Slide1 : KARST CONNECTION MODEL FOR THE GRAND CANYON
ARIZONA, USA By Carol A. Hill, Noel Eberz, and Bob Buecher
Slide2 : GRAND CANYON PROJECT Age of the Grand Canyon. Dating of cave deposits to determine
water-table position over time and space. Victor Polyak, Carol Hill, Yemone
Asmeron. Dating project supported by the National Science Foundation and
University of New Mexico Radiogenic Isotope Laboratory. (2) Ancestral Colorado River. Where did the ancestral Colorado River flow
before it went through the Grand Canyon? Carol Hill, Wayne
Ranney, Bob Scarborough, and Doug Powell. Field support from-
BLM Grand Staircase-Escalante National Monument. **(3) Karst Connection Model. Addresses 4 major geomorphic mysteries about
the Grand Canyon from a karst perspective. Carol Hill, Noel Eberz, and
Bob Buecher. Grants from National Park Service, Grand Canyon Association,
and National Speleological Society.
Slide4 : Little Colorado R. Chuar basin Colorado R. Colorado R. Marble Canyon ? 5 MAJOR MYSTERIES:
GEOMORPHIC EVOLUTION
OF EASTERN GRAND CANYON (1) Where did Ancestral Colorado River
flow before its integration through the
Grand Canyon ~6 Ma? Kaibab arch (5) How did the Colorado River cross
the Kaibab arch high? That is, how
did the eastern Grand Canyon connect
with the western Grand Canyon? (4) Why does the Colorado River make
a sudden bend from south to west? C (3) Why does the young narrow
Marble Canyon cut its course less than
a mile from the Chuar Basin? (2) Why do the “young” narrow
Little Colorado and Marble Canyons
meet at the Confluence = C, whereas
the Grand Canyon “opens up” below
the Confluence? This karst connection sub-project #3 Sub-project #2
Slide5 : . . . . A F B H KAaxis C Map showing groundwater divides (dashed lines) between hydrologic basins. Blue Springs (B) is the discharge point for the Black Mesa
basin today. For each of these modern basins, water follows structure (synclines, faults) along the steepest hydraulic gradient to spring
outlets in the Redwall Limestone.
Solid arrows shows probable route Redwall water takes today from the 3 pits (Ah Hol Sah A, Indian, Black Abyss) to Fence Springs (F).
From Huntoon (2000). PRESENT-DAY HYDROLOGY OF THE EASTERN GRAND CANYON
Slide6 : Ah Hol Sah sinkhole, near Tanner Wash, is 150 m across and 40 m deep. The sinkhole is actively
collapsing into the Redwall karst aquifer, which is probably discharging at Fence Springs. A small
wash (foreground) now drains (arrow) directly into the sinkhole; i.e., drainage to Tanner Wash has
been pirated down the sinkhole to karst channels (caves) below. *The Karst Connection Model proposes that this same process happened at the Confluence ~6 Ma.
Water flowing along the ancestral Little Colorado River was pirated down into a Confluence
sinkhole in the same manner as it is today at Ah Hol Sah. A = AH HOL SAH SINKHOLE
Slide7 : . . . . A F B H KAaxis C THE PRESENT IS THE KEY TO THE PAST Essentially, we are projecting what is happening today in the Kaiparowits basin (where the Redwall aquifer is still
intact), back in time and spacially southward. At~6 Ma, before canyon dissection, the Redwall aquifer was still
intact in the area of the Confluence (C). Note that the proposed karst connection goes under the Kaibab arch.
Slide8 : PROPOSED KARST CONNECTION ROUTE – PRE-6Ma Ancestral Little
Colorado River
flows north to Utah
prior to connection
at ~6 Ma
To Utah (“Glen Lake”) Pre- 6 Ma:
No Marble Canyon
No Little Colorado
River Canyon
No eastern Grand
Canyon
No Blue Springs
(erosion had not cut
down to Redwall
level yet) Water flows east
down East Kaibab
monocline,
vertically down
collapse features,
and west along
ancestral Black
Mesa basin. It
converges on Blue
Springs fault,
descends to the
Redwall aquifer,
and then moves
northward, in the
direction of the
hydraulic gradient.
Slide9 : . . . . . . . . C . . . . . . Breccia pipe Collapse feature 36°15' 36°15' 111°45' Water flowed north in the Redwall aquifer until it encountered the Cedar Ridge anticline; then it was diverted southwest to the
Confluence (C), creating a zone of collapse features - the Confluence sinkhole being one of this zone. Little Colorado River water
was pirated down this collapsing sinkhole (blue arrow). The Cedar Ridge anticline caused water to divert toward the Confluence
(green arrow), thus allowing headward erosion of Marble Canyon to proceed against dip. Confluence = surface + subsurface water.
Collapse features and base map from Sutphin (1986); breccia pipes from Sutphin and Wenrich (1989) and Huntoon et al. (1996). Cedar Ridge anticline Cedar Ridge anticline Marble Canyon Redwall karst aquifer flow Subsurface Surface Surface
Slide10 : PROPOSED KARST CONNECTION ROUTE: ~6 Ma Reversal of drainage Sinkhole Headward erosion
proceeds up Marble
Canyon and Little
Colorado River
Canyon from
collapsing sinkhole. Redwall karst
aquifer flow
goes under
the Kaibab arch
to discharge
in headward
eroding western
Grand Canyon
along synclinal
axis of Grandview
monocline.
Spring discharge
occurs along
Redwall horizon
in the Hance Rapids
area where the
Redwall Ls has been
uplifted and
exposed along faults C = Collapsing
sinkhole at
Confluence Little Colorado River
water is pirated down
the sinkhole to the
Redwall aquifer; no
longer flows north. Reversal of drainage
in Marble Canyon Where does water go? It follows steepest
hydraulic gradient
to exit as springs
where Redwall Ls
is exposed.
Slide11 : KARST AQUIFER FLOW Permeability pathways are produced by the fluid of the flow system itself rather than
by some inherited geologic fabric or structure. As karst conduits become larger and better integrated, the hydrologic flow system
becomes dominant and conduits develop along the steepest hydraulic gradient. Thus, flow in karst aquifers can cross faults and folds, move opposite to dip, and go under
or through structures as it pursues a path along the steepest hydraulic gradient to discharg.
Slide12 : 3000 ft 4000 ft 5000 ft 6000 ft 7000 ft 8000 ft TOK = 6100 ft TOR = 4100 ft Confluence
sinkhole TOR = 4400 ft Marble Platform GV = Grand View Point HS Mesa, TOR = 5200’ Redwall Ls TOR = ~4500’(?) H = Hance spring C = Confluence Redwall Ls Grandview monocline ~6000 ft (?) TOK = 7400 ft East Kaibab monocline 300 ft PS PS = Potentiometric surface Butte fault Kaibab arch Schematic cross section of how Redwall karst aquifer water could have recharged on the Marble
Platform, gone under the Kaibab arch, and discharged from the-then still-intact Redwall Limestone
in the Hance Rapids area ~6 Ma. TOK = Top of the Kaibab; TOR = Top of the Redwall;
PS = Potentiometric surface. Vertically exaggerated. Extension
faults ~6 Ma: Time of Karst Connection
Slide13 : POST-CONNECTION EVENTS (<6 Ma to Present) Once the Little Colorado
River cut down to Redwall
level at the Confluence and
then in Little Colorado
Canyon, the discharge point
for the Black Mesa basin
moved from H to C to B
(Hance Rapids area to
Confluence to Blue Springs) The former Redwall karst
aquifer route past the
Confluence thus became
disconnected from the
Black Mesa hydrologic
basin by canyon incision. Subsequent collapse
and canyon incision
followed along the
former karst
connection route.
Slide14 : EVIDENCE SUPPORTING A KARST CONNECTION MODEL (1) The model is consistent with the Principles of Karst Hydrology. Flow in karst aquifers
can cross faults and folds, move opposite to dip, and go under or through structures as it
pursues a path along the steepest hydraulic gradient to discharge.
So going under the Kaibab arch is no problem! (2) The model is consistent with the Principle “the present is the key to the past”. The model
extends Huntoon’s flow in present-day hydrologic basins backward in time. We have just
moved what is happening today in northern Marble Canyon, where the Redwall karst aquifer
is still intact, southward to where the Redwall aquifer was intact ~6 million years ago
(i.e., before canyon erosion truncated the aquifer in the area of the Confluence). (4) The model is supported by the “barbed tributaries” in Marble Canyon. (3) The model is consistent with today’s differential incision rates for the eastern and
western Grand Canyon. Eastern Grand Canyon = ~0.2-0.5 mm/yr; Western Grand Canyon
= ~0.07 mm/yr. Since the karst connection at ~6 Ma, the eastern Grand Canyon is still trying
to “catch up”(equilibriate) with the western Grand Canyon, incision-wise.
Slide15 : Base drawing from Ranney (2005) San Juan River Proposed interior lake basin (“Glen Lake”) Red arrows: Proposed direction of
flow of ancestral Little Colorado River
before karst connection at the
Confluence (C). Barbed tributaries
reflect the direction of this ancestral
flow; tributaries are obtuse to today’s
direction of flow. Ancestral flow was
down the northeast dip of beds; today’s
flow cuts opposite to dip.
Black arrows: Direction of flow today C BARBED TRIBUTARIES Glen
Lake
Slide16 : Confluence C = KINGPIN
to understanding mysteries
of eastern Grand Canyon: (1) Headward erosion proceeded up
Marble and Little Colorado canyons
from collapsing sinkhole at C; hence
these canyons are “young” (<6 Ma)
and narrow.
(2) “Ancient” Chuar basin is located less
than a mile from “young” Marble Canyon
because these two drainage systems
developed independently of each other. (4) The Colorado River crossed the
Kaibab arch by going under it, along
a karst route independent of structure. (3) The Colorado River turns from
south to west because it followed the
former karst route that connected
with a western proto-Grand Canyon
eroding eastward. Chuar Basin
Slide17 : CONCLUSION Karst processes are key to understanding the Grand Canyon,
from its connection to time of incision; yet these processes
are rarely invoked in the “standard” models of its evolution.