20 April 2006

Onward to Greenland

A month from now I'll be on my way to Jakobshavns Isbrae, a glacier in western Greenland. I'll travel from Fairbanks to Albany, NY, via commercial airlines. From there we'll fly on an Air National Guard plane to Kangerlussuaq, Greenland, and then hop on a smaller plane to Ilullissat. We'll spend a few days in Ilullisaat organizing gear and double-checking everything, and then we'll take a helicopter to our camp site located at the terminus of Jakobshavns (or Sermeq Kujalleq, in Greenlandic). Check it out on Google Earth: our camp site will be located at about 69°07'30"N, 49°43'48"W. The fjord in front of the glacier that is now filled with brash sea ice was occupied by the glacier as recently as 200 years ago. The current terminus position is actually about 5-10 km back from where it appears in the Google Earth image. Sermeq Kujalleq drains 7% of the Greenland ice sheet, is up to 2500 m thick, and flows at a rate of about 15 km/yr at the terminus. Its impressive, so I'm told.

We'll be in the field for about 6 weeks, and then returning to Fairbanks via Copenhagen... We aren't able to fly with the Air National Guard on our return trip so we're forced to take the scenic route. The benefit is that we get to meet with some researchers in Copenhagen - and I'm going to take few days off and explore the city and its surroundings. So if you're going to be in the area... Let's meet!

Something about CO2

From ice core data we have learned definitively that there is a link between CO2 and global air temperature. The following figure shows CO2 concentration and air temperature (from some reference value) as determined from an ice core in Antarctica. Similar patterns have been found in all ice cores.


The C02 concentrations are measured in air bubbles within the ice core. Air temperature is approximated by measuring oxygen isotopes within the ice crystals themselves. Essentially, isotope fractionation occurs when water evaporates from the oceans - since oxygen-18 is heavier than oxygen-16, water molecules containing O-18 require more energy to be turned into water vapor than water molecules containing O-16. Thus the water vapor tends to be "isotopically lighter" than the oceans it has left behind. The water vapor travels poleward (due to temperature/pressure gradients) and encounters colder temperatures. Cold air can't hold as much moisture as warm air so the water vapor condenses and falls as snow or rain. Again, because it is heavier, the O-18 tends to precipitate sooner than the O-16. So it requires rather warm temperatures at all latitudes for O-18 to be found at the poles, and it can therefore be used as a proxy for air temperature.

The large, 100,000-year cycles in air temperature are what are referred to as glacial cycles. There is quite a bit of evidence that suggests that they are controlled by orbital parameters, such as the tilt of the Earth's axis, the ellipiticity of its orbit, and precession (the Earth wobbles like a top over a long time scales). Other factors are also clearly important, such as the distribution of land mass, which is important over much larger timescales (millions of years).

As I mentioned early, there is a strong correlation between atmospheric CO2 concentrations and air temperature, but from the plot above it is very difficult to determine what comes first - a change in CO2 or a change in temperature. (Methane also experiences similar oscillations.) And in fact there are reasons to believe that a rise in temperature can drive CO2 (and methane) concentrations - it can, presumably, force CO2 out of the oceans (and methane out of swamps that were previously frozen). But on the other hand, CO2 is also a "good" greenhouse gas that can trap solar radiation - more on that in a later post.

Two things to note from this figure: (1) the current interglacial period is the longest in the recent geologic past, and (2) CO2 concentrations are currently rising very rapidly and are much higher than any time in the past 400,000 years. I will also discuss this in a later post with respect to what's happened over the last 100 years - since the industrial revolution.

11 April 2006

Field prep

Sorry about the lack of updates lately - it's been a hectic couple of months and I don't think it will get much better anytime soon. Most people would probably take a break after defending their thesis, but not me. I'm busy running in circles trying to get equipment ready for field work. We have to have almost everything sent and on its way through Greenlandic customs (I guess Danish customs, technically) within the next couple of weeks... In retrospect I should've started preparing things sooner, but, well, too late. What this means is that I don't get to enjoy the balmy spring weather as much as I'd like, but I'll get my share of "outdoor time" later in the summer. And anyway, getting field equipment organized is a nice change from sitting in front of my computer, but then again, it is really stressful. There is a lot of time, money, resources, and work going into this field campaign and it'd be a shame to have some major problems just because we forgot to bring along the right size wrench. Plus my Ph.D. will depend largely on how things go over the next few months, so I've got a lot at stake too.

Maybe in my next few posts I'll spend some time discussing my project and field site - I don't have much else on the brain at the moment. Oh, but I did promise to talk more about carbon dioxide and global warming. Hmmm..