Geologic Studies in Alaska by the U.S. Geological Survey, 1992

EARLY CENOZOIC DEPOSITIONAL SYSTEMS, MATANUSKA COAL FIELD
to rapid basin subsidence (Smith, 1983). Thus, the vertical
repetition of coal zones in the Chickaloon Formation re-
flects an intrabasin interaction of autocyclic (avulsion and
abandonment of stream courses influenced by local sedi-
ment compaction) and allocyclic (regional basin subsid-
ence) processes.
WISHBONE FORMATION
Facies characteristics of the lowermost part of the
Wishbone Formation, which consists mainly of frame-
work-supported conglomerates and subordinate gritty sand-
stones, indicate deposition in high-gradient braided streams
and alluvial fans. Steepening of stream courses at this
time reflects extrabasinal or provenance uplift (Clardy,
1974). The multiscoured, imbricated, pebbly conglomer-
ates were deposited as gravel bars by traction currents in
channelized flows. Fining-upward conglomerate suggests
gradual infilling of active channels by migrating gravel
during floods. Waning stages of floods are reflected by
ripple-laminated gritty sandstone caps on these gravel bars.
Interbedded conglomerates and sandstones reflect the
flashy discharge af the braided streams. Erosional-based
sandstones interbedded with the conglomerates, which are
trough and planar crossbedded, are attributed to sand-bar
accretions marginal to or on top of gravel-bars during wan-
ing flows. Vertical stacking of the conglomerates suggests
their deposition in laterally shifting, diverging, and con-
verging channels such as in a broad-belt braided stream.
The lower part of the study interval in the Wishbone
Formation probably reflects a dichotomy of braiding by
sand and gravel bars. The sandy braid bars suggest devel-
opment of a passive belt of braided streams contemporane-
ous to gravelly braid bars, which represent active belts of
braided streams. This dichotomous relationship of bedload
sediments in a depositional continuum reflects gravel-bar
sedimentation during flood periods succeeded by pro-
longed gradual waning periods, which resulted in infilling
of gravel belt margins of braided streams by sand bars.
Waxing and waning depositional events in the braided
streams are in contrast to the upper part of the study inter-
val, which was deposited during perennial flood periods.
This facies sequence indicates sedimentation at distal and
proximal areas of humid alluvial fans (Clardy, 1974).
Pebble imbrication and crossbed directions (Clardy, 1974)
suggest westerly flow of the braided streams and south-
westerly flow of streams within the alluvial fans.
SUMMARY
Facies architecture indicates that the fluvial deposi-
tion of west-southwest-flowing meandering to anasto-
mosed streams in the Chickaloon Formation was
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succeeded by westerly flowing braided streams and south-
westerly prograding alluvial fans in the Wishbone Forma-
tion. The meandering and anastomosed streams probably
were a part of a flow-through, trunk-tributary, fluvial sys-
tem that drained the "Matanuska geosyncline" (fig. 11).
These streams may have been propagated under varying
base-level conditions influenced by basin subsidence
(allocyclic), avulsion due to sediment compaction
(autocyclic), and growth faulting. When subsidence rates
were low, lateral aggradation by meandering streams oc-
curred in stable, confined meander belts. This was ac-
companied by flood-plain clastic accretion and organic
accumulation in topogenous mires, which developed on
abandoned meander belts removed from detrital influx.
In areas dissected by left-lateral, oblique-slip faults, verti-
cal movements localized aggradation by streams captured
on downthrown areas. In addition, probable diversion of
crevasse splays on downthrown areas caused splitting of
the coalbeds accompanied by overthickened interburden
intervals. In contrast, mires on upthrown areas, where
thick coalbeds accumulated, were undisturbed by detrital
influx.
Flood-plain sedimentation by crevasse splays during
flood discharges from meandering streams initiated the
process of anastomosis. Progradation of crevasse splays
into the flood plain permitted bifurcation and merging of
crevasse channels. This process, influenced by a high rate
of basin subsidence, expanded areas of anastomosis and
flood-basin lake development, and enhanced vertical
aggradation of crevasse channel-overbank sediments.
Topogenous mires formed in flood basins enlarged onto
abandoned sites of anastomosis. As anastomosis matured,
a crevasse channel was transformed into a major conduit
and through time, developed from a low- to a high-sinuos-
ity stream, leading to the onset of a meandering stream and
repetition of the fluvial cycle. However, we propose that
these streams occurred alternately through time and geo-
graphically coexisted in the drainage basin. Vertical and
lateral aggradation of these streams were affected by local
subsidence due to sediment compaction (autocyclic) and
regional basin subsidence (allocyclic).
During raising and steepening of the regional base
level (due to extrabasinal factors), the mire-prone, mean-
dering and anastomosed fluvial systems were replaced by
high-gradient, braided streams and transverse alluvial fans.
Uplift of the Talkeetna Mountains along the Castle Moun-
tain fault north of the Matanuska Valley controlled the gra-
dient of the streams and their sediment supply (Grantz,
1966; Clardy, 1974). Mountain-front, alluvial-fan con-
glomerates represent IocaIized deposits from intermittent
movements along the fault. These alluvial fans supplied
sediments to the lower-gradient, non-mire-forming, braided
streams. Bimodal sediment loads in the braided streams
reflect either episodic flash floods due to seasonal climatic
changes or periodicity of provenance uplift.