otseng wrote:micatala wrote:The seasonal snow layers are easiest to see in snow pits, writes Alley, the Evan Pugh Professor in the Environment Institute and Department of Geosciences at Pennsylvania State University. To see the layers, scientists dig two pits separated by a thin wall of snow. One pit is covered, and the other is left open to sunlight. By standing in the covered pit, scientists can study the annual snow layers in the snow wall as the sunlight filters through the other side. I have stood in snow pits with dozens of people"drillers, journalists, and others"and so far, every visitor has been impressed. The snow is blue, something like the blue seen by deep sea divers, an indescribable, almost achingly beautiful blue, writes Alley. The next thing most people notice is the layering.
I've found an image of a snow pit in Antarctica.
http://lima.nasa.gov/antarctica/
Very nice. Thanks for the inclusion.
The caption reads:
"Snow pits dug into the surface snow (and back lit with a second pit to illuminate a thin wall of snow) show layers caused by individual snowfall events. Unevenness of the layers results from drifting of the snow while it was on the surface."
I assume the numbers on the right is the depth.
Based on the comparison with the person in the photo, that seems reasonable.
If so, even near the surface, the individual layers are quite thin and irregular. Layers are not attributed to annual layers, but to individual snowfall events.
How do you know the layers are not annual but are individual snow fall events? I looked for some accompanying explanation, but there was none concerning this photo. I agree the layers are "irregular". I would agree it is possible that a layer can be "pinched off" so you might get a different number of visual layers. This could be due to drifting, for example. I would even agree that I would not personally feel confident in predicting where the yearly breaks are. Keep in mind that any "missing layers" only increases the actual age as compared to the estimated age based on the core sample.
In addition, you and I don't have a lot of experience looking at such layers. Nor do we have any of the other data for these layers, like oxygen ion ratios, carbon dating of pollen and other residues, etc.
If this photo is from close to the surface, it is possible and perhaps likely that they have kept track of the annual layers as the fell for several years. I mentioned this before.
I can understand how you might come to an initial impression, but your comment
completely ignores many considerations that have already been discussed concerning ice cores, especially that scientists use a variety of methods in concert to check for errors in any one method.
See
http://www.gfy.ku.dk/~www-glac/datering ... tint_e.htm for an image including very deep visual layers together with accompanying data from two chemical tests.
otseng wrote:
As one goes deeper, the layers will be even more indistinguishable. So, this image leads me to believe that visual layer counting cannot be used as a method of dating in the Antarctic.
I will allow the visual inspection is not perfect, and this is acknowledged in the sources I have cited. However, it is incorrect, I think, to say that it cannot be used as a dating method by people with experience with ice core layers.
Also, I am not sure that deeper necessarily means more indistinguishable. The image from the link I posted (from the Copenhagen Ice Core Dating Initiative) is deeper and these seem on first blush to be MORE distinguishable. I think it depends on how deep you go. I would agree, and the sources Ive cited allude to this, that when compression makes the layers too thin, one will lose the ability to visually distinguish layers and may lose the ability to distinguish them chemically and by other means. I will see if I can check on how for down one typically has to go before this happens.
Here is a section from
http://www.csa.com/discoveryguides/icecore/review.php which discusses how O16 versus O18 concentrations are used for dating purposes.
Stable Isotope Analysis:
One of the most common ice core proxies is the analysis of stable isotopic ratios, primarily deuterium and oxygen 18. Atoms are composed of protons, neutrons, and electrons. The number of protons determines what the element is, while neutrons and electrons can vary. An isotope is an atom with a different number of neutrons from the set number of protons. For example, oxygen, which contains 8 protons, usually has with it 8 neutrons creating oxygen 16. However, in some cases, there may be 9 or even 10 neutrons in the oxygen nucleus creating oxygen 17 and oxygen 18 respectively.
Water, composed of hydrogen and oxygen, contains naturally occurring isotopes that combine into molecules of differing weights. Oxygen occurs naturally as three different stable isotopes with relative abundance in parenthesis - 16O (99.76%), 17O (0.04%), and 18O (0.2%). Hydrogen can occur with two stable isotopes -- 1H (99.984%) and 2H (0.016%). Together these combine to make up all water molecules, of which only two combinations are important for paleoclimatic research - 1H2H16O and 1H218O. As these water molecules are evaporated, primarily from the oceans, the lighter molecules, those having fewer neutrons, are preferentially evaporated over the heavier ones, due to a slight difference in vapor pressure caused by the extra neutrons. This causes the vapor to be depleted in heavy molecules but enriched in lighter ones. As the air mass cools and condensation occurs, the heavier molecules preferentially condense due to the same principle. The condensation is then assumed to fall out of the cloud as precipitation. Thus, the oxygen isotopic ratio of rain and snow is strongly related to condensation temperature. If the temperature of the air mass should continue to fall, the condensation will contain decreasing concentrations of the heavy molecules, resulting in a depletion of 18O relative to precipitation that condensed in a warmer environment. In the current environment this is exemplified by annual layers exhibited in Greenland and Antarctic cores with a much greater depletion of heavier molecules in ice and snow.
In the 1960's this principle was well understood by scientists and engineers; however for researchers around the world to study the relationship between isotopic ratios and air temperature a standard had to be developed to allow for intercomparisons of all samples. Developed in 1961, this is called Standard Mean Ocean Water (SMOW), and all oxygen isotopic deviations from it are denoted as delta18O; hydrogen isotopic deviations as deltaD.
More details follow this paragraph.
To reiterate, it is the combination of methods checked against each other, including the use of marker events like volcanic eruptions, crater impacts (like the 1908 impact in Russia), ongoing observation as layers form, etc., that allow us to conclude with a high degree of certainty that we are counting annual layers.
Based on this experience and the science of ice flow and formation, we can at least do estimates based on depth for the deepest part of sheets where layers may be difficult to distinguish. For example, if we get N years of "countable layers" at the top of a core and have only gone through a fraction of the total depth, we can reasonably suggest (although perhaps not prove) that the sheet is several factors of N older.
" . . . 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
