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GM/Great Flood Critique
« on: January 31, 2017, 01:34:21 pm »
Critique
http://www.asa3.org/ASA/education/origins/agescience2.htm
Complete Geologic Column
http://www.talkorigins.org/faqs/geocolumn/basin3.gif


GM: The Talk.Origins Archive: Exploring the Creation/Evolution Controversy
http://www.talkorigins.org/faqs/geocolumn

(1)Sedimentation Rate & Orbital Cycles
- The Cretaceous Carlile shale consists of sands and shales. Fourier analysis of the Niobrara laminations reveals that they vary in thickness according to the periodicities of the earth's long-term orbital cycles (Fischer, 1993, p. 263-295).

(2)Multi-Year-Old Organism Fossils (Oncolite Algae Growth)
- There are also oncolites, an algal growth on shells after the animals die which took time to grow (Wardlaw and Reinson, 1971, p. 1762). An excellent example of an oncolite is shown in figure 58 of Dean and Fouch (1983, p. 123). It says: "Cross section of an oncolite developed around a gastropod-shell nucleus from Ore Lake, Michigan. Concentric layering is the result of annual couplets of porous and dense laminae.)

Multi-Year-Old Coccolith Growth
- The Greenhorn limestone is made mostly of coccoliths, small skeletal remains approximately 3-5 micrometers in diameter about 40 ft thick, 16 ledge-forming, burrowed limestone beds separated by thin shales. The coccoliths had to grow in the water, then die and fall to the bottom; then organisms had to burrow into the sediment; then when coccoliths were not as productive, shale was deposited, separating the limestone beds, all requiring still water.

Multi-Year-Old Stromatolites
- The Duperow formation has stromatolites (limestone rocks deposited by daily increments of limestone from algae on a shallow (less than 30 feet) sea bottom (Burke, 1982, p. 554; Altschuld and Kerr, 1983, p. 104).

(3)No Fossil Organisms Like Today's
- The upper Jurassic Continental Morrison formation has footprints (Stokes, 1957, p. 952-954), fossil soil profiles (Mantzios, 1989, p. 1166), mammals, plants, some coal (Brown, 1946, p 238-248) huge dinosaurs and smaller ones. The animals and plants are different from anything alive today.

A: http://creation.com/werner-living-fossils
- http://creation.com/modern-birds-with-dinosaurs

(4)Dolomite Overheating
- 1300 feet of Bighorn Dolomite can not be Great Flood deposits because each gram of carbonate gives off about 1207 kilocalories per mole (Whittier et al, 1992, p. 576). To deposit these beds in one year requires that the energy emitted by each meter squared would be 278 times that received by the sun.

(5)Delicate Fossils
- There are also abundant fecal pellets and feeding traces (Hattin, 1971, p. 412-431; Savrda and Bottjer, 1993, p. 263-295).

(6)Too Much Bioclastic Limestone
- The lower part of the Devonian formations consist of bioclastic limestone, and the upper part interbedded carbonate with anhydrite.

A: http://creation.com/can-flood-geology-explain-thick-chalk-beds
- https://creation.com/images/pdfs/tj/j10_1/j10_1_107-113.pdf
- http://creation.com/grand-canyon-limestone-fast-or-slow-deposits
- ? http://creation.com/not-ancient-reefs-but-catastrophic-deposits
 
Too Many Crinoids
- The Mississippian Madison group largely consists of dead crinoid parts. (Clark and Stearn, 1960, pp. 86-88): The upper Mission Canyon formation or the Livingstone formation (of Alberta) is a massive limestone formation composed of sand-sized particles of calcium carbonate, fragments of crinoid plates, and shells broken by the waves. The Madison sea must have been shallow, and the waves and currents strong, to break the shells and plates of the animals when they died. The sorting of the calcite grains and the cross-bedding are additional evidence of waves and currents at work. The Livingstone limestone may be calculated to represent at least 10,000 cubic miles of broken crinoid plates, enough crinoids to cover the entire earth to a depth of 3 inches, but only a small part of a vast Mississippian crinoid bed that almost does cover the world (Morton, 1984, p. 26-27), U.S., Canada, England, Belgium, European Russia, Egypt, Libya, central Asia, and Australia.

(7)Non-Flood Sorting of Sediments & Fossils
- The geologic column is not sorted by ecological zones. The Silurian Interlake, Devonian Prairie, Pennsylvanian Minnelusa and Jurassic Morisson formations are continental deposits. Oceanic deposits sandwich these beds. The ocean came and went many times.

- The Paleozoic corals belong to one of three groups - only one of which is found in Mesozoic rocks; the other two became extinct at the end of the Paleozoic. The four-sided corals are only found in the Paleozoic. Modern corals of the 6-sided or 8-sided kind are not found until the Triassic.

- Permian pollen is found in the salt; modern pollen is not found (Wilgus and Holser, 1984, p. 765,766).

R: http://creation.com/pollen-paradox

- The Pierre shale has marine reptile bones concentrated in the Sharon Springs member, not sorted as Morris would assume by ecological zonation.

- Third, the geologic column is not divided by hydrodynamic sorting.

- Fossil mammals are not found with the earliest dinosaurs & no primates are found until the Ft. Union formation or that no full dinosaur skeletons are found in the Tertiary section, implies strongly that the column was not the result of a single cataclysm. Worldwide, no whales are found with the large Devonian fish. If the column was an ecological burial pattern, then whales and porpoises should be buried with the fish.

<<I think I have good answers for the rest below:>>
(8)Impossibility of Geocolumn Deposition in Short Timespan
(9)Too Much Evaporites
(10)Slow-Settling Particles
(11)Impact Signs vs Flood
(12)Fossils of Slow-Growing Trees
(13)Missing Sediments & Non-Flood Erosion

(8)Impossibility of Geocolumn Deposition in Short Timespan
- There is no way to have the whole column be deposited in a single year.
__[How many years then?]

(9)Too Much Evaporites [They aren't evaporites; they're magma deposits]
- The Opeche shale in the center of the basin, at its deepest part, is 300 feet of salt covering 188,400 square kilometers.
__[How fast could brine dry out between tsunamis? Or could it dry out under a load of salty limestone?]

- The Silurian Interlake formation consists of carbonates, anhydrite, salt, with minor amounts of sand & throughout this deposit are also burrows and mudcracks from drying out of the layers (Lobue, 1983, p. 36,37).
__[If each megatsunami came a few weeks apart, would it be enough time to dry out & form mudcracks, anhydrite, salt etc?]

- Anhydrite is an evaporitic mineral not compatible with a global flood. The next Devonian bed is the Prairie Evaporite. It consists of dolomite, salt, gypsum, anhydrite and potash. These are generally considered evaporitic and thus incompatible with deposition during a worldwide flood (Gerhard, Anderson and Fischer, 1990, p. 515).
__[Were there heat sources during the cataclysm & enough time between tsunamis for significant evaporation?]

- There is also salt cementation with salt deposited in the fractures and crevices in the rock. Halite plugged burrows are also found.
__[Could the source of salt be like the brine lake under the Gulf of Mexico carried by tsunamis?]

- The Triassic Spearfish formation contains the Pine Salt Bed, some gypsum and highly oxidized sands and shales, found in modern arid environments, gypsum being an evaporitic mineral (Wilmarth, 1938, p. 2037). There are conglomerates in which the Mississippian rocks were deposited, hardened, then eroded and fragments deposited in the Spearfish redbeds. (Francis, 1956, p. 18)
__[How long does it take gypsum to dry out in air, or under overburden?]

- The early oceanic sediments are covered by desert deposits of the Prairie Evaporite, Interlake, and Minnelusa formations. Oncolites found in the Interlake prove that these deposits took some time to be deposited. There are 11 separate salt beds scattered through four ages: 2 Jurassic Salt beds, 1 Permian salt bed, 7 Mississippian salt beds, and one thick Devonian salt. Half of these salt beds are up to 200 feet thick. The top Mississippian salt is 96% pure sodium chloride! Since they are sandwiched between other sediments, to explain them on the basis of a global, one-year flood, requires a mechanism by which undersaturated sea water can dump its salt. If the sea were super-saturated during the flood, then no fish would have survived.
__[Would these salt deposits all be from undersea brine lakes?]

- The Minnelusa formation contains three features incompatible with the flood: dolomite with desiccation cracks; two anhydrite layers with a peculiar "chicken-wire" structure (Achauer, 1982, p. 195); cross-bedding identical to modern desert dunes; "chicken-wire" anhydrite only forms above 35 degree C. and near the water table (Hsu, 1972, p. 30). This type of anhydrite is deposited in the Persian Gulf area today.
__[Would a few weeks time between tsunamis be enough time to produce these effects?]

- The erosional layers and the evaporative salt requires much more time than a single year to account for the whole column.
__[Is that true?]

(10)Slow-Settling Particles
- The Bakken formation is an organic rich shale that required tranquil, even stagnant, oxygen-poor water.
__[Could enough stagnant water have been available between tsunamis to produce this organic matter?]

- The 200 feet of pure coccolith chalks of the Niobrara and the bentonite deposits also require a lot of time. A chalk particle, 2 microns in radius, takes about 80 days to fall through only 300 feet of very still water.
- Some of the smaller volcanic ash particles in the bentonites could take even longer to fall through 100 m in water than the coccoliths.
__[Would chalk or ash particles settle quickly if the water were saturated with them?]

A: http://creation.com/can-flood-geology-explain-thick-chalk-beds
- https://creation.com/images/pdfs/tj/j10_1/j10_1_107-113.pdf

- The Dakota formation has numerous borings, relatively pure volcanic ash layers (Lane, 1963, p. 229-256). If the ash layers occurred during a raging flood, they would have been thoroughly mixed with other sediment.
__[Was the ash sealed in by the shale layer above it?]

- The black shale with very small particle size requires quiet, tranquil waters for deposition.
__[JB says that is false.]

- The Ordovician Winnipeg formation is very similar to the Deadwood "suggesting that the Deadwood Sandstone may be a source for the Winnipeg Sandstone" (Bitney, 1983, p. 1330) by local erosion rather than a world wide catastrophe.
__[The two sandstones are 145 ft apart vertically. Would the two basal layers have been deposited by successive tsunamis?]

(11)Impact Signs vs Flood
- The Hell Creek formation is the last Cretaceous deposit. It has sands and shales, with dinosaurs and Cretaceous style mammals. And it contains the famous iridium anomaly from the K/T meteor impact. In 1984, the iridium in a 3 centimeter layer was about 12 nannograms / gram (ng/g) and in the other layers it was undetectable. Just below the iridium anomaly there is a ratio of 1 pollen grain to every fern spore. At the iridium anomaly, the angiosperm pollen practically disappears, the ratio being 100 fern spore to every angiosperm pollen grain, as if the angiosperm plants disappeared (Smit and Van der Kaars, 1984, p. 1177-1179). Why would a global flood cause fern/pollen and iridium to alter in a way that would mimic an asteroid impact? (Kamo and Krogh, 1995, p. 281-284; Nichols et al., 1986, p. 714-717)
__[Maybe there were impacts during the floods.]

(12)Fossils of Slow-Growing Trees
- The Fort Union formation is the first Tertiary deposit. It cannot be the flood deposit. It has standing fossilized tree stumps (Hickey, 1977, p. 10).
The Golden Valley Formation has tree trunk molds. This means that the trees had time to rot away before they were buried by the next layer, meaning that this layer took some time to be deposited. (Hickey, 1977, p. 68-72,90-92,168)
__[Didn't the roots break off in tsunamis?]

(13)Missing Sediments
- There is no sand, or shale [in a sequence], so it is hard to see how this could be the flood deposits.
__[Is it because tsunamis likely came from different directions at different times during the cataclysm, picking up & dropping different materials?]

Non-Flood Erosion
- The Devonian Dawson Bay formation is a carbonate which shows evidence of subaerial erosion (Pound, 1988, p. 879; Dunn, 1983, p. 79,85) which can't be created under flood waters.
__[Could the limestone have been eroded between tsunamis?]

- The Cambrian Deadwood Formation consists of a lower sandstone with scolithos burrows widely found in similar basal sandstones around the world.
__[- The Moine Thrust - http://www.see.leeds.ac.uk/structure/assyntgeology/classic/assynt_shore/prpipes.jpg
- Closely spaced Skolithos burrows of the Tumblagooda Sandstone can be up to 1 metre long
- http://www.dmp.wa.gov.au/Images/Community-Education/GSWA_Kalbarritracks_01_rdax_620x827.JPG ]
__[Definition of basal conglomerate. A well-sorted, lithologically homogeneous conglomerate that forms the bottom stratigraphic unit of a sedimentary series and that rests on a surface of erosion, thereby marking an unconformity; esp. a coarse-grained beach deposit of an encroaching or transgressive sea.]
__[Okay?]

-----

==2_ C14 Dating Diamonds
- D: why would anyone talk about carbon dating something like a diamond? That makes NO sense. It's ONLY useful for dating things that we know were once alive. It tells us with incredible accuracy, up to 50,000 years (with current precision of measurement but it may increase with newer technology), how long ago the living cells in a material stopped continually replenishing their C14 content, i.e. when they DIED. Based strictly on the carbon dating of formerly living things and disregarding mounds of other evidence, we know factually that there were living things walking the Earth 50,000+ years ago.

Erosion Rate & Seafloor Sediments
- Re: One of the best evidence is coastal and continental erosion. At the current rates of erosion the continents would all erode completely below sea level within 20 million years and the seafloors would have deep deposits of sediment. The seafloors have very little sediment.
- MS: That's completely incorrect.  Erosion rates are nowhere near high enough to do that.  And the seafloors are made up almost entirely of sedimentary rock, except in the tectonically-active areas where new rock is being formed by subsurface vulcanism.

Impact Overheating
- An impact strong enough to move the Americas by 2000 miles in a day would have turned the planet into a glowing cinder.  It wouldn't cause a "Great Flood," as there would be no water left.  Or air.  Or anything else, other than molten rock.  It would send so much crustal material into orbit that the resulting dead rock would have a ring system.  There's a good chance that the ring material would impact the moon, creating enough "drag" to slow its orbital speed to the point that it actually crashed back to Earth eventually, effectively destroying both bodies.

http://forum.freestateproject.org/index.php?topic=16789.msg294281#msg294281
- Those who do radioactive dating don't agree with your claims. 
- Erosion rates don't even vaguely approach what you've claimed. 
- Seafloors do have deep deposits of sediment. 
- And an impact that could move continents would have destroyed the planet, as far as it being anything approaching something that could have life (and could have actually physically destroyed the planet, turning it into an asteroid belt).
c
« Last Edit: February 19, 2017, 12:29:50 pm by Admin »

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Re: GM/Great Flood Critique
« Reply #1 on: February 03, 2017, 08:08:39 pm »
GM: The Talk.Origins Archive: Exploring the Creation/Evolution Controversy
http://www.talkorigins.org/faqs/geocolumn
The Geologic Column and its Implications for the Flood

Williston Basin
http://ndstudies.gov/energy/level2/files/level2/img/module02/williston-basin-x-sec-08-29-14.jpg

The Geologic Column in North Dakota

GM: The Talk.Origins Archive: Exploring the Creation/Evolution Controversy
http://www.talkorigins.org/faqs/geocolumn
The Geologic Column and its Implications for the Flood

- - We will now examine the strata that form the entire geological column which is found in North Dakota.
- - The Geologic Column in North Dakota
- - The Cambrian of this region consists of the ____Deadwood Formation.
- This formation consists of a lower ____sandstone with scolithus burrows (Wilmarth, Part 1, 1938, p. 578.).
- These scolithos burrows are widely found in similar basal sandstones around the world.
- They are found in Newfoundland, Scotland, Antarctica, Greenland always in Cambrian sands.
- Thus, the basal sandstone appears to have been the tranquil home for whatever animal made the scolithos burrows.
- Sedimentologically, these basal quartzites are nearly pure sand and must have taken a lot of time to winnow the shale out from them.
- It is unlikely that this winnowing could be accomplished in a yearlong flood with all its turbulence.
__[- The Moine Thrust - http://www.see.leeds.ac.uk/structure/assyntgeology/classic/assynt_shore/prpipes.jpg
- Closely spaced Skolithos burrows of the Tumblagooda Sandstone can be up to 1 metre long
- http://www.dmp.wa.gov.au/Images/Community-Education/GSWA_Kalbarritracks_01_rdax_620x827.JPG ]__
__[Definition of basal conglomerate. A well-sorted, lithologically homogeneous conglomerate that forms the bottom stratigraphic unit of a sedimentary series and that rests on a surface of erosion, thereby marking an unconformity; esp. a coarse-grained beach deposit of an encroaching or transgressive sea.]__
- There are some trilobites found in the Cambrian strata.
- - Above this is a ____black shale.

- Shale, due to the very small particle size requires quiet, tranquil waters for deposition to take place.
__[?JB says this is disproven.]

- This is one of the unrecognized difficulties of flood geology.
- Every shale, which is approximately 46% of the geologic column, is by its existence, evidence for tranquil waters.
- - Above this is the ____Ordovician Winnipeg formation.
- It consists of a ____basal sand whose lithology is very similar to that of the Deadwood scolithus sand, "suggesting that the Deadwood Sandstone may be a source for the Winnipeg Sandstone" (Bitney, 1983, p. 1330).
- This would mean that local erosion was the cause of the sand for the Winnipeg sand rather than a world wide catastrophe.
__[?Same source for 2 sandstone layers?]

- The Winnipeg does not have scolithus burrows.
- - Above this is the ____Icebox shale.
- Once again a shale requires still water for deposition.
- - Above this lies 1300 feet of ____Ordovician limestone and dolomite.
- These are the Red River, Stony Mountain and Stonewall formations, collectively known as the ____Bighorn Dolomite. (data from W. H. Hunt Trust Larson #1 well, Mckenzie Co., North Dakota)
- These can not be the flood deposits for reason of heat.
- Each gram of carbonate gives off about 1207 kilocalories per mole (Whittier et al, 1992, p. 576).
- Since the density of the carbonate is around 2.5 g/cc this means that there are 2.2 x 10^6 moles of carbonate deposited over each meter.
- Multiply this by 1,207,000 joules per mole and divide by the solar constant and you find that to deposit these beds in one year requires that the energy emitted by each meter squared would be 278 times that received by the sun.
- Such energies would fry everybody and everything.
__[?I don't understand what heat is produced by carbonate.]

- Besides, throughout these carbonates are layers upon layers of burrows (Gerhard, Anderson and Fischer, 1990, p. 513).
- These Ordovician carbonates also show interesting sedimentological features.
- Fossils include graptolites, gastropods, cephalopods, and corals.
- The Red River dolomite is burrowed by some type of animal (Kohm and Louden, 1983, p. 27).
- - Above the Ordovician carbonates lies the ____Silurian Interlake formation.
- This formation consists of ____carbonates, anhydrite, salt, with minor amounts of sand.
- Layers throughout this deposit are also burrows and mudcracks from drying out of the layers (Lobue, 1983, p. 36,37).
__[??Each megatsunami would come a few weeks apart, maybe enough time to form mudcracks.]

- There are also intact corals of a totally different type than are alive today.
- The Paleozoic corals [all] belong to one of three groups - only one of which is found in Mesozoic rocks; the other two became extinct at the end of the Paleozoic.
- The four-sided corals are only found in the Paleozoic.
- Modern corals of the 6-sided or 8-sided kind are not found until the Triassic.
__[??The lower corals may have been too thoroughly buried; the upper ones may have mutated from the lower via electrical effects during the cataclysm.]

- - Above this are the ____Devonian formations.
- The lower Devonian is the Winnepegosis formation and it consists of a bioclastic (meaning made up of the shells of dead carbonate producing animals) ____limestone, and the upper part is interbedded ____carbonate with anhydrite.
__[?Interbeds are all from the same time.]
 
- Mud cracks are also found as are burrows.(Perrin, 1983, p. 54, 57.)
- There is no sand, no shale so it is hard to see how this could be the flood deposits.
__[?Tsunamis likely came from different directions at different times during the cataclysm, picking up & dropping different materials.]

- Anhydrite is an evaporitic mineral and not compatible with a global flood.
- The next Devonian bed is the ____Prairie Evaporite.
- It consists of ____dolomite, salt, gypsum, anhydrite and potash.
- These are generally considered evaporitic and thus incompatible with deposition during a worldwide flood (Gerhard, Anderson and Fischer, 1990, p. 515).
__[??There were likely heat sources during the cataclysm & there may have been enough time between megatsunamis for significant evaporation.]

- There are also oncolites which are the spherically concentric carbonate depositions, due to algal growth on shells after the animals die.
- This takes time (Wardlaw and Reinson, 1971, p. 1762).
- An excellent example of an oncolite is shown in figure 58 of Dean and Fouch (1983, p. 123).
- It says: "Cross section of an oncolite developed around a gastropod-shell nucleus from Ore Lake, Michigan.
- Concentric layering is the result of annual couplets of porous and dense laminae.)
__[??Maybe there were beds of dead shells long before the tsunamis hit.]

- Fig. 59 is an example from the Eocene period.
- The ____Devonian Dawson Bay formation is a ____carbonate which shows evidence of subaerial erosion (Pound, 1988, p. 879).
- The evidence consists of eroded limestone horizons which can't be created under the ocean.
__[?Maybe the limestone was eroded between megatsunamis.]

- There is also salt cementation.
- This means that salt was deposited in the fractures and crevices in the rock.
- Halite plugged burrows are found.
__[??There's a brine lake under the Gulf of Mexico; maybe tsunamis carried such brine lake contents onto land.]

- Numerous erosional surfaces are found (Dunn, 1983, p. 79,85).
- Once again, hardly a result to be expected from the flood.
__[?There was likely a lot of erosion between successive tsunamis.]

- Next up is the ____Duperow formation.
- It also shows signs of subaerial erosion, salt deposition in the pores, ____anhydrite deposition.
- The deposition of these chemicals are more consistent with arid environments than with flood environments. (Dunn, 1974, p. 907).
__[Maybe the aridity occurred between successive tsunamis.]

- Burrows and stromatolites (limestone rocks deposited by daily increments of limestone [from] algae on a shallow (less than 30 feet) sea bottom. See Burke (1982, p. 554) and Altschuld and Kerr (1983, p. 104).
__[??*Need more info.]

- - Above this is the ____Birdbear formation with desiccation, ____caliche <mineral deposit of gravel, sand, and nitrates or area of calcium carbonate formed in semiarid soils> development (caliche is widespread in west Texas- a dry area) and burrows (Ehrets and Kissling, 1983, p. 1336; Halabura, 1983, p. 121).
- - Above this is the Threeforks shale.
- Once again, a shale requires quiet water to be deposited. (Wilmarth, 1938, part 2, p. 2144)
- The overlying Bakken formation is an organic rich shale.
- Tranquil, even stagnant-oxygen poor, water required.
__[??Maybe megatsunamis could provide such oxygen-poor water.]

- The ____Mississippian Madison group is probably my favorite deposit in the whole world.
- It largely consists of dead ____crinoid parts.
- In the Hunt Larson #1 well, it is 2200 feet thick.
- The following quote makes the problem with the Madison quite understandable (Clark and Stearn, 1960, pp. 86-88):
    The upper Mission Canyon formation (of the northwestern states and the Williston Basin) or the Livingstone formation (of Alberta) is more interesting, not only for its contribution to mountain scenery but also for its lithology and importance as an oil reservoir.
    Much of the massive limestone formation is composed of sand-sized particles of calcium carbonate, fragments of crinoid plates, and shells broken by the waves.
- Such a sedimentary rock qualifies for the name sandstone because it is composed of particles of sand size cemented together; because the term sandstone is commonly understood to refer to a quartz-rich rock, however, these limestone sandstones are better called calcarenites.
- The Madison sea must have been shallow, and the waves and currents strong, to break the shells and plates of the animals when they died.
- The sorting of the calcite grains and the cross-bedding that is common in this formation are additional evidence of waves and currents at work.
- Even in Mississippian rocks, where whole crinoids are rare fossils, and as a result it is easy to underestimate the population of these animals during the Paleozoic era.
- Crinoidal limestones, such as the Mission Canyon-Livingstone unit, provide an estimate, even though it be of necessity a rough one, of their abundance in the clear shallow seas they loved.
- In the Canadian Rockies the Livingstone limestone was deposited to a thickness of 2,000 feet on the margin of the Cordilleran geosyncline, but it thins rapidly eastward to a thickness of about 1,000 feet in the Front Ranges and to about 500 feet in the Williston Basin.
- Even though its crinoidal content decreases eastward, it may be calculated to represent at least 10,000 cubic miles of broken crinoid plates.
- How many millions, billions trillions of crinoids would be required to provide such a deposit?
- The number staggers the imagination.
>
- That is enough crinoids to cover the entire earth to a depth of 3 inches and yet this deposit is only a small part of a vast Mississippian crinoid bed that almost does cover the world (Morton, 1984, p. 26-27).
- These ____crinoidal limestones are called the Redwall in Arizona, the Leadville, in Colorado, the Rundle, in Canada, the Lisburne, in Alaska, the Keokuk and Burlington in the Mid-continent region of the U. S.
- Other crinoidal limestones are found in England, Belgium, European Russia, Egypt, Libya, central Asia, and Australia.
- How can the preflood world be covered in dead crinoids and still have room for people and the dinosaurs?
__[???Potential sources of the dead crinoids may be sea floors or continental shelves. They're smaller than a penny, so they may have flourished between tsunamis.]

- At the top of the Madison are ____karsts and occasionally, caverns due to subaerial erosion, with salt deposition etc.
- It is also heavily burrowed. Other fossils include half millimeter long scolecodonts, spores, coral, ostracods, gastropods and plants (Altschuld and Kerr, 1983, p. 106,107).
- - Above the Madison is the ____Big Snowy group.
- The lower part is composed of algal laminated ____dolomite with desiccation features.
- Intertidal channels are cut into this surface and are filled with sand. (Guthrie, 1985, p. 850)
- - Above this is the ____Minnelusa formation which contains three features which are incompatible with the flood.
- First there is a desiccated ____dolomite with desiccation cracks.
- Secondly, there are two ____anhydrite layers with a peculiar "chicken-wire" structure (Achauer, 1982, p. 195).
- Thirdly, the ____sands are cross-bedded in a fashion identical to modern desert dunes!
- The importance of these three features is that desiccation is not likely in a world wide flood, and "chicken-wire" anhydrite only forms above 35 degree C. and near the water table (Hsu, 1972, p. 30).
- This type of anhydrite is deposited in the Persian Gulf area today.
__[??Anhydrite near water table may need more info.]

- Fossils include brachiopods, cephalopods, gastropods, fish teeth, crinoids pelecypods.
- None of the Minnelusa beds are likely to be deposited under flood waters.
- - The ____Opeche shale is of ____Permian age and overlies the Minnelusa.
- The interesting thing about the Opeche is that in the center of the basin, at its deepest part, it is ____salt - 300 feet of salt.
- Permian pollen is found in the salt, modern pollen is not found (Wilgus and Holser, 1984, p. 765,766).
__[??Why no modern pollen? Why pollen in Precambrian?]

- This bed has the appearance of a period of time in which the Williston Sea dried up, leaving its salt behind in the deepest parts of the basin as would be expected.
- The area of salt deposition is 188,400 square kilometers. Assuming that over this area the salt averages half that 300 feet(91 m) or averages 45 meters, then this deposit represents 9 trillion cubic meters of salt!
- With a density of 2160 kg/m^3 this represents the evaporation of 845 million cubic kilometers of seawater.
- This is 1/14 of the world's ocean water.
- This is hardly something to be expected in a global flood.
__[???Need to determine how fast brine can dry out between tsunamis. Or could it concentrate under salty limestone, the next layer above?]

- - Above this is the ____Minnekahta limestone which was deposited in hypersaline waters.
- Hypersaline waters were not likely to be the flood waters which would have been brackish at worst due to the large influx of rainwater.
__[?Rainwater would not add much to the tsunamis.]

- - Next is the ____Triassic Spearfish formation.
- It contains the Pine ____Salt Bed, some gypsum and highly oxidized ____sands and ____shales.
- These red beds have the appearance of the deposits found in modern arid environments. Gypsum is an evaporitic mineral.
__[??More salt. Need to see how long it takes gypsum to dry out in air, or under overburden.]

- The Spearfish deposits have the appearance of modern deposits found on an arid intertidal flat.(Wilmarth, 1938, p. 2037)
- There are conglomerates in which the Mississippian rocks were deposited, hardened, then eroded and fragments deposited in the Spearfish redbeds. (Francis, 1956, p. 18)
- - The ____Jurassic Piper formation comes next.
- The lowest member is the Dunham ____salt (Gerhard,Anderson and Fischer, 1983, p. 529).
- Highly oxidized ____red beds, (normally marine deposits are dark, continental, subaerial deposits are reddish) with ____gypsum, an evaporitic bed lies above the salt (Peterson, 1958, p. 107).
- A small ____limestone followed by more ____redbeds and ____gypsum finishes the Piper formation.
- - The ____Rierdon formation is a set of interbedded marine and evaporitic rocks.
- Some times the ocean covered the area and then it was exposed long enough for ____gypsum and ____anhydrite and once again ____salt to be formed.
- Remember that it must be above 35 degree C [95F] for anhydrite to form.
- Ocean water is not often that hot.
- These beds are also very fossiliferous, containing pelecypods, ostracods, and foraminifera (Peterson, 1972, p. 178).
- This formation also contains oolitic ____limestones.
- Since oolites are formed from algal deposition of limestone, this bed requires some time.
__[??How much time did algae need to deposit this lime?]

- - The ____Jurassic Swift formation is predominantly ____shale in the lower part.
- Shale requires tranquil water for deposition.
- This shale has abundant belemnites, oysters and pelecypods. All oceanic creatures.
- These beds are above the terrestrial, salt depositing beds discussed previously.
- This oceanic deposit does not look like a flood deposit but the tranquil deposition from an ocean (Peterson, 1958, p.112).
__[???]

- - The upper ____Jurassic Continental Morrison formation is next.
- This is the bed with all the dinosaur bones.
- It extends from Canada to Arizona.
- It consists of ____sands and ____shales.
- It has footprints (Stokes, 1957, p. 952-954), fossil soil profiles (Mantzios, 1989, p. 1166), mammals, plants, some coal (Brown, 1946, p 238-248).
- Both the mammals and plants are different from anything alive today.
- Huge dinosaurs, as well as smaller ones are found here.
__[??Why no modern mammals & plants? They became extinct it seems.]

- - The ____Cretaceous begins with the ____Dakota Group.
- Unique ammonites mark each of the beds in the Cretaceous.
- The Dakota also is formed of ____sand and ____shales with ____lignite (Bolyard, 1965, p. 1574).
- Parts of this group have ripple marks, burrows, animal tracks, worm trails.
- The deposits are interpreted as being formed by a delta (Bolyard and McGregor, 1966, p. 2221-2224).
- The Dakota formation has numerous channels eroded into underlying strata.
- Some of these channels are 30 feet deep.
- There are numerous borings, ____volcanic ash layers, in which the ash is relatively pure.
- If the volcanoes which produced these ash layers occurred during a raging flood, the ash would have been thoroughly mixed with other sediment. - They aren't.
__[??Was the ash sealed in by shale?]

Plant fragments are found throughout the strata (Lane, 1963, p. 229- 256)
- - The ____Belle Fourche shale is next.
- As mentioned many times previously, due to small particle size, a shale needs tranquil water.
- There is a ____bentonite (volcanic ash) bed near the base which would be mixed in with other sediments if it were laid down in a raging flood.
- - Above this is the ____Greenhorn limestone.
- The limestones are made mostly of coccoliths, small skeletal remains approximately 3-5 micrometers in diameter.
- This formation is about 40 ft thick and consists of 16 ledge-forming, burrowed limestone beds separated by thin shales.
- Over a distance of 450 miles the ledges lie on and below persistent bentonite (volcanic ash beds).
- The parallelism proves that the ledges are synchronous across their extent.
- The coccoliths had to grow in the water, and then die and fall to the bottom.
- After this, organisms had to burrow into the sediment.
- When the coccoliths were not as productive in the waters above, ____shale was deposited, separating the limestone beds.
- All of this required still water.
__[??]

- there are also abundant fecal pellets in this deposit as well as burrows and feeding traces (marks an animal makes on the sediment when he is feeding) (Hattin, 1971, p. 412-431; Savrda and Bottjer, 1993, p. 263-295).
- - The ____Cretaceous Carlile shale lies above the Greenhorn.
- It consists of ____sands and ____shales.
- There are erosional channels, burrows, feeding markings.
- Shark teeth and bones are found.
- A shark during its lifetime sheds numerous teeth which fall to the ocean floor to be buried (McLane, 1982, p. 71-90).
- - The ____Niobrara Chalk is next.
- It too is made up largely of coccoliths, has abundant fecal pellets, which are made of the eaten remains of coccoliths.
- Whatever fish dined on the plankton, let their presence be known by leaving their droppings.
- More than 100 bentonite beds are found throughout the formation.
- Fish bones and scales are found throughout the formation.
- The fossils of the Niobrara are quite interesting.
- There is a 14-foot Portheus (fish) which apparently died after trying to digest a smaller 6-foot fish.
- Skulls of the giant marine lizard Tylosaurus was found.
- Pterodactyls have also been recovered from this bed (Stokes and Judson, 1968, p. 372,377,379).
- Sediment filled burrows occur rarely in the bed (Hattin, 1981, p. 831- 849).
>
- But what has recently come to my attention is that Fourier analysis of the Niobrara laminations reveals that the laminations vary in thickness according to the periodicities of the orbital cycles.
- If this bed were deposited in a two day time frame required by the assumption of a global deluge, there is absolutely no reason to find orbital periodicities in this rock (Fischer, 1993, p. 263-295).
__[??Which orbital cycles? Day? Moon? Year?]

- - The ____Pierre shale is rich in organic matter and it is almost entirely contained in the fecal pellets.
- Marine reptile bones are concentrated in the ____Sharon Springs member.
- Note in all the above, that the fossils are not sorted as Morris would assume by ecological zonation.
__[??Non-ecological fossil sorting?]

- This marine bed is above the Morrison bed which contains the dinosaurs (Parrish and Gautier, 1988, p. 232).
- There is also the ____Monument Hill Bentonite which is 150-220 feet thick and represents one heck of a volcanic eruption.
- Above this is another ____bentonite, the Kara, which is 100 feet thick.
- Mt. St. Helens pales by comparison (Robinson, et al., 1959, p. 109).
- - The ____Fox Hills formation is next.
- It is ____sands, ____shales, ____coal and ____limestone.
- It contains coal, root casts, Ophiomorpha (a crab) burrows, dinosaur bones, turtle plates, shark teeth, and erosional channels over 120 feet deep.
- There is a fossil clam bed (Pettyjohn, 1967, p. 1361-1367).
- - The ____Hell Creek formation is the last Cretaceous deposit.
- It tells one of the most interesting stories of any of the beds in the column.
- Other than the types of animals found in it, it looks just like the Ft. Union discussed below (McGookey, et al, 1972, p. 223).
>
- The Hell Creek section is formed of ____sands and ____shales, with many, many meandering channels incised into it.
- The fauna found in it consists of dinosaurs and Cretaceous style mammals.
- The highest dinosaur layer is at the top of this section.
>
- The Hell Creek section contains the famous iridium anomaly from the K/T meteor impact.
- In 1984, the iridium in a 3 centimeter layer was about 12 nannograms / gram (ng/g) and in the other layers it was undetectable.
- Extremely few dinosaur remains or Cretaceous style mammals are found above the iridium anomaly and only in the lowest layers of the Fort Union formation.
>
- They are believed to be eroded and re-deposited material.
>
- A look at the pollen/spore record reveals an interesting pattern also.
- Just below the iridium anomaly there is a ratio of 1 pollen grain to every fern spore.
- At the iridium anomaly, the angiosperm pollen practically disappears, the ratio being 100 fern spore to every angiosperm pollen grain.
- It is as if the angiosperm plants disappeared.
- Several taxa of angiosperm pollen disappear at the iridium anomaly (Smit and Van der Kaars, 1984, p. 1177-1179).
- The stratigraphically equivalent strata in Saskatchewan and New Mexico also shows the iridium anomaly and the quantity of angiosperm pollen is severely decreased relative to the spores of ferns.
>
- The question is why would a global flood cause fern/pollen and iridium to alter in a way that would mimic an asteroid impact? (Kamo and Krogh, 1995, p. 281-284; Nichols et al., 1986, p. 714-717)
__[?Maybe there were impacts during the floods.]

- - The ____Fort Union formation is the first ____Tertiary deposit.
- It also cannot be the flood deposit.
- It consists of ____shale, ____sandstone, and ____conglomerate.
- The fossils consist of marsupials, a bat, the earliest monkeys, the earliest ungulates, alligator, root casts, erosional channels, fossil leaves, spore and pollen (Keefer, 1961, p. 1310-1232).
- Animal burrows are quite common as are minerals deposited in poorly drained swamps, e.g. pyrite and siderite (Jackson, 1979, p. 831-832).
- It also has standing fossilized tree stumps (Hickey, 1977, p. 10).
- - The ____Golden Valley Formation is made of two layers, a hard kaolinitic ____claystone and an upper member made of ____sandstone lenses interspersed with parallel bedding made from finer grained material as well as numerous incised channels cutting through the section.
- This bed contains a unique plant fossil Salvinia preauriculata.
- The list of plants remains found is quite long.
- The animals include fish, amphibians, reptiles (4 species of crocodile), mammals such as five genera of insectivores, three primates, rodents, a pantodont, an allothere, Hyracotherium, which is the ancestor of the horse, and an artiodactyl.
- Fresh water mollusks, and two species of insects are also found.
- There are also tree trunk molds.
- This means that the trees had time to rot away before they were buried by the next layer, meaning that this layer took some time to be deposited. (Hickey, 1977, p. 68-72,90-92,168)
__[?The roots didn't rot away, they broke off in tsunamis.]

- - The rest of the Tertiary consists of sediments like the Golden Valley followed by a ____gravel bed and topped by ____Glacial tills.
- - The W. H. Hunt Trust Estate Larson #1 well in Section 10 Township 148 N Range 101 W was drilled to 15,064 feet deep.
- This well was drilled just west of the outcrop of the Golden Valley formation and begins in the Tertiary Fort Union Formation.
- The various horizons described above were encountered at the following depths (Fm=formation; Grp=Group; Lm=Limestone):

    Tertiary Ft. Union Fm ..........................100 feet
    Cretaceous Greenhorn Fm .......................4910 feet
    Cretaceous Mowry Fm........................... 5370 feet
    Cretaceous Inyan Kara Fm.......................5790 feet
    Jurassic Rierdon Fm............................6690 feet
    Triassic Spearfish Fm..........................7325 feet
    Permian Opeche Fm..............................7740 feet
    Pennsylvanian Amsden Fm........................7990 feet
    Pennsylvanian Tyler Fm.........................8245 feet
    Mississippian Otter Fm.........................8440 feet
    Mississippian Kibbey Lm........................8780 feet
    Mississippian Charles Fm.......................8945 feet
    Mississippian Mission Canyon Fm................9775 feet
    Mississippian Lodgepole Fm....................10255 feet
    Devonian Bakken Fm............................11085 feet
    Devonian Birdbear Fm..........................11340 feet
    Devonian Duperow Fm...........................11422 feet
    Devonian Souris River Fm......................11832 feet
    Devonian Dawson Bay Fm........................12089 feet
    Devonian Prairie Fm...........................12180 feet
    Devonian Winnipegosis Grp.....................12310 feet
    Silurian Interlake Fm.........................12539 feet
    Ordovician Stonewall Fm.......................13250 feet
    Ordovician Red River Dolomite.................13630 feet
    Ordovician Winnipeg Grp.......................14210 feet
    Ordovician Black Island Fm....................14355 feet
    Cambrian Deadwood Fm..........................14445 feet
    Precambrian...................................14945 feet

- - Conclusion - What does all this mean?

    First, as I have noted before, the concept quite prevalent among some Christians that the geologic column does not exist is quite wrong. Morris and Parker (1987, p. 163) write:

        Now, the geologic column is an idea, not an actual series of rock layers. Nowhere do we find the complete sequence.

    They are wrong.
- - You just saw the whole column piled up in one place where one oil well can drill through it.
- Not only that, the entire geologic column is found in 25 other basins around the world, piled up in proper order.
- These basins are:
        The Ghadames Basin in Libya
        The Beni Mellal Basin in Morrocco
        The Tunisian Basin in Tunisia
        The Oman Interior Basin in Oman
        The Western Desert Basin in Egypt
        The Adana Basin in Turkey
        The Iskenderun Basin in Turkey
        The Moesian Platform in Bulgaria
        The Carpathian Basin in Poland
        The Baltic Basin in the USSR
        The Yeniseiy-Khatanga Basin in the USSR
        The Farah Basin in Afghanistan
        The Helmand Basin in Afghanistan
        The Yazd-Kerman-Tabas Basin in Iran
        The Manhai-Subei Basin in China
        The Jiuxi Basin China
        The Tung t'in - Yuan Shui Basin China
        The Tarim Basin China
        The Szechwan Basin China
        The Yukon-Porcupine Province Alaska
        The Williston Basin in North Dakota
        The Tampico Embayment Mexico
        The Bogata Basin Colombia
        The Bonaparte Basin, Australia
        The Beaufort Sea Basin/McKenzie River Delta
    (Sources:
    Robertson Group, 1989;
- http://www.talkorigins.org/faqs/geocolumn/#ref-robertson
    A.F. Trendall et al , editors, Geol. Surv. West. Australia Memoir 3, 1990, pp 382, 396;
- http://www.talkorigins.org/faqs/geocolumn/#ref-trendall
    N.E. Haimla et al, The Geology of North America, Vol. L, DNAG volumes, 1990, p. 517)
- http://www.talkorigins.org/faqs/geocolumn/basin3.gif
    T. Moore's Map
    (Figure courtesy of Thomas Moore)
- - Second, the existence of desert deposits is quite hard to place in the context of a global flood.
- Morris and Morris (1989, p. 37) write:
- http://www.talkorigins.org/faqs/geocolumn/#ref-morris89
        If real desert-formed features do exist in the deeper geologic deposits, this could indeed be a problem for the Biblical model since the antediluvian environment was said by God to be all 'very good' and the future promised restoration of these to good conditions to the earth includes desert reclamation (e.g. Isaiah 35).
>
    The early oceanic sediments are covered by desert deposits of the Prairie Evaporite, Interlake, and Minnelusa formations. Oncolites found in the Interlake prove that these deposits took some time to be deposited. There are 11 separate salt beds scattered through four ages: 2 Jurassic Salt beds, 1 Permian salt bed, 7 Mississippian salt beds, and one thick devonian salt. Half of these salt beds are up to 200 feet thick. The top Mississippian salt is 96% pure sodium chloride! Since they are sandwiched between other sediments, to explain them on the basis of a global, one-year flood, requires a mechanism by which undersaturated sea water can dump its salt. If the sea were super-saturated during the flood, then no fish would have survived.
__[?]

- - Third, the geologic column is not divided by hydrodynamic sorting.
__[?]

 Whitcomb and Morris (1961, p. 276) write:
- http://www.talkorigins.org/faqs/geocolumn/#ref-whitcomb
        In general, though, as a statistical average, beds would tend to be deposited in just the order that has been ascribed to them in terms of the standard geologic column. That is on top of the beds of marine vertebrates would be found amphibians, then reptiles and finally birds and mammals. This is in the order: (1) of increasing mobility and therefore increasing ability to postpone inundation; (2) of decreasing density and other hydrodynamic factors tending to promote earlier and deeper sedimentation, and (3) of increasing elevation of habitat and therefore time required for the Flood to attain stages sufficient to overtake them.
    The biggest single factor for how fast an object settles in a fluid is the size. The relevant physical law is Stoke's Law. The larger an object, the faster it falls. A cat can survive a fall from a 20 story building because it falls at a speed of only 60 mph. A human dies because he reaches a terminal velocity of 120 mph if laid out like a skydiver, 180 if He falls feet first. Thus for any given habitat, the largest animals should be on the bottom. There are a lot of very small dinosaurs found in the Morrison formation, with the giants, both of which are below the Niobrara which contains the 20 foot long fish and micrometer sized chalk particles. Large, teleost fish are found well above the layers in which fish are first found.
- - Fourth, the geologic column is not sorted be ecological zones.
- The Silurian Interlake, Devonian Prairie, Pennsylvanian Minnelusa and Jurassic Morisson formations are continental deposits.
- Oceanic deposits sandwich these beds.
- The ocean came and went many times.
__[?As in megatsunamis.]

- - Fifth, the persistent burrowing which is found throughout the geologic column, the erosional layers and the evaporative salt requires much more time than a single year to account for the whole column.
__[?How many years?]

- Here is how I know the Williston Basin sediments couldn't be deposited in a single year.
- 15,000 feet divided by 365 days equals 41 feet per day.
- Assuming that a burrow is only 1 foot long and that the creature could not survive the burial by an additional foot of sediment, the creature doing the burrowing must accomplish his work in less than 40 minutes.
- That doesn't sound all that bad, until it is realized that if the poor critter ever stops to rest, even for a half an hour, he will be buried too deeply to escape.
- - The pure coccolith chalks of the Niobrara and the bentonite deposits also require a lot of time.
- A chalk particle, 2 microns in radius, takes about 80 days to fall through only 300 feet of very still water.
__[?Depends how saturated the water is.]

- The 200 feet of the Niobrara Chalk would have to be deposited in 4 days if the column was the result of a 1- year flood.
- The detection of long-period cyclicities in the Niobrara which match those of the earth's long-term orbital periodicities must cause one to pause and think about the concept that the geologic column is due to a single cataclym.
- Some of the smaller volcanic ash particles in the bentonites could take even longer to fall through 100 m in water than the coccoliths.
__[?Saturation?]

- - Sixth, the fact that the fossil mammals are not found with the earliest dinosaurs, or that no primates are found until the Ft. Union formation or that no full dinosaur skeletons are found in the Tertiary section, implies strongly that the column was not the result of a single cataclysm.
- Worldwide, no whales are found with the large Devonian fish.
- If the column was an ecological burial pattern, then whales and porpoises should be buried with the fish. They aren't.
__[?]

- The order of the fossils must be explained either by progressive creation or evolution.
- - Seventh, until Christian catastrophists can explain the facts of the geologic column, they need to tone down their rhetoric against the geologist and other scientists.
- Paul Steidl (1979, p. 94) wrote:
http://www.talkorigins.org/faqs/geocolumn/#ref-steidl
        The entire scientific community has accepted the great age of the universe; indeed, it has built all its science upon that supposition. They will not give it up without a fight. In fact, they will never give it up, even if it means compromising their reason or even their professional integrity, for to admit creation is to admit the existence of the God of the Bible.
    Geology, like any science, is not immune from criticism. but Christians who criticize geology should do so only after a thorough understanding of the data, not as is usually the case before such an understanding is gained. They should also be willing to advance explanations for explaining the details observed.
- - Eighth, those who would decry the use of uniformitarianism in the interpretation of the fossil record need to show how uniformitarian methodology is inappropriate when one looks at the persistent burrowing, the orbital cyclicities, the abundant erosional surfaces and footprints.
- They also need to show why the laws of physics (Stokes law) does not apply to the deposition of 2 micron chalk particles, and demonstrate what laws do apply in order to explain the supposed rapid sedimentation of these beds.
- - Ninth and finally, the data shows that there is no strata which can be identified as the flood strata and there is no way to have the whole column be deposited in a single year.
__[?How many years?]

References:

    Altschuld, N., and S. D. Kerr, 1983. "Mission Canyon and Duperow Reservoirs" in J. E. Christopher and J. Kaldi, editors, 4th International Williston Basin Symposium. Special Publication No. 6, Saskatchewan Geological Society, pp. 103-112.

    Achauer, C. W., 1982. "Sabkha Anhydrite: The Supratidal Facies of Cyclic Deposition in the Upper Minnelusa Formation (Permian) Rozet Fields Area, Powder River Basin, Wyoming" in Depositional and Diagenetic Spectra of Evaporites, SEPM Core Workshop No. 3 Calgary Canada, June 26-27, 1982. pp. 193-209.

    Bitney, Mary, 1983. "Winnipeg Formation (Middle Ordovician), Williston Basin" AAPG Bulletin, August, p. 1330.

    Bolyard, D. W., 1965. "Stratigraphy and Petroleum Potential of Lower Inyan Kara Group in Northeastern Wyoming, Southeastern Montana, and Western South Dakota" AAPG Bulletin, p. 1574.

    Bolyard, D. W. and Alexander A. McGregor, 1966. "Stratigraphy and Petroleum Potential of Lower Cretaceous Inyan Kara Group in Northeastern Wyoming, Southeastern Montana, and Western South Dakota" in AAPG Bulletin, Oct. 1966, pp. 2221-2244

    Brown, R. W., 1946 "Fossil Plants and Jurassic-Cretaceous Boundary in Montana and Alberta" in AAPG Bulletin, pp. 238-249.

    Burke, Randolph B., 1982. "Facies, Fabrics, and Porosity, Duperow Formation (Upper Devonian) Billings Nose Area, Williston Basin, North Dakota" in AAPG Bulletin, p. 554.

    Clark, Thomas H., and Colin W. Stearn, 1960. The Geological Evolution of North America, (New York: The Ronald Press).

    Dean, Walter E., and Thomas D. Fouch, 1983. "Lacustrine Environments" pp. 98-130, in Scholle, Peter A., Don G. Bebout and Clyde H. Moore, Editors, 1983. Carbonate Depositional Environments, AAPG Memoir 33, (Tulsa: Amer. Assoc. Petrol. Geol.)

    Dunn, C. E. 1974. "Upper Devonian Duperow Sedimentary Rocks in SE Saskatchewan. Why no Oil Yet?" in AAPG Bulletin, May, 1974, p. 907.

    Dunn, C. E., 1983 "Geology of the Middle Devonian Dawson Bay Formation" in J. E. Christopher and J. Kaldi, editors, 4th International Williston Basin Symposium. Special Publication No. 6, Saskatchewan Geological Society, pp. 75-88.

    Ehrets., J. R. and Don L. Kissling, 1983. "Depositional and Diagenetic Models for Devonian Birdbear (Nisku) Reservoirs, NE Montana" in AAPG Bulletin, p. 1336.

    Fischer, A. G., 1993, "Cyclostratigraphy of Cretaceous Chalk-Marl Sequences" in Evolution of the Western Interior Basin, (GAC Special Paper No. 39, 1993) pp. 263-295 cited in Petroleum Abstracts, 35:12, March 25, 1995, p 1001.

    Francis, David R., 1956. Jurassic Stratigraphy of the Williston Basin Area, Report No. 18, Saskatchewan Department of Mineral Resources.

    Gerhard, Lee C., Anderson, Sidney B., and Fischer, David W., 1990. "Petroleum Geology of the Williston Basin" in Morris Leighton et al, Interior Cratonic Basins, AAPG Memoir 51 (Tulsa: AAPG), pp. 507-559.

    Guthrie, Gary E., 1985. "Stratigraphy and Depositional Environment of Upper Mississippian Big Snowy Group, Bridger Range Montana" in AAPG Bulletin, p. 850.

    Halabura, S., 1983. "Depositional Environments of the Upper Devonian Birdbear" in J. E. Christopher and J. Kaldi, editors, 4th International Williston Basin Symposium. Special Publication No. 6, Saskatchewan Geological Society, pp. 113-124

    Hattin, Donald E., 1971. "Widespread Synchronously deposited, Burrow-mottled Limestone Beds, Greenhorn Limestone of Kansas and Southeastern Colorado" in AAPG Bulletin, pp. 412-431.

    Hattin, D. E., 1981 "Petrology Smoky Hill member, Niobrara Chalk, in Type Area, Western Kansas" in AAPG Bulletin, pp. 831-849.

    Hickey, Leo J., 1977. Stratigraphy and Paleobotany of the Golden Valley Formation of Western North Dakota, (Washington: Geological Society of America)

    Hsu, Kenneth, 1972. "When the Mediterranean Dried Up" in Scientific American, Dec. 1972, pp. 26-36.

    Kamo, Sandra L. and Thomas E. Krogh, 1995. "Chicxulub Crater Source for Shocked Zircon Crystals from the Cretaceous-Tertiary Boundary Layer, Saskatchewan: Evidence from New U-Pb data" in Geology pp. 281-284.

    Keefer, W. R., 1961. "Waltman Shale and Shotgun members of Ft. Union Formation Wyoming" in AAPG Bulletin, pp. 1310-1323

    Kohm, J. A., and R. O. Louden, 1983. "Ordovician Red River of Eastern Montana and Western North Dakota" in J. E. Christopher and J. Kaldi, editors, 4th International Williston Basin Symposium. Special Publication No. 6, Saskatchewan Geological Society, pp. 27-29.

    Jackson, T. J., Frank G. Ethridge, and A. D. Youngberg, 1979, "Flood-plain Sequences of Fine-Grained Meander-Belt System, Lower Wasatch and Upper Fort Union Formations, Central Powder River Basin" in AAPG Bulletin, pp. 831-832.

    Lane, D. W., 1963. "Sedimentary Environments in Dakota Sandstone" in AAPG Bulletin, pp. 229-256.

    Lobue, C. 1983. "Depositional environments and Diagenesis of the Silurian Interlake Formation Williston Basin W. North Dakota" in J. E. Christopher and J. Kaldi, editors, 4th International Williston Basin Symposium. Special Publication No. 6, Saskatchewan Geological Society, pp. 29-42.

    Mantzios, Christos, 1989. "Significance of Paleosols in Alluvial architecture: Example from Upper Jurassic Morrison Formation, Colorado Plateau)" in AAPG Bulletin, Sept., 1989, p. 1166.

    McBride, Earle F., 1969. "Stratigraphy and Sedimentology of the Haymond Formation" in Earle F. McBride, Stratigraphy, Sedimentary Structures and Origin of Flysch and Pre-Flysch Rocks, Marathon Basin, Texas (Dallas: Dallas Geological Society), pp. 86-92.

    McGookey, Donald P. et al., 1972. "Cretaceous" in Geologic Atlas of the Rocky Mountain Region, pp. 190-232.

    Mclane, M. 1982. "Upper Cretaceous Coastal Deposits in South Central Colorado - Codell and Juana Lopez members of Carlile shale" in AAPG Bulletin, pp. 71-90.

    Morris, Henry M. and Gary Parker, 1987. What is Creation Science? (San Diego: Creation-Life Publishers).

    Morris, Henry M., and John Morris, 1989. Science, Scripture, and the Young Earth. (El Cajon: ICR).

    Morton, G. R. 1984, "Global, Continental and Regional Sedimentation Systems and their Implications" in Creation Research Society Quarterly, June, 1984, pp. 23-33.

    Nichols, D. J. et al, 1986. "Palynological and Iridium Anomalies at Cretaceous-Tertiary Boundary, South-Central Saskatchewan" in Science, 231, pp. 714-717.

    Parrish, Judith T. and Donald L. Gautier, 1988. "Upwelling in Cretaceous Western Interior Seaway: Sharon Springs Member, Pierre Shale" in AAPG Bulletin, pp. 232-233.

    Perrin, N. A., 1983. "Environment of Deposition and Diagenesis of the Winnipegosis formation", in J. E. Christopher and J. Kaldi, editors, 4th International Williston Basin Symposium. Special Publication No. 6, Saskatchewan Geological Society, pp. 51-66.

    Peterson, J. A. 1958. "Marine Jurassic of Northern Rocky Mountains" in A. J. Goodman, editor, Jurassic and Carboniferous of western Canada, (Tulsa: AAPG)

    Peterson, J. A., 1972. "Jurassic System" W. W. Mallory, editor, Geologic Atlas of the Rocky Mountain Region. Denver: Rocky Mountain Association of Geologists, pp. 177-189.

    Pettyjohn, W. A., 1967. "New Members of Upper Cretaceous Fox Hills Formation in South Dakota" in AAPG Bulletin, pp. 1361-1367.

    Pound, Wayne, 1988. "Geology and Hydrocarbon Potential of Dawson Bay Formation Carbonate Unit( Middle Devonian), Williston Basin, North Dakota" in AAPG Bulletin, p. 879.

    Robertson Group, 1989. Stratigraphic Database of Major Sedimentary Basins of the World. (Llandudno Gwynedd, England: The Robertson Group)

    Robinson, C. S., W. J. Mapel, and W. A. Cobban, 1959. "Pierre Shale along Western and Northern Flanks of Black Hills, Wyoming and Montana" in AAPG Bulletin, pp. 101-123.

    Smit, J. and S. van der Kaars, 1984. "Terminal Cretaceous Extinctions in the Hell Creek Area Montana: Compatible with Catastrophic Extinctions" in Science, 223, pp. 1177-1179.

    Paul M. Steidl, Paul M., 1979. The Earth, The Stars,and The Bible. (Phillipsburg: Presbyterian and Reformed).

    Stokes, W. L., 1957. "Pterodactyl Tracks from Utah" in Journal of Paleontology, pp. 952-954 reprinted in William A. S. Sarjeant, 1983. Terrestrial Trace Fossils, (Stroudburg: Hutchinson Ross Publishing Co.

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Re: GM/Great Flood Critique
« Reply #2 on: February 05, 2017, 09:42:45 am »
Mike, thanks for the comments and links. 3 days ago I posted this on the TB forum:
BASINS SUPPORT RAPID DEPOSITION
That is something Berthault's experiments apparently showed. When tsunamis deposit strata they separate the strata according to grain size etc. Since they are deposited simultaneously in a megasequence they form curved strata in basins. The curves of the strata nearly follow the curves of each basin surface, except that each stratum is a bit thicker at the bottom than on the sides, like this: http://www.fortunebay.org/wp-content/uploads/2016/03/michiganbasin-cross-big.jpg . If strata formed in continental shallow seas, they should have formed at river deltas as sloped fans, like this http://www.scielo.cl/fbpe/img/andgeol/v36n1/fig05-10.jpg and http://www.scielo.cl/fbpe/img/andgeol/v36n1/fig05-09.jpg . Or if frequent tremors or tides or something caused the sediments to spread out across the floor of a shallow sea, the sediments should go to the bottom as flat layers, like this http://images.slideplayer.com/5/1507022/slides/slide_12.jpg .
- So I agree that the broad horizontal lateral extent of strata support very large tsunamis as the cause of deposition. If erosion into shallow seas were true, there should only be fan shaped strata and they shouldn't be separated into individual rock types, since there would not have been pure lime regions being eroded for thousands of years followed by similar periods of clay erosion and sand erosion. I think those are among the strongest arguments against gradualism.
- Last night I posted this on the TB forum:
Igneous Origin of Salt
I just made a good find on salt. See the 20 min. video, PRIMARY IGNEOUS ORIGIN OF SALT FORMATIONS, at http://youtube.com/watch?v=MfN0MIOnRNQ . It's just in time to answer most of the next bunch of claims against the Great Flood. The host of the video also authored a good paper, which I posted on my forum at http://funday.createaforum.com/1-10 .
- Mike, we're lucky to have critiques of the Great Flood posted online. Those seem likely to be the reasons the NCGT members support the conventional gradualist timeline. Of course, radiometric dating methods are probably their main reason for supporting it, but I think we have abundant evidence against it. So I look forward to getting all the main pro and con arguments listed coherently and organized into a good scientific format.

--------------------------------------------

On Sat, 2/4/17, mike@newgeology.us <mike@newgeology.us> wrote:
Subject: RE: Critique Questions
It is typical of anti-creationists and other propagandists to throw up a flurry of arguments loaded with assertions to give their bluster an "overwhelming" appearance.  The certainty of the claims in the list you posted is unfounded.  For most, either the conditions of deposition stated are not the only possibilities, or not enough is understood about them.  For example, until recently shale and other mudstones, which comprise over 60% of the geologic column, were thought to require quiet environments to form.  The 2009 reference I sent you demonstrates that they can form in moving water as well  Schieber, J., and J. B. Southard (2009), Bedload transport of mud by floccule ripples - Direct observation of ripple migration processes and their implications, Geology, 37(6), 483-486, doi:10.1130/G25319A.1.  Salt beds in the geologic column are extremely pure compared to evaporites being formed today, as described here:  http://www.icr.org/article/does-salt-come-from-evaporated-sea-water/  And how dolomite is formed, especially in depth, remains unsolved.  It is apparent that conditions today differ from those in place when most of the geologic column was laid down.  The huge geographic extent of many strata and the dearth of erosional interfaces suggests large scale, at least regional catastrophic deposition mechanisms.
- Don't forget the bizarre uniformitarian explanation for many deposits - rising and falling landmasses and sea levels depositing the same material over the same unchanged areas over millions of years.  There is no indication of this happening today outside of small local environments.  Note that in Shock Dynamics geology, all Cenozoic sedimentary strata formed hundreds of years after the Noahic Flood during the SD event.
- Compression built virtually all mountain chains, and rapid compression of continental crust, as in SD, would likely have had a substantial global piezoelectric electromagnetic effect.  I don't see it being associated with radiation, though.

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Subject: Critique Questions
Date: Fri, February 03, 2017 10:20 pm
- I analyzed a long critique of the Great Flood and sorted it into 12 claims, along with my questions for each claim about what might be answers to them. I didn't number all of the claims, because some are closely related. I posted them here: http://funday.createaforum.com/1-10/1-62/msg90/#msg90
- If you have answers to any of them, feel free to let me know. Otherwise, I'll eventually try to find answers for them myself, at least for the most important ones. I arranged the most important ones first.
- Some of the claims refer to the impossibility of high amounts of salt in sediments drying out quickly enough and of high concentrations in the ocean being deadly for all life there. I was thinking maybe there were more submarine brine lakes like the one in the Gulf of Mexico, which got washed ashore in some of the tsunamis.
- A claim about carbonates giving off too much heat is hard for me to understand. Maybe you would understand it.
- I posted more material on my forum lately, like Walter Brown's info about electrical effects, lineaments, radioactivity etc at LK2. I found a map of lineaments online that seems pretty detailed. The lines on it on the Atlantic coasts of Africa and South America look like they could have formed when the Madagascar strip connected to South America started peeling away from Africa. I think there would have been really strong electric currents under the continents as they slid apart and they could have produced the radioactivity, some of which was injected vertically under mountain ranges in granite intrusions etc. There probably was a lot of supercritical water too, like Brown thought, but not nearly as much. He claimed that it shot into the upper atmosphere and came down in Siberia as rock ice, which would have been cold enough to freeze mammoths to -150F.

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Re: GM/Great Flood Critique
« Reply #3 on: January 07, 2020, 10:38:39 am »
Critique (from first post above)
http://www.asa3.org/ASA/education/origins/agescience2.htm
Complete Geologic Column
http://www.talkorigins.org/faqs/geocolumn/basin3.gif

MAJOR WORLD BASINS:
AFRICA: BeniMellal (Morocco), Tunisian, Ghadames (Libya), WesternDesert (Egypt); EURASIA: Adana+Iskenderun (Syria), MoesianPlatform (Greece), Carpathian (E.Europe), Baltic, Yazd-Kerman-Tabas (Iran), OmanInterior, Farah+Helmand (Afghanistan), Jiuxi (NW.China), Yeniseiy-Khatanga (N.Siberia), Tarim+Manhal-Subel+Tung-t'in-YuanShul+Szechwan E.China); AUSTRALIA: Bonaparte (N.Australia); S.AMERICA: Bogata (Colombia); N.AMERICA: TampicoEmbayment (E.Mexico), Williston (NC.U.S.), BeaufortSea+Yukon-Porcupine (Yukon)
« Last Edit: January 07, 2020, 10:42:18 am by Admin »