconvex shell profile, slightly auriculate outline, shallow dorsal sulcus, and indistinct cardinal process (Roberts and Jell, 1990). Wimanella mollensis Benedetto and Foglia, 2012 from the middle Cambrian La Laja Formation of the Precordilleran Terrane can be differentiated by its deeper dorsal sulcus and less-developed radial striae (Benedetto and Foglia, 2012).