Thorsteinsson et al. sediment or cells derived from 15 ml aliquots from each sample were cultured on PCA agar at 30!C for 3 days. Significant microbial growth was observed in all samples (Table 2), but those that had been exposed to the UV radiation (samples 3–5) contained far fewer cultivable cells than the other samples. The lowest cell counts were found in a sample collected from the drill stem. The growth at 30!C is probably due to mesophilic contaminates, whereas the low tempera- ture growth indicates the presence of psychrotolerant bacteria in the snow (and hence in all samples taken from the drilling system during operations). Additional testing of the sterilization efficiency of the drilling system was carried out in two sepa- rate tests at the NEA workshop during spring 2006 (Table 3). The system was filled with 70% ethanol 2 hours before the start of each of these two tests. The heater within the high pressure pump (unit 2D) was now run at maximum temperature (150!C), and the water/steam mixture emerging at the drill tip was found to be at 99!C. The snow used in Test 1 (March 8) was collected near Reykjavík. For Test 2 (May 22) no snow could be obtained and the snowmelter was thus filled with tap water. In Test 2, the water was deliberately spiked with a known number of viable Escherichia coli bac- teria and samples were collected when the concentra- tion of bacteria in the system had reached 3.2!104 cells/ml. Standard methods accredited by the Ice- landic standard ÍST EN ISO/IEC 17025 and New York State Department of Health, Environmental Lab- oratory Approval Program (ELAP) were used in the biological analysis of the samples collected during these tests. In NEA Test 1, culturing at 3!C showed no ev- idence for growth of psychrotolerant bacteria in the snow sample or the samples collected from the sys- tem. Relatively few mesophilic contaminants, indi- cated by growth at 22!C, were found in the system. The number of mesophilic bacteria decreased slightly after in-line filtering and dropped significantly after UV radiation. In this test and the Langjökull test, the mesophiles likely originated from the snowmelter which was not washed with 70% ethanol prior to the tests like other parts of the system. In the test with spiked tap water (NEA Test 2), the number of viable cells was dramatically attenuated by UV and reduced to undetectable levels by heating. It is not straightforward to explain the difference between the results shown in Table 3 and those ob- tained in the Langjökull test. Two possible factors are the higher temperature in the test performed at NEA and the use of 70% ethanol (a more effective disin- fectant than the 95% solution used in the Langjökull test) in the system before the start of operations. The absence of psychrotolerant bacteria in the snow col- lected near Reykjavík (Test 1) is also unexplained. Chemical analysis of drilling water During the drill test on May 22 (Test 2 in Table 3), samples were collected from the system for chem- ical analysis to determine the background concen- trations of ions released into the meltwater by drill system components. The samples were taken from the water container (filled with tap water), from the sampling location S1 (Figure 1) and from the drill stem outlet. The water samples were filtered on site through 0.2µm Teflon filters into polypropylene bottles. Samples for determination of cation and trace metal concentrations were acidified (Teflon dis- tilled Suprapur!, Merck), but samples for anion con- stituents were not treated. Amber glass bottles were used to collect samples for determination of pH and total dissolved CO2. To prevent any organic growth or decay, samples for the determination of nutrients were frozen (-18!C) within hours of collection and kept frozen until analyzed. The concentrations of ma- jor cations and trace metals were analysed using ICP- AES and ICP-SFMS techniques, respectively, and the concentrations of major anions and nutrients were analysed using RF-IC. The results are given in Ta- ble 4. The composition of the water did not change sig- nificantly as it was run from the snowmelter through the drill system. The concentrations of major ele- ments, most trace metals as well as nutrients are, es- sentially, the same in the container, at the inlet and outlet of the drill system. A few metals are, however, slightly enriched at the inlet and outlet of the drill sys- tem compared to the snowmelter, including Zn, Pb, 76 JÖKULL No. 57

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