otseng wrote:micatala wrote:Obviously, if Austin wanted a sample that only represented the material that solidified during the 1986 eruption, he would have had to remove ALL of the plagioclase and other phenocrysts from the glass component. Even when phenocrysts (as in Austin's Figure 4) and xenocrysts can be seen with an optical microscope, they can be extremely difficult, if not impossible, to effectively separate from the glass. I've attempted to separate very fined-grained minerals from glass in coal ashes by using magnetic separation and hydrofluoric and other acids. It's not easy.
If the author is to charge that having a good sample is difficult, then I will use the same charge and say that SG geologists as well can have impure samples, which leads to erroneous datings.
To address the second statement first, it is fallacious to say that because one person was unable to create a pure sample that all others must have the same problem.
Well, it would then as well be fallacious to say that since the author finds it difficult to separate the minerals, then Austin as well would. However, the point was that even the
author says it "can be extremely difficult, if not impossible." And it reveals that the process is subject to human error, not matter how careful one can be.
Secondly, there are more difficulties with Austin's work than just this one point.
See
http://www.noanswersingenesis.org.au/mt ... ite_kh.htm.
In particular, the lab to which the samples were sent specifically noted up front that their techniques could not be applied to rocks known to be under 2 millions years old.
Yes, Scotracer
referenced that earlier.
Here was
my reply:
Well, since the Geochron labs now no longer does K-Ar dating, I cannot confirm that "We cannot analyze samples expected to be younger than 2 M.Y" was on their website.
And the charge that "very tiny amounts of argon contaminants from previous analyses may remain within the equipment, which precludes accurate dates for very young samples", I think would be highly speculative.
He also charges Austin with a failure to properly identify the phenocrysts. But, Henke even states "For even the best mineralogists and petrologists, xenocrysts may be difficult to distinguish from phenocrysts." This would place a significant human source of error into any K-Ar dating.
Here is the summary from the second link in my previous post.
[url=http://skeptoid.com/episodes/4146]Brian Dunning[/url] wrote:
If we allow both sides to have their say, and do not bring a bias preconditioning us to accept whatever one side says and to look only for flaws in the other side, a fair conclusion to make is that both sides make valid points. Austin does indeed identify a real potential weakness in potassium-argon dating. However he is wrong that his phenocrysts constitute a fatal flaw in potassium-argon dating previously unknown to geology. In fact, the implications of phenocrysts were already well understood. Yes they are one of the variables, and yes, in some samples they do push the error bars. However, the errors they introduce are in the range of a standard deviation, they are not nearly adequate to explain errors as gross as three or more orders of magnitude, which would be necessary to explain the discrepancy between the measured age of rocks and the Biblical age of the Earth.
Such variables are also a principal reason that geologists never rely on just one dating method, with no checks or balances. That would be pretty reckless. For most rocks, multiple types of radiometric dating are appropriate; and in practice, multiple samples would always be tested, not just one like Austin used. In combination, these tests give a far more complete and accurate picture of a rock's true age than just a single potassium-argon test could. In addition, stratigraphic and paleomagnetic data can often contribute to the picture as well. From many decades of such experience, geologists have excellent data that guides proper usage of each of these tools, and they don't include gross misuse of potassium-argon dating.
What Austin did was to exploit a known caveat in radiometric dating; dramatically illustrate it with a high-profile test using the public's favorite volcano, Mount St. Helens; and sensationalize the results in a paper that introduces nothing new to geologists, but that impresses laypeople with its detailed scientific language. Occasionally scientists do actually make huge discoveries that everyone else in their field had always missed, but such claims are wrong far more often than they're right; and Dr. Austin and his finding that radiometric dating has always been useless is a perfect example.
Leaving aside the rabbits represented by the sampling, the main problem is that what Austin did is like sending a molecule out to be measured by an approximate yardstick. The reading came back 1/16th of an inch. Compared to the magnitude of a molecule, this is a big error. Compared to the scale on a yard stick it is a small error. Austin concludes from this that we should throw out the yardstick.
Argon has a half life of 1.2 billion years. 2 million years is about 1/6th of a percent of this half life. About the same fraction as 1/16th of an inch to a yard.
The margin of error mentioned by Dunning for Argon dating is in the range of 600,000 years. This is a rather huge fraction of the dates given by Austin, not to mention many thousands of times the actual age of the rocks.
I am sorry. The argument that Austin's analysis implies major problems for radiometric dating in general, or even Argon dating in particular does not hold water
At any rate, I noticed you picked out this one piece from my previous post. Now, I am not saying dating is irrelevant to the discussion of the SG or FM. However, we could consider the features and fossils presented by the Grand Canyon without considering the time scales involved.
In particular, how could a flood create the tilted features at the bottom, with the faults, and then the layers on top, and also have some small interpolations of bowl shaped layers (4a, 4b, 4c).
Note that in the "Grand Staircase" picture you provided, there are two smaller regions of layers that have faulted and slid past each other towards the bottom right where the canyon is. The rightmost of these two is labelled 1 and 2 in the more zoomed in graphic. Then we have layers on top of these.
Again, how could this have occurred during a flood? The faults do not go through the layers numbered 3 or higher. Also, if the 1 and 2 layers were formed during a flood and then also faulted during the flood, how did they not get mixed up? Surely it would take a while for these layers to harden.
If they were not hard when the faulting occurred, the layers would get rather severely disturbed along the fault line. This does not appear to have happened. Thus, it is reasonable to assume they were hardened before cracking and sliding. Then, being hard, they would have had to be tilted and then parts eroded away before the higher layers were laid down. That's a lot to happen during a short flood period.
" . . . the line separating good and evil passes, not through states, nor between classes, nor between political parties either, but right through every human heart . . . ." Alexander Solzhenitsyn
