Description. Unit 2a is composed of laterally and vertically extensive fine‑ to coarse-grained sands interbedded with pebble‑ to boulder-sized gravels. At most of the sites studied, the sediment lies stratigraphically below finely laminated silt and clay of unit 2b or massive, matrix-supported silty diamicton of unit 3a (Fig. 3). Often the lower contact of the unit is not exposed, but drilling in the Bulkley River valley indicates these sediments lay above older Quaternary deposits (Fig. 4).

Generally, unit 2a is <10 m thick, but along the Pine Creek valley (site 1, Figs. 2‑3), the sand and gravel sequence ranges from 10‑30 m thick. Similar sand and gravel deposits were described by Levson et al. (1997) and Levson (2001) northeast of the study area, and by Clague (1984) northwest of Smithers (Fig. 1).

The sands and gravels are moderately dense to loose and moderately to well-sorted. They show both horizontal bedding and large-scale, low-angle trough cross-bedding. In the Pine Creek valley (site 1, Figs. 2‑3), a thick sequence of horizontally bedded sand lies beneath trough cross-bedded strata (Fig. 5). Locally, the sand and gravel deposits contain trough-shaped channel fill sequences of medium‑ to fine-grained sand. Near the base of this unit, fluid escape and loading structures (e.g. flame structures) deform bedding. These sediments are exposed well above the levels of modern drainage channels.

Interpretation. The sands and gravels were likely deposited as glaciofluvial sediments during a period of elevated local base level, probably caused by aggradation in front of advancing glaciers at the onset of the Fraser Glaciation (cf. Levson et al., 1997; Levson, 2001). In the Pine Creek valley, sands forming horizontal beds (likely bottomset beds) and low-angle trough cross-beds (possibly foreset beds) were likely deposited as a fan or outwash delta (cf. Donnelly and Harris, 1989; Postma, 1990) by water flowing out of the Hazelton Mountains into a proglacial lake.

Description. Stratified and horizontally-bedded sediments of unit 2b composed of repeated silt beds and clay laminae (e.g. Fig. 6) were identified in numerous vertical exposures in the Bulkley River region (Fig. 3). Sediment of unit 2b was also encountered during subsurface drilling for geological and engineering investigations (e.g. British Columbia Ministry of Forests, 1996). These fine-grained sediments lie beneath deposits of unit 2c or massive matrix-supported diamicton of unit 3.

Silts and clays of unit 2b range from reddish brown to grey in colour and contain scattered clasts, some up to boulder-size and a few with striae and facets. Locally, unit 2b may include massive or horizontally bedded fine-grained sands that may be interbedded with medium‑ to coarse-grained sand and small pebble gravel beds, or diamicton lenses with intraclasts of sorted sediment. At some sites, beds of sand grade upwards into the coarser sediments of unit 2c. The unit ranges from 2‑15 m thick.

Moderate to intense deformation was locally observed, and included loading features, folding, and faulting. Also, the sediments are over-consolidated and bedding in the upper part of the unit is sheared. These characteristics are similar to glaciotectonic deformation found in glacial advance sediments at other locations (e.g. Broster and Clague, 1987).

Concretions and worm burrows are locally present along individual lamina. Several concretions were collected from site 2 (Figs. 2‑3). Carbon contained in the accretion rings (dated by Accelerator Mass Spectrometry; Levy and Jull, 1998) yielded a radiocarbon age of 37 700 ± 2100 BP (AA‑331440). The carbonate was pre-treated with phosphoric acid and reacted at 625 °C with hydrogen, and iron filings catalyst.

Interpretation. Silts and clays of unit 2b were probably deposited in proglacial lakes during ice advance (cf. Eyles and Clague, 1991) suggesting that proglacial lakes developed in front of advancing glaciers at the onset of the Late Wisconsinan glaciation. Interbeds of medium‑ to coarse-grained sand and small pebble gravel within the unit were likely laid down by underflows (cf. Shaw and Archer, 1978). Lenses of diamicton and intraclasts of sorted sediment were probably deposited as ice-marginal subaqueous debris flows (cf. Broster and Hicock, 1985).

Well-developed laminae, probably rhythmites, are characteristic of sedimentation in ice-marginal and proglacial lakes with relatively constant sediment inputs and strong seasonal controls (Smith and Ashley, 1985). Sharp contacts between unit 2b and the underlying sands and gravels of unit 2a (e.g. site 1, Fig. 3) are indicative of a rapid transition between glaciofluvial and glaciolacustrine depositional environments. Moderate to intense soft-sediment deformation commonly observed in unit 2b likely occurred when the saturated sediments were buried. However, compressive deformation (shearing) and consolidation of the unit are attributed to stress from the overriding ice.

The occurrence of a concretion dated to the Olympia Nonglacial Interval, in sediments interpreted as Late Wisconsinan ice advance sediments, is problematic. It indicates that the concretions probably formed by precipitation of old carbonate from groundwater yielding a spurious radiocarbon age. Additional development of the methodology used to date concretions by radiocarbon is required before this date can be resolved.

Description. Unit 2c consists of an interbedded sequence containing pebbly silt, fine- to medium-grained sand, diamicton, silt and clay and fine gravel. The unit gradationally overlies silts and clays of unit 2b. The sediments are massive to crudely bedded and generally coarsen upwards (e.g. site 5, Figs. 2‑3). Silt and clay beds contain numerous pebble‑ to boulder-sized clasts. Unit 2c ranges from 2‑18 m thick.

Interbeds of diamicton increase in abundance toward the top of unit 2c. At many sites, the diamicton contains lenses of stratified gravel and sand, and blocks (intraclasts) of silt and clay with deformed bedding (Fig. 7). Often, bedding in these sediment packages is deformed by faults and folds, and ball-and-pillow, flame and fluid-escape structures.

Interpretation. Unit 2c is interpreted as proglacial and ice-marginal deposits that include subaqueous debris-flow deposits (cf. Eyles, 1987 and Ghibaudo, 1992) or rainout debris from icebergs (cf. Hambrey, 1994). Subaqueous debris flows probably remobilized submerged valley-fill sediments when moving downslope in a manner outlined by Eyles and Clague (1991) and Bennett et al. (2002). Pebbly silt and laminated silt and clay with clasts (dropstones) accumulated in proglacial lakes ponded in front of advancing glaciers. The upward increase in the abundance of diamicton, coarse sediments and dropstones, probably reflects the increased proximity of ice.

Intraclasts of reworked sediment in debris flow diamicton were likely incorporated during downslope movement over previously deposited glaciolacustrine sediments. Also, incorporation of the underlying substrate by debris flows and glaciers may have produced gradational basal contacts (cf. Hart, 1995; Benn and Evans, 1996).

The ball-and-pillow and flame structures present in unit 2c are attributed to rapid deposition on saturated sediments and post-depositional dewatering. Folding and faulting of beds in the unit are interpreted to result from basal shear during subsequent glacier overriding (cf. Menzies, 1995).

Description. In the Bulkley River region, unit 3a is comprised of massive matrix-supported diamicton predominantly having a silt loam matrix texture; locally it varies from silty clay to sandy loam where the glacier eroded older lacustrine or fluvial sediments. Typically, the diamicton unconformably overlies either older sediments of unit 2 or bedrock.

The diamicton is moderately to very dense, contains striated and faceted clasts of diverse lithologies, and its overall colour and clast content largely reflect the character of the underlying sediments or local bedrock. For example, diamicton down-ice of maroon-coloured (Lower Jurassic) andesite has a distinctive reddish brown colour and contains a larger proportion of andesite clasts than elsewhere. Where measured, the a‑axes of clasts generally parallel the main directions of ice flow at the glacial maximum in the region (site 6, Fig. 3; Stumpf, 2001). Moderate to strong fracturing and jointing are pervasive. Locally, the diamicton contains thin beds or lenses of pebble gravel, sand, silt, or clay. Locally, the upper part of the diamicton is crudely stratified in valley bottoms along the margins of deglacial lakes.

The diamicton is <0.5‑40 m thick and commonly extends to the surface. Geomorphologically, this unit is expressed as: (1) drumlinoid ridges that parallel former ice flow; (2) a gently sloping or undulating terrain that completely mantles the topography of the underlying material; or (3) a thin veneer that lies on an undulating to ridged bedrock surfaces.

Interpretation. This massive, matrix-supported silty diamicton unit is interpreted as a basal till. This interpretation is supported by the presence of lithologically diverse and glacially abraded clasts, the high degree of consolidation, and the strong clast fabric. Crude stratification, locally present in the upper part of the till, likely resulted where slumping along the margins of deglacial lakes reworked the till, although, deposition by meltout of basal debris-rich ice is also a possibility.

Description. Massive, matrix-supported silty diamicton (basal till) of unit 3a is locally overlain by weakly consolidated and stratified diamicton of unit 3b. This material is distinguished from unit 3a by its generally sandier texture (sandy clay loam to loamy sand), presence of stratification, and weaker consolidation. It is pervasively oxidized, and contains interbeds of poorly sorted cobble‑ to boulder-sized gravels. Locally, the diamicton contains a higher proportion (>20%) pebble‑ to boulder-sized clasts derived from distal bedrock units than that of the underlying unit 3a (basal till).

Typically, unit 3b forms a thin, discontinuous surface blanket up to about 2 m thick that overlies either basal till or bedrock. Generally, the surface expression of the diamicton is hummocky, but in some areas, the topography is more subdued and ranges from undulating to level. This diamicton is most often present in areas where ice-contact sediments and deglacial landforms (e.g. kames, kame terraces, and eskers) are present.

Interpretation. The sandy diamicton of unit 3b is interpreted as till of a supraglacial or englacial origin (cf. Benn, 1992). Coarse gravel interbeds probably reflect the sorting of debris by meltwater as well as sedimentation within small ice-proximal channels. The increase in far-traveled clasts, compared to unit 3a, suggests that unit 3b debris was carried in englacial or supraglacial positions.

Description. Unit 4a consists of beds of crudely imbricated, rounded pebble to cobble gravel and poorly to well sorted medium‑ to coarse-grained sand. These deposits form sinuous ridges, undulating to hummocky topography (Fig. 8), and elevated terraces or fan-shaped deposits at the outlet of tributary valleys or along margins of valleys. These sediments range in thickness from 3‑10 m and are present up to 130 m above the bottom of modern river valleys. Generally, gravels in unit 4a are poorly sorted and clast-supported, and commonly have crude horizontal bedding. In some locations, the gravels show planar or trough cross-bedding, scour-and-fill structures, and interbeds of fine‑ to coarse-grained sand. Typically, the sand beds in unit 4a are well-sorted, and exhibit horizontal‑ and ripple‑, or trough cross-bedding. These sediments locally contain striated clasts and interbeds or lenses of matrix‑ and clast-supported diamicton that are stratified or deformed. At some locations, gravels and sands of unit 4a fine upwards into laminated silts and clays of unit 4b.

Locally, gravel and sand beds in this unit are faulted and folded, or show scour-and-fill structures. Paleocurrent measurements indicate that meltwater flowed in various directions, not necessarily parallel to the alignment of modern valleys. In some areas (e.g. east of Bulkley Lake, Figs. 1, 9), meltwater flow was directed across modern drainage divides.

Interpretation. The gravels and sands of unit 4a are interpreted as glaciofluvial sediments deposited at the end of the Fraser Glaciation. These sediments compose ridges (eskers), elevated benches (ice-marginal terraces), fan-shaped deposits (fans and deltas), and flat-lying lowlands (outwash plains). Locally, fining-upward gravels and sands in the section indicate a shift towards a more ice-distal depositional environment. The diamicton layers were likely deposited as debris flows in an ice-proximal environment. Deformation observed in these sediments is attributed to the melting of supportive ice.

Description. Unit 4b is composed of interstratified fine-grained sand, silt, and clay. These sediments overlie diamictons of unit 3, or unit 4a at elevations ranging from 520 and 975 m asl (Fig. 9). The fine-grained sands can be massive, horizontally stratified, ripple laminated, or cross-bedded. Generally, the silts and clays are crudely laminated, but they also form thick (>50 cm) massive beds. Typically, unit 4b ranges from 2‑10 m thick, with the thickest deposits commonly exposed near outlets of major meltwater channels along the larger valleys.

Locally, these fine-grained sediments are interbedded with small‑ to large-sized gravels and coarse-grained sands, and massive or stratified diamicton. Scattered rounded and striated clasts, some up to boulder size, are present throughout the unit.

Interpretation. Fine-grained sediments of unit 4b are interpreted as late-glacial phase, glaciolacustrine sediments deposited distally from glacier margins. These lakes were ponded behind downwasting ice blocks and/or recessional moraines during deglaciation (cf. Plouffe, 1997a, 2000). The lack of thick sequences of rhythmic silts and clays, and the absence of recognizable glacial lake strandlines, suggests that these lakes were probably shallow and existed for a relatively short time.