Guest post by Dr. Walt Meier
Now that the summer is over, I thought people might be interested in a bit of retrospective of the sea ice melt season in 2010 and in the longer-term context. NSIDC provided a brief recap and the SEARCH Sea Ice Outlook will soon have their own recap. However, I can explain in a bit more detail and directly address some issues that arose here over the summer.
First, I thank Anthony for this opportunity and him and Steve for their frequent posts this summer, and for the handy sea ice reference page. It is nice to see climate and sea ice issues brought to an audience that might otherwise not hear about them. I hope the information will bring further clarity to some sea ice and polar climate processes. Some of the issues below, I at least touched on earlier this summer in posts here and here. As usual, I’m speaking for myself and not as a representative of the National Snow and Ice Data Center (NSDIC) or the University of Colorado.
Recap of summer predictions
I will start with a discussion of the prognostications from earlier this spring. In the June SEARCH Sea Ice Outlook there was fairly broad range of estimates, from 4.2 to 5.7 million square kilometers. If I remember correctly, Steve and Anthony’s estimates were 5.5 and 5.1 million square kilometers respectively. NSIDC’s initial estimate in June was 5.5 million square kilometers.
The first thing to point out is that none of the estimates approached the 1979-2000 monthly September average of 7.0 million square kilometers. Even the highest estimates were nearly 20% lower. This is a recognition that conditions have clearly changed since the 1980s and 1990s. It is no longer plausible to prognosticate anything near average levels. (For those who are curious, the 1979-2010 average, which of course includes the recent very low years, is 6.58 million square kilometers. Only one outlook (5.7 by Tivy) was within 1 million square kilometers of that value.)
NSIDC’s June estimate was too high compared to what actually happened. This is not at all surprising to me. We used a method that relies on past survival rates of ice of different ages. However, conditions have changed with the Arctic sea ice – the ice overall is thinner and less consolidated. Predictions based on past behavior are less likely to be valid. In other words, the odds of have changed. Steve’s prediction was based on a similar premise – the apparent similarity between winter 2006 and 2010 ice thickness patterns in the PIPS model.
Over the summer there was discussion ascribing the lower than predicted minimum extent primarily to ice motion. Ice motion indeed plays a role in the seasonal evolution of the ice cover as well as the interannual variation in the multiyear ice cover. However, to ascribe all or even the majority of sea ice changes to ice motion is simply wrong. As I discussed in my post earlier this summer, even in an extreme year like 2007, only a third of the extreme loss was due to anomalous ice motion. Over longer time scales, it has been shown that the Arctic Oscillation influences how much multiyear ice (MYI – ice that has survived at least one summer melt season) stays in the Arctic vs. how much leaves the Arctic over the winter, which in turn affects how much ice remains at the end of summer. For example, over the past winter, we had an extreme negative AO, which kept a lot of MYI in the central Arctic.
This summer was not particularly extreme in terms of ice motion. There were times during the summer where the ice pack was pushed together in some places, while at other times the motion was not a factor or even pushed the ice edge outward.
The importance of bottom and lateral melt
One factor that wasn’t discussed much is melt at the bottom and sides of the ice. This melt depends on the ocean temperatures. During summer when ice melts and open water is exposed, the ocean warms. The ocean accumulates heat which can then melt the ice, both along the edges (lateral melt) of the ice and on the bottom of the ice as currents move the warmer water under the ice and/or the ice is pushed over warmer water by winds. Most of the late season ice melt is due to lateral and bottom melt because the surface has cooled with the setting sun. This explains why even when the DMI air temperatures commonly discussed in the WUWT Sea Ice News, go below freezing around mid-August, there is still another month left in the melt season and extent continues to decline at least a few hundred thousand more square kilometers after mid-August. This year ocean temperatures were not as extreme as the past few summers, but there was still a considerable amount of ocean heat available to melt sea ice.
The bottom line is that while winds can make a difference at times, the overriding factor in seasonal and long-term Arctic sea ice decline is that warmer temperatures lead to less ice.
Why forecasts were too high
The biggest change in the ice over the past several years is that the ice is thinner overall than it used to be and there is less of the thicker, older ice. Another thing is that the old ice that remains is less consolidated – scattered floes of old ice with thinner, younger ice in between instead of tightly packed together. These factors affect the seasonal evolution of the summer sea ice in two ways. First, when the thicker, older ice is in broken up floes, it is more easily “attacked” on all sides by the ocean heat and can potentially be melted completely. Second, the less consolidated ice is more easily pushed around by the ice and more susceptible to winds pushing the ice together – in other words, the effect of the wind is amplified.
I think this is a major reason why a lot of the forecasts were too high. The tongue of mostly MYI in the Beaufort Sea completely melted out. In 2006, there was enough thick and consolidated ice to be vanguard against further ice loss, but by 2010 it was thinner and less consolidated and melted completely (Figure 1). This can be seen clearly in the ice age animation for the past year (Figure 2). The nice thing about these fields is that they show the effect of both motion and melt. If the extent decline were primarily motion, we would simply see the MYI in the Beaufort and Chukchi Seas get pushed together. Instead however, we see the older ice disappear over the summer, i.e., it melts (Figure 2).
Figure 1. Arctic sea ice age during March (left) and September (right) for 2006 (top) and 2010 (bottom). The color key denotes the age of ice (a value of “1” means first-year ice or ice that is 0-1 year old, etc.). Thanks to C. Fowler, Univ. of Colorado, for providing images.
Figure 2. Animation of sea ice age from September 2009 through September 2010. The color key denotes the age of ice (a value of “1” means first-year ice or ice that is 0-1 year old, etc.). The number in the lower right corner denotes the week of the year (1-52). Thanks to C. Fowler, Univ. of Colorado, for providing animation.
After the past couple of summers, there has been a build-up of young MYI – ice between 1 and 3 years old. It had been thought that this MYI would “buffer” the summer ice loss and keep extents from dropping too low. However, watch the animation (Figure 2) closely and see that the 3rd year ice (ice that is 2-3 years old, in green), dispersed and melted or exited out of the Arctic through the winter-spring of 2009-2010. So there was very little replenishment of the older ice. A lot of the 2nd year ice remained at the end of this summer, which has now aged into 3rd year ice. So maybe there’s hope for next year, but what we’re seeing is that the MYI just is not surviving like it used to. There is now almost no ice older than 4 years old remaining in the Arctic. This is a stark and fundamental change in the character of the Arctic sea ice.
PIPS vs. PIOMAS revisited
There was a lot of discussion earlier this year on the PIPS model sea ice fields vs. the PIOMAS model fields (e.g., here). At the beginning of the melt season, PIPS showed quite a bit of thick (3-4 m) ice throughout much of the Arctic Ocean, which wouldn’t be expected to melt completely. This portended less loss of ice during the summer. However, the PIPS fields did not agree well with the ice age fields, which showed less thick ice and a more dispersed multiyear ice cover. As it turned out, I think the PIPS were indeed to too thick, resulting in a forecast that was too high.
On the other hand, the PIOMAS total volume anomaly estimates were quite low going into the summer, indicating thinner ice and suggesting a low extent was likely. As I said previously, the volume seemed to me to be too low. Indeed, the PIOMAS forecast was lower than the actual minimum, though in the end it didn’t do a half-bad job in its prediction (4.7 predicted vs. 4.9 actual, in millions of sq km). To be sure, some of this could be attributed to luck, because there is always the wildcard of what the weather will do over the summer. Regardless, it is clear from the ice age, other ice thickness observations, and the overall state of the ice cover that volume is at or near record lows compared to at least the past 30 years. So while PIOMAS may be biased too low on ice volume, it captures the overall thinning trend and seems to better represent the actual state of the ice cover than PIPS.
Pre-satellite records of sea ice
Whenever I talk about “long-term” trends, I always see comments about how NSIDC’s data are only a 32 year record and hardly constitute “long-term” in the big picture of climate. This is a fair point. However unfortunate though it may be, that is all the data we have, at least in terms of a consistent and complete record. We have some data from earlier decades, but these are incomplete. For example, there was post earlier this week (October 16) about a recent book on longer-term sea ice changes in the 20th century. I read through this book earlier this year, so I’m familiar with it. As the title (“Climate Change in the Eurasian Arctic Shelf Seas”) states, the book analyzes data only the Russian shelf regions of the Arctic – it doesn’t include the central Arctic or U.S./Canadian Arctic, where a significant portion of the decline has occurred over the past decades. Their conclusions are drawn from data through only 2003, so with the recent low years since then, the observed patterns of variability may no longer hold. (There is a final section in the book on 2003-2008 sea ice conditions, but these data are discussed independently and are not incorporated to update their analyses earlier in the book.)
The book only superficially examines ice thickness changes (again only in the Russian shelf regions) and does not examine the recent thickness data from ICESat or the ice age fields. Finally, as it states in conclusion #2: “These cyclic oscillations of sea ice extent were superimposed on the background consisting of a negative long-term linear trend that characterizes gradual decrease of sea ice extent during the 20th century and the beginning of the 21st century.” In other words, even in the Russian data, there is a decline. The authors suggest this decline could be indicative of a longer cycle, but admit that such a conclusion can only be “conjectured”.
So while the book provides useful data (Russian information is often difficult to obtain), their conclusions about reasons for the changes in overall Arctic sea ice and the state of sea ice in the coming decades are more limited than the book seems to suggest. Andy Mahoney (a former colleague of mine at NSIDC) and others also analyzed the Russian data in a paper published in 2008 (Mahoney et al., 2008 – a brief summary is here).
Paleo records of sea ice
Even 100 years is still a fairly short period of time in terms of the history of the earth. However, in terms of climate change, such a period of time is enough discern the influence of large-scale forcing such as anthropogenic greenhouse gases. Nonetheless, it is useful to have longer-term data to understand climate history, particularly in terms of how sensitive various aspects of the climate system, such as sea ice, are to changes in climate forcings. We can obtain some information about earlier sea ice from proxy records, but it gets even more difficult to draw conclusions about conditions Arctic-wide.
For example, there was a post on September 23 about a 2006 paper discussing a proxy record indicating more extensive sea ice now than most of the past 9000 years. However, the paper is about a single record from a single location. It is very difficult to generalize from one isolated observation. As I mentioned in a previous post, the most recent and comprehensive analysis of all available proxy sea ice records, published earlier this year (Polyak et al., 2010 – note that Polyak is a co-author on the 2006 paper), indicates that current total Arctic-wide sea ice extents are likely lower than any time in the last several thousand years and are “not explainable by known natural variabilities”. The data are still sparse, but this is the best information we have at the moment.
The Northwest Passage, Northern Sea Route, and Circumnavigation of the Arctic
Navigation in the Arctic during the summer always gets a lot of interest. People point out that recent sailing expeditions through the Northwest Passage and Northern Sea Route (along the Siberian coast) are not unique in history. This is true. Amundsen navigated through the NWP in 1903, the Canadian vessel St. Roche went through the NWP a couple times in the 1940s. In 1969, the ice-strengthened freighter, USS Manhattan went through with Canadian icebreaker support. There were a few others before 2000. Many required icebreaker support or needed more than one summer to complete the journey (Amundsen needed nearly three summers). The Northeast Passage has been used by the Russians as an icebreaker-supported shipping route for many years and several ships have made the voyage.
However, this doesn’t mean conditions in the past were anything like today. They were not. While conditions will vary from year-to-year and I think it will be some time before either passage (especially the NWP) will be a reliable route, both passages have been far more open in recent years than in the past. What used to be a risky proposition, carefully navigating through narrow openings between ice floes, has in recent years become a mostly open water cruise with occasional ice (though still dangerous because even relatively small scattered floes of ice can damage a vessel). This year two vessels circumnavigated the pole through the two passages within one summer. In addition, several other vessels went through at least one of the passages this year. This is really quite remarkable and something I doubt anyone in the 20th century ever thought would be possible in 2010.
(Some complained when these expeditions were called “circumnavigating the Arctic” or “circumnavigating the Arctic Ocean” because they went south of Greenland. To technically circumnavigate the Arctic Ocean, one would need to follow the coast along the north coast of Greenland. This is true, but it in no way diminishes the feats nor does it contradict the reality that the Arctic is very different place than it was just twenty or thirty years ago.)
Antarctic sea ice
During the past Arctic summer, the Antarctic winter sea ice was showing some interesting behavior. As the Arctic ice declined, Antarctic ice went to much higher than normal levels. This caused a bit of a stir. It seemed like the Antarctic was headed to a record-shattering maximum. Alas, this did not happen. The extent went back to down to normal. Now it is again above normal. Such variability is characteristic of the Antarctic, especially in winter. The entire circumference of the Antarctic continent is surrounded by sea ice. Most of the ice is less than 1 meter thick, and much of it is less than 0.5 meters, particularly near the ice edge. This means shifts in currents and winds can quite quickly shift the ice edge in or out. So fairly dramatic ups and downs in Antarctic sea ice extent are not uncommon.
Nonethless, over the satellite record there is a small upward trend in overall Antarctic sea ice extent. The magnitude of the trend is much smaller than the Arctic (1-4% per decade vs. 3-11% per decade, depending on the month). And when you look at the spatial trends, where the decline is occurring, you see an interesting difference. In the Arctic, there is decline in almost all regions throughout the entire year (the Bering Sea during winter being the lone exception). In the Antarctic, all months are characterized by variation in the trends – in one region there is an increasing trend in extent and in another region there is a decrease (Figure 3). This is a clue that a main driver is changing circulation patterns, and indeed the changes in Antarctic sea ice have been linked to changes in circulation from the Southern Annular Mode (SAM – kind of an Arctic Oscillation [AO] for the southern hemisphere), for example in Turner et al. (2010) (key points can be read here). Circulation changes affect the Arctic sea ice too of course, particularly the AO, but the impact is even greater in the Antarctic because the ice is so thin and the ice boundary is completely open throughout the year (as opposed to the Arctic where for much of the year most of the ice edge borders the coast).
Figure 3. Trends in Arctic (top) and Antarctic (bottom) sea ice for (from left to right): September, December, March, and June. Red shades mean an increasing trend of sea ice; blue shades mean a decreasing trend. Images from the NSIDC Sea Ice Index. Other months show similar patterns and can be viewed using the Sea Ice Index browse tool.
But why has the SAM changed? Some scientists have suggested that a possible mechanism is the ozone hole. The ozone hole changes circulation high in the atmosphere, which then changes circulation at the surface. It is a plausible theory, supported by some evidence (discussed for example in Turner et al., 2010), but still tentative. Recently, there was paper (Sigmond and Fyfe, 2010) that showed results of a modeling study where the ozone hole did not increase sea ice in their model as had been expected (discussed here). It is rare these days that a single paper provides a final answer, so while the results are intriguing, it could be that the model is not capturing all the physical processes (e.g., the details of the interaction between snow and sea ice discussed below); or it could be that the model results are correct and a new explanation is needed.
Another study that was mentioned this past summer, discussed here, was the paper by Liu and Curry (2010) on the seeming contradiction that warmer temperatures over the Antarctic Ocean can lead to more sea ice (at least for a while). This seems counterintuitive, especially in light of my comment about the Arctic sea ice and temperatures above.
The key is that the Antarctic and the Arctic sea ice regions are very different places. In the Arctic, we have a relatively shallow, semi-enclosed body of water. There is a lot of freshwater from rivers input into the surface of the ocean. This less saline water floats on the surface, while heavier and warmer water sits below – in other words the ocean is stratified. That heavier water has a lot of heat in it, but it is difficult for the heat to reach the ice. The waters in the Antarctic are not well-stratified and there is a lot of potential heat from the ocean that can melt ice.
Another difference is that because the Arctic Ocean is almost completely surrounded by land, there is not as much moisture available and snow fall is relatively low. In contrast, Antarctica is surrounded on all sides by an ocean. While the middle of the Antarctic continent is a desert (because moisture cannot reach the high altitudes inland), the coastal and sea ice regions actually receive a lot of snow.
The snow has two effects. First, when it falls into the open ocean, it serves to freshen (and hence stratify) the surface layers. Then the more stable ocean surface makes sea ice formation easier by keeping more ocean heat below the surface. Second, when it falls onto sea ice it accumulates on top and “weighs down” the sea ice. With Antarctic sea ice being on average much thinner than the Arctic, it is not uncommon for the weight of the snow to push the top surface of the ice below the water line. When this occurs, the snow gets flooded by the ocean waters, which then freeze and form what is called “snow ice”. Effectively, the snow is converted to ice and thickens the ice cover.
When the atmosphere is warmer, it can hold more moisture, which in the Southern Ocean will fall as snow. This increase in snowfall then leads to more sea ice growth. This potential effect has been long known to scientists, and Liu and Curry’s paper is evidence that supports this idea (with the same caveats above that this is just one paper). Thus, warmer temperatures can lead to more sea ice. At least up to a point. If, as expected, temperatures continue to warm over the Southern Ocean, eventually the direct effect of the warmer temperatures will overtake the indirect effect on sea ice via snow fall, and Antarctic sea ice will begin to decline.
Conclusion
Though I don’t have time to read nearly all of the posts here and even fewer of the comments, I am often impressed by the interest and passion expressed therein. I’m sure I haven’t answered all questions about sea ice here, but I hope I’ve addressed many things that people have been curious about, particularly issues that have come up over this past summer.
References
Liu, J., and J.A. Curry, 2010. Accelerated warming of the Southern Ocean its impacts on the hydrological cycle and sea ice, Proc. Nat’l Academies of Science, 107(34), 14987-14992, doi:10.1073/pnas.1003336107.
Mahoney, A.R., R.G. Barry, V. Smolyanitsky, and F. Fetterer, 2008. Observed sea ice extent in the Russian Arctic, 1933-2006, J. Geophysical Research, 113(C11005), doi:10.1029/2008JC004830.
Polyak, L., and 17 others, 2010. History of sea ice in the Arctic, Quaternary Science Rev., 29, 1757-1778, doi:10.1016/j.quascirev.2010.02.010.
Sigmond, M., and J. C. Fyfe (2010), Has the ozone hole contributed to increased Antarctic sea ice extent?, Geophys. Res. Lett., 37, L18502, doi:10.1029/2010GL044301.
Turner, J., R.A. Bindschadler, P. Convey, G. Di Prisco, E. Fahrbach, J. Gutt, D.A. Hodgson, P.A. Mayewski, and C.P. Summerhayes, 2010. Antarctic Climate Change and the Environment, Scientific Committee on Scientific Research (SCAR), ISBN 978-0-948277-22-1. http://www.scar.org/publications/occasionals/acce.html
Welcome to the rough and tumble world of WUWT, Dr. Meier. We are a scrappy lot, used to giving as good as we got. Hurry back and next time you might want to bring some friends with you just to make it fair.
It’s amazing what silly jobs people (Walt.M) do for a living.
WUWT is changing lately, it blows warmer…
RE: Mike says:
October 21, 2010 at 2:16 pm
***This just in:
Report: Arctic temperature rising at near record rates, sea ice melting faster
1:56 p.m. CDT, October 21, 2010
WASHINGTON (AP) — The temperature is rising again in the Arctic, with the sea ice extent dropping to one of the lowest levels on record, climate scientists reported Thursday.***
Yawn. When they do not want to report what is actually happening they rehash stuff from months ago.
“”” John F. Hultquist says:
October 21, 2010 at 6:50 pm
tonyb says: at 12:25 pm
Also as regards to the ozone hole , how do we know it hasn’t always been there growing and shrinking in a random fashion. “””
It has long been known that the sun, as the most prominent natural light source in the sky, has a seasonal and randomly varying apparent color temperature. (check Standard Optics Handbooks).
These variations were also attributed to changes in the (apparent) solar spectrum particularly in the UV region. Ozone is known to take out a big whack in the UV to green/blue region of the solar spectrum; (see air mass zero and air mass one solar spectrum plots).
So I suggest that there is ample historic observational evidence, that ozone holes have always been with us; but weren’t recognised as such until somebody looked for an ozone hole and found one.
I don’t know when the words “Ozone Hole” first appeared in a scientific paper; but if I had to guess I would say sometime during the IGY of 1957/8 which was deliberately set up to coincide with the expected maximum of the current sunspot cycle; which as it turned out was the ne plus ultra of all sunspot peaks; either before or since; and since the Antarctic Continent gained a huge population of scientists during that research “woodstock”, I wouldn’t be surprised to find that one of them looked for an Ozone hole and found one. I’d pick a Frenchman if I was a betting person; but then I’m not.
Well just for kicks, I wikied ozone hole discovery, and found that some Brit invented them in 1985.
In which case I shall declare him to be a Johny come lately in the history of Ozone holes.
So now to make good, I shall research my Optics Handbooks, to find an earlier reference to the varying color Temperature of the Sun as a natural Light Source.
So what i can take away from this is that the arctic sea ice will continue to melt and we will soon be ice free in the arctic, which in turn will allow us to drill in these waters for more oil.
I guess in summary, ‘its better than we thought’!
Thanks for the great summary, really….hobo
The problem with this analysis is not with the analysis itself but with the data, or rather the lack of relevent data.
It is well known that the climate varies substantially over long time periods.
Very careful scietific analysis is not in itself adequate for the task.
Selecting a ridiculously short time frame as satelite data allows, shows a significant misunderstanding of reality.
There are good (and no doubt peer reviewed) historic records to use to compare the current situation.
It is clear that the artic has been open and closed many time during human occupation, as well as during the relatively shorter time when historic records have been kept.
Compare the past with the present.
Nothing much is happening today that is out of the ordinary.
Move along now, this joke is getting rather stale.
Climatologists should all hang up their spreadsheets and spend the next few years in silent contemplation.
Reading some history would not go amiss.
Tenuc says: October 21, 2010 at 2:51 pm
Wrong. Past behaviour theory only works for linear systems where all the variables can be accounted for. Sea ice levels are the result of a non-linear process driven by deterministic chaos and linear trends and past history have no predictive value.
You have a good point that the sort of precise predictions that physicists like to make (for example, on 2019 Jul 02 there will be a total eclipse across parts of South America) are not possible for weather and climate. Past behavior of the moon gives us very precise predictions of future behavior that climate scientists can only dream about.
That does not mean that there is not predictive power. For example, I just ran August sea ice data from NSIDC (1979-2010 — both extant and area) through Minitab, and it gives around a 0.6 autocorrelation for one year to the next again, for both extent and area). This result is much better than the standard 0.05 level for statistical significance. Without knowing a thing about the actual mechanisms, I can still conclude that there is a statistically significant correlation from one year to the next year.
Based on this, I am pretty confident that since this year was well below average, next year will also be well below average. To say that there is no predictive value in past data, you would have to think that any result from the data set would be equally likely next year, and that there is a 50-50 chance of being above average.
@Dale Rainwater Meier
Thank you for the thoroughful exposition of the subject.
I have looked up the Russian book on the arctic ice. You say that the declining trend is “conjuctured”- it is in fact a true quotation of their book. However, they put it in a context – they hypothesise a 200 year climatic cycle to be responsible for this.
I would say it is prudent on their side to use these words – they do not have enough data to support it.
On other hand, do you have enough data to reject their hypothesis? And adopt a linear aproximation of observed data?
the_Butcher says: October 21, 2010 at 7:11 pm
“It’s amazing what silly jobs people (Walt.M) do for a living.
WUWT is changing lately, it blows warmer…”
WUWT is becoming more inclusive. We are not going to advance human knowledge by ignoring each other, yelling at each other, attempting to belittle each other, etc. Try challenging Walt’s facts, rather than questioning his quite admirable career path…
Walt Meier says:
October 21, 2010 at 4:00 pm
“……
Wes (10:14): Icebreakers have a negligible effect on the sea ice. Even with more icebreakers, the area they impact is very small compared to the overall sea ice cover.”
Can you please provide more detail to back up this statement. I can put a small crack on a windscreen covering a very tiny portion of the area of that windscreen but that crack can then go on to compromise the entire windscreen.
I simple tear in a hot air balloon whilst being only a small portion of the entire baloon can cause the entire ballon to fail.
A small tear in a muscle can lead to greater failure if the muscle is under stress.
You only need to look at the movement of the ice each year. To see it flow and crack to understand that if you run an icebreaker through an area that was not previously cracked then your going to weaken it.
Some of these icebreakers make extensive journeys through the ice. How much do these icebreakers affect the cohesion of the pack. Whilst the passages they create might be small in comparison to the overall volume of ice, how do you know for a certain that an area of ice that has been split in 2 by the passage of an icebreaker won’t be more susceptible to melt?
Have any studies been done? If not then your answer must be that you don’t know what role icebreakers are playing.
David W says: October 21, 2010 at 9:03 pm
“Whilst the passages they create might be small in comparison to the overall volume of ice, how do you know for a certain that an area of ice that has been split in 2 by the passage of an icebreaker won’t be more susceptible to melt?”
This is an interesting point, especially when large sea ice floes can be blow into warmer waters. For example if you look at the icebreaker Healy’s Cruise Track for 2007;
http://www.icefloe.net/docs/HLY-07track.pdf
it is not hard to imagine how a fleet of icebreakers might have a measurable impact on sea ice melt.
For those interested, the US Coast Guard’s Icebreaker Science Operations site can be found here:
http://www.icefloe.net/cruisetrack.html
I see 2 potential threats from icebreakers but the biggest would be in allowing huge chunks to break off that then flow into warmer waters. Chunks that were they still attached to the larger sheet would not have done so.
The other threat would be if you put a passage through an otherwise solid sheet you end up with 2 sheets separated that can bump and grind against each other causing further ice loss.
I would be very curious to see a set of before and after images from the passage on an icebreaker.
The worst part of it is though, its likely that the majority of the damage could be occuring on the edges of the ice sheet where the ice is at its most susceptible. And each season the ice on the edges gets into poorer conditions allowing ice breakers to penetrate further into areas they previous might not have gone.
…and meanwhile, the sea surface temperature continues to plunge:
http://discover.itsc.uah.edu/amsutemps/execute.csh?amsutemps+001
It’s now approx 0.4 degree cooler than last year.
kuhnkat said:
October 21, 2010 at 11:26 am
The good doctor makes it sound like any one with an attention span could navigate through the passages. I would ask him why there were so many people requiring RESCUE this year if the conditions were so favaorable?
__________________________
I think the biggest rescue was a boat that ran aground, rather than ice, indeed if there had been more ice it might not have run aground 😉
Excellent article by Walt, and followup about Cryosat 2. I was wondering how to stitch together the new data with the old but it seems it won’t be as yet. However if it helps with the seasonal forecast then that will be great, especially as the current conditional change up there is making estimates too high at the moment. Perhaps SEARCH will be more accurate in 2011.
I’ll be interested to see if rbatemans 22M km^2 plays out, is that extent at the end of December rbateman? I think you called it for Dec rather than March????
Andy
I think this talk of ice breakers is baloney to be honest. It’s sort of like a flea biting an elephant, an elephant the size of 3 Manhattan’s (to quote that newest of SI measurements). 🙂
Andy
David W says: October 21, 2010 at 10:10 pm
“And each season the ice on the edges gets into poorer conditions allowing ice breakers to penetrate further into areas they previous might not have gone.”
Here is a progression of the US Coast Guard Icebreaker Healy’s Cruise Tracks from
2006 – 2008;
2006: http://www.icefloe.net/images/HLY-06annot.pdf
2007: http://www.icefloe.net/docs/HLY-07track.pdf
2008: http://www.icefloe.net/docs/healy2008.pdf
and I believe that this is a compilation of Healy’s Cruise Tracks from 2000 – 2005:
http://www.icefloe.net/images/healy_tracks2.jpg
The Healy seems to be doing what it is intended to do, i.e. breaking up the ice. In addition to science and exploration, the Coast Guard is tasked with opening and maintaining sea lanes, rescuing stranded boats, etc.
For context here a good article in the Coast Guard Compass on Healy included a good full-size pic at the end:
http://coastguard.dodlive.mil/index.php/2009/06/coast-guard-and-the-arctic-part-2/
I found this quote interesting;
“Key sea and air lanes need to remain open as a matter of international legal right and not depend on the approval from nations along the routes, so that vessels like Healy can get where they need to go and get there quickly.”
and this one amusing;
“Coast Guard Cutter Healy is the largest of the heavy ice breakers in the Coast Guard. Her ice breaking capabilities are 4.5 ft @ur momisugly 3 knots continuous and 8 ft of ice when backing and ramming. Backing and ramming is pretty much what it sounds like and I don’t mean how you parallel parked a car when you were a teenager.”
Don’t forget about Carbon Black (Soot, not CO2) is a relatively new phenomena and is getting worse.
AndyW says:
October 21, 2010 at 11:10 pm
“I think this talk of ice breakers is baloney to be honest. It’s sort of like a flea biting an elephant, an elephant the size of 3 Manhattan’s (to quote that newest of SI measurements). :)”
I fail to see the comparison.
Tell me opening a 100 foot wide channel (this is the width of the largest ice breaker) 100’s of miles long in ice which is being compacted, dispersed and put under all sorts of pressure, will have no impact and I’ll suggest I think that your full of it.
Lots of ice is lost each year as it flows out the circle into warmer waters. How much of this ice was separated from bigger sheets by the action of icebreakers. Answer that before providing inane response like the one you provided above.
Oh and the icebreaker Healey mentioned in an earlier post is 82 feet wide. Do you have any idea how many miles of ice it has ploughed through in its short history of Arctic operations?
Walt, could you explain this change?: http://img821.imageshack.us/img821/7995/animateanda.gif
(The first image was provided by Fowler and Maslanik for the august ARCUS sea ice outlook. The second image is that used in the animation you posted above)
Why Fowler and Maslanik have changed their own sea ice age data??
Ice breakers would probably increase iceformation because they create so called polynyas (open areas of water) in the ice. The arctic ice sheet is not a contiunous icesheet but rather very dynamic with open areas cracks, ice floes stacking on top of eachother, ice crumbeling and freezing together again and so on. If this was not so the iceformation would be much lower because as soon as the ice sheet is solid ice formation slows to a crawl because the icesheet isolates the water from the cold air, blocks radiation and evaporation from the surface. Polynyas increase ice formation by allowing water to be exposed the the arctic cold. In other words, if you crack the ice the arctic waters will loose more heat. So actually strong winds will increase ice formation as log as the wind doesent blow the ice out of the arctic or bring warm water in contact with the ice.
David W, Walt Meiers also said it was not a factor, though he didn’t use the word baloney. My comment wasn’t inane, it precisely pointed out the size of the effect it has on the Arctic with a fun analogy.
A 100 mile channel 100 foot wide is approximately 5 Km^2 in area. The minimum ice extent is approximately 1 million times as much. If you instead take it as amount of new edge produced, 200 miles, then I would guess the fraction compared to the whole of the amount of ice edge in the Arctic is even less, a billionth?
I’m sure people “want” things to be true rather than accepting when things are not.
Andy
Note: Inconsistencies in the data of multiyear ice
http://translate.google.es/translate?u=http%3A%2F%2Fdiablobanquisa.wordpress.com%2F2010%2F10%2F22%2Faviso-inconsistencias-en-los-datos-de-hielo-multianual%2F&sl=es&tl=en&hl=&ie=UTF-8
[quote]This is a great question in that it encompasses something that I think is often misunderstood. The reason we know the ozone hole is different this time is that we know the chemistry. Scientists did experiments that demonstrated how under conditions in the Antarctic stratosphere, CFCs break down ozone. And studies were done that showed how CFCs emitted by humans work their way up into the stratosphere.[/quote]
That doesn’t explain why Antarctic ozone hole is larger than the Arctic one, when most of the CFC were consumed and produced in the Northern hemisphere.
There is no ozone hole, it is just that the ozone layer is thinner at the poles, The reason? Sun radiation is responsible or making ozone, and since there is less radiation in the poles, then the ozone layer is thinner.
And it has been always thinner in the south hemisphere. Do you want me to probe it. Look at the aboriginals of the southern hemisphere, they have darker skin than the ones of the northern hemisphere, to fight against the extra UV radiation.
AndyW says:
October 22, 2010 at 3:00 am
David W, Walt Meiers also said it was not a factor, though he didn’t use the word baloney. My comment wasn’t inane, it precisely pointed out the size of the effect it has on the Arctic with a fun analogy.
A 100 mile channel 100 foot wide is approximately 5 Km^2 in area. The minimum ice extent is approximately 1 million times as much. If you instead take it as amount of new edge produced, 200 miles, then I would guess the fraction compared to the whole of the amount of ice edge in the Arctic is even less, a billionth?
I’m sure people “want” things to be true rather than accepting when things are not.
Andy
Walt Meier’s comments seem to indicate he hasnt even explored the possiblity but rather just glibly dismissed it without thinking about it. But I guess when you work for an organisation that is not prepared to look at anything beyond CO2 as a cause of Arctic Ice loss, his response isnt surprising.
Now lets look at your argument on ice edge. The circumference of the entire arctic circle is only about 17,000km. Even given a degree of break up during the melt season I think your argument of the a 100mile or 160km channel (and thats from one icebreaker) being only a billionth of the total ice edge is clearly ludicrous. Perhaps if the entire arctic was split into 1km blocks you might be close to being right but this clearly isnt the case.
It is very clear that icebreaker activity from not just one but many ships operating in the area is crisscrossing the ice edge with mazes of channels. This is allowing large chunks of ice to break off and be transported out the circle.
As far as Peter arguments go, they dont seem to make much sense either. Your argument is only valid if the ice stays in one spot. Unfortunately it doesnt, it moves around and flows into places like the Fram Strait where it then gets transported into warmer waters.
If you were right Peter, then arguments about rotten ice make little sense. We’d see a lot more Polynyas and by your logic the entire Arcitc should have refrozen this melt season with so many patches of open water.
I suspect your argument about polynyas is probably more relevant to ice inside of 80N. If you look at the path of most of the Healy’s trips they are predominantly around the edges. It is this icebreaker acttivity around the edges which has to be the most damaging to the ice pack.