Biogeosciences, 5, 925–935, 2008 www.biogeosciences.net/5/925/2008/ © Author(s) 2008. This work is distributed under the Creative Commons Attribution 3.0 License. Biogeosciences Small scale controls of greenhouse gas release under elevated N deposition rates in a restoring peat bog in NW Germany S. Glatzel1, I. Forbrich2, C. Kru¨ger3, S. Lemke3, and G. Gerold3 1University of Rostock, Faculty for Agricultural and Environmental Sciences, Landscape Ecology and Land Evaluation, Justus von Liebig Weg 6, 18059 Rostock, Germany 2Ernst Moritz Arndt University Greifswald, Institute for Botany and Landscape Ecology, Grimmer Straße 88, 17487 Greifswald, Germany 3University of Go¨ttingen, Landscape Ecology Unit, Institute of Geography, Goldschmidtstraße 5, 37077 Go¨ttingen, Germany Received: 16 November 2007 – Published in Biogeosciences Discuss.: 16 January 2008 Revised: 16 May 2008 – Accepted: 26 May 2008 – Published: 11 June 2008 Abstract. In Central Europe, most bogs have a history of drainage and many of them are currently being restored. Success of restoration as well as greenhouse gas exchange of these bogs is influenced by environmental stress factors as drought and atmospheric nitrogen deposition. We deter- mined the methane and nitrous oxide exchange of sites in the strongly decomposed center and less decomposed edge of the Pietzmoor bog in NW Germany in 2004. Also, we examined the methane and nitrous oxide exchange of mesocosms from the center and edge before, during, and following a drainage experiment as well as carbon dioxide release from disturbed unfertilized and nitrogen fertilized surface peat. In the field, methane fluxes ranged from 0 to 3.8 mg m−2 h−1 and were highest from hollows. Field nitrous oxide fluxes ranged from 0 to 574µg m−2 h−1 and were elevated at the edge. A large Eriophorum vaginatum tussock showed decreasing nitrous oxide release as the season progressed. Drainage of meso- cosms decreased methane release to 0, even during rewet- ting. There was a tendency for a decrease of nitrous oxide release during drainage and for an increase in nitrous ox- ide release during rewetting. Nitrogen fertilization did not increase decomposition of surface peat. Our examinations suggest a competition between vascular vegetation and den- itrifiers for excess nitrogen. We also provide evidence that the von Post humification index can be used to explain ni- trous oxide release from bogs, if the role of vascular vegeta- tion is also considered. An assessment of the greenhouse gas release from nitrogen saturated restoring bogs needs to take into account elevated release from fresh Sphagnum peat as well as from sedges growing on decomposed peat. Given the high atmospheric nitrogen deposition, restoration will not be able to achieve an oligotrophic ecosystem in the short term. Correspondence to: S. Glatzel (stephan.glatzel@uni-rostock.de) 1 Introduction Due to the high amount of carbon stored in the peatlands of the world and the sensitivity of biogeochemical processes in these ecosystems to climate change, research on matter cy- cling in peatlands has received considerable interest. Espe- cially the release of greenhouse gases (GHG) as carbon diox- ide (CO2), methane (CH4), and nitrous oxide (N2O) from peatlands has been the focus of biogeochemical research due to its potential contribution to feedbacks to global warming. Despite large areas of (often degraded) peat bodies in tem- perate regions, research on peat bogs is mostly from natural boreal sites and focuses on the role of the water table (Roulet et al., 1992; Nyka¨nen et al., 1998; Blodau, 2002). In temperate Germany, widespread drainage of bogs re- sulted in a serious decline of peatland area. Today, in NW Germany (Lower Saxony) merely 5% of formerly 2348 km2 bog area remain undisturbed or in a close to natural state (Schmatzler, 1990). Therefore, protection of the remaining intact peat bogs is accompanied by restoration efforts in mod- erately degraded bogs. The most important environmental constraints on the successful restoration of these bogs are i) a low water table, a result of previous drainage and climate change, ii) atmospheric N deposition, and iii) strong decom- position of degraded peat. The importance of water table on GHG release from peat has been discussed extensively (Blodau, 2002). CO2 evolu- tion follows an optimum function, with highest rates at an intermediate water table (Glatzel et al., 2006). Magnitude and important parameters of CH4 emission from wetlands are well known (Le Mer and Roger, 2001). Drainage de- creases CH4 release and rewetting does not necessarily lead to an immediate rise in CH4 release (Tuittila et al., 2000). Jungkunst and Fiedler (2007) stress the role of water table on GHG release and emphasize the climate control on the nature of the relation between water table and GHG release. Published by Copernicus Publications on behalf of the European Geosciences Union. 926 S. Glatzel et al.: Greenhouse gases German bog Nutrients that may limit decomposition include nitrogen (N) and phosporus (P) (Gu¨sewell and Freeman, 2003). In Lower Saxony, even “undisturbed” bogs are subject to ele- vated N deposition of up to 70 kg ha−1 yr−1 (Gauger et al., 2002). At these high N deposition rates, the capacity of Sphagna to take up N is exceeded (Lamers et al., 2000), N concentration in pore water accumulates and plants with high N demand as Molinia caerulea become more competitive (Limpens et al., 2003). An increasing proportion of easily de- composable litter and N enriched Sphagnum tissue enhance decomposition and N mineralization (Lamers et al., 2000; Aerts et al., 1992), facilitating N2O and CO2 release. Gener- ally, in bogs, N2O release is most common in disturbed loca- tions influenced by elevated N content (Regina et al., 1996). N2O production requires the availability of nitrogen and is highest at high soil moisture, but not inundation (Granli and Bøckmann, 1994). Decomposition status of peat controls its potential for fur- ther decomposition. Examinations by Glatzel et al. (2004) demonstrated a decreasing potential for aerobic and anaero- bic CO2 and CH4 production with a rising von Post decom- position index. In the Pietzmoor Glatzel et al. (2006) ex- plained increased CO2 release from Sphagnum hollow peat compared to hummock peat by lower decomposition rates of hollow peat. Alm et al. (1999) remarked that increased NO3 availability may be due to high decomposition, increasing rates of N2O emission from drained peatlands. In this contribution we intend to add understanding on the influence of these controls on the GHG release of a restoring temperate bog. Previous investigations (Glatzel et al., 2006) have shown the effect of drought on decomposition rates. Specifically, we investigate the influence of a drawdown in water table and peat properties on methane and nitrous oxide release in a restoring peat bog and the influence of nitrogen on decomposition of surface peat. We hypothesize that i) drought decreases the CH4 and N2O release in the bog and rewetting temporarily increases CH4 and N2O release, ii) de- composition of peat controls CH4 and N2O release, and iii) atmospheric nitrogen deposition accelerates decomposition of surface peat. 2 Site and methods 2.1 Research site The study site was the Pietzmoor (Lower Saxony; NW, Ger- many; 53◦06′ N; 9◦50′ E). It is part of the nature reserve Lu¨neburger Heide. The bog is located on the eastern edge of the closed occurrence of rainfed bogs in NW Germany. Mean annual precipitation is 790 mm; mean annual temper- ature is 8◦C. The examination period was March to Septem- ber 2004. Atmospheric N deposition is ca. 22 kg ha−1 yr−1 (Fottner et al., 2004). Today, the Pietzmoor is moderately de- graded. Manual peat extraction at the edges of the Pietzmoor was conducted between the 16th century and 1960. Deep drainage ditches, constructed in the 19th century further de- graded the bog, resulting in increased growth of birch (Betula sp.) and pine (Pinus sp.). Since 1970, when restoration ef- forts began, drainage ditches have been closed and trees cut. This resulted in formation of a recent superficial acrotelm with Sphagnum spp. growing in many hollows. Hummocks are still dominated by Empetrum nigrum, Calluna vulgaris, and Eriophorum vaginatum. 2.2 Field CH4 and N2O flux determination Between March and August 2004, CH4 and N2O fluxes were determined 14 times employing a closed chamber method (Hutchinson and Livingston, 1993) at 10 locations within the Pietzmoor bog. Of the 10 previously installed collars (cover- ing 0.068 m−2), five collars were installed in the center and at the edge of the bog. Six collars covered hummocks and four collars covered hollows. Hummocks were 20 cm ele- vated compared to hollows. They dominate the site resulting in a high coverage of Calluna vulgaris, which is typical for dry degraded peatland sites (Rathert, 2004). Due to the pro- tection status of the site it was not possible to construct a system of boardwalks. However, CH4 fluxes are generally low and we did not find stepwise nonlinear concentration in- creases in our measurements that would have been a sign for ebullition events (e.g. Chanton and Whiting 1995). Hence, we assume no risk of severe disturbances in our measure- ment setup. Among the hollow collars, two were vegetated by Sphag- num fallax, one hosted a small Eriophorum vaginatum tus- sock and one contained no living vegetation. Among the hummock collars, three were vegetated by Calluna vulgaris, one contained a big and one a small Eriophorum vaginatum individuum, and one was inhabited by lichens. These collars covered the range of microsites in the bog previously deter- mined by Rathert (2004). For gas flux determination, gas samples from the closed chamber were sampled by syringe five times in 5 minute in- tervals and transported to the laboratory in Go¨ttingen. On the evening of the day of sampling, the 60 mL syringes were attached to an autosampler coupled to a Shimadzu GC-14B gas chromatograph and a set of four different calibration gas cocktails (described by Loftfield et al., 1997). Precision of analysis was 0.4% for CH4 and 1.0% for N2O. As no sat- uration effects were found, fluxes were calculated from the linear slope of the concentration change over time (Lessard et al., 1994) taking into account the headspace temperature and the coefficient of determination for each regression. 2.3 CH4 and N2O release from mesocosms This experiment was set up to test the first hypothe- sis. Twelve undisturbed peat cores (diameter 15 cm) were sampled by cutting the peat at the outside of tube and Biogeosciences, 5, 925–935, 2008 www.biogeosciences.net/5/925/2008/ S. Glatzel et al.: Greenhouse gases German bog 927 simultaneously pushing the tube above the cut peat until av- erage 23 cm of peat were inside the tube. All cores were taken from hollows, six in the center and six from the edge. The peat cores were transferred into 30 cm high mesocosms that enabled sampling of percolating water and gas concen- trations from a 7 cm headspace. Peat cores were watered in three day intervals with artificial Schneverdingen rain (di- luted ammonium nitrate solution set to a pH of 4.5, equiv- alent to an amount of 790 mm yr−1 and 20 kg dry and wet N deposition ha−1 yr−1). As suggested by Blodau et al. (2004), a two month equilibration phase preceded the experiment. During the equilibration phase, the water table was set to 7 cm below ground, which is a compromise between flooded conditions that were found in the hollows and much drier conditions in the hummocks. The cores were stored at 20◦C close to windows, allowing a natural night and day regime. Vegetation (Sphagna and small herbs, no large plants) con- tinued to grow during the experiment. The experiment consisted of three phases. The pre- drainage phase preceded the drainage phase. During this phase, the six manipulated cores were subjected to free drainage (restricted to 100 mL d−1) without applying low pressure. At the control cores water table remained close to the peat surface. During the second phase (drainage phase), the manipulated cores were subjected to free drainage. The third phase (post-drainage phase) began by closing the drainage at experimental cores and the daily addition of 40 mL artificial Schneverdingen rain until the water table was back to 7 cm below ground. The pre-drainage phase lasted 5 to 8 days, the drainage phase until the elimination of standing water lasted 5 to 6 days and the regeneration of high water ta- ble (post drainage phase) took 12 to 14 days. During the experiment, we determined gas fluxes from all cores as described above (except for a 30 s sampling interval due to the small headspace) daily. Following the experiment, carbon (C) and N concentration of peat from all cores was determined. This was done by drying peat at 45◦C from all horizons, milling it to 0.25 mm and analysis by combustion at 900◦C in a LECO CN- Analyzer (LECO, St. Joseph, MI, USA). The C and N concentration of all horizons were av- eraged to 0–15 cm depth. We also estimated the von Post humification index at all cores. These examinations on peat properties enabled us to test the second hypothesis. 2.4 CO2 evolution from incubated disturbed samples In order to test the third hypothesis, we sampled peat from 0–10 cm depth from Calluna hummocks and Sphagnum hol- lows in the Pietzmoor. Approximately 20 g of peat were set to 75% water content, which yields intermediate rates of CO2 evolution (Glatzel et al., 2006) and placed in 400 mL jars in triplicate. All samples were additionally moistened by one mL of liquid. The fertilized samples received 0.036 M am- monium nitrate solution (equivalent to 50 kg N ha−1), and the unfertilized control samples received plain water. The incu- Fig. 1. Water table at the center and at the edge of the research site in the Pietzmoor from March to August 2004. bation experiment was conducted using the method by Iser- meyer (1952) following the experimental design described Glatzel et al. (2006). Briefly, evolved CO2 was absorbed by 20 mL of 0.1 M NaOH adsorption inside the jars. Sampling of NaOH placed in small containers) following 1, 3, 6, 11, 17, 28 and 42 days of incubation and titration with 0.1 M HCl allows the calculation of CO2 evolved since the preced- ing sampling date. 2.5 Ancillary measurements and statistical procedures We measured air temperature and precipitation at a weather station located 2 km from the field site and installed an air temperature logger 20 cm above the surface of the bog. We determined water table by previously installed wells at the bog center and edge 14 times between March and August 2004 in hollows at the center and the edge of the Pietzmoor. All data sets were tested for normal distribution using the Kolmogorov-Smirnov test. Data on N2O release and day of year (Fig. 3) was normal distributed, so Pearson’s correla- tion coefficient was calculated. The other data was generally not normally distributed, and n was generally small, so cor- relation analyses were carried out using Spearman’s rho test and differences between data subsets were analyzed using the Wilcoxon test employing the Statistica 6.1 software package (Stat Soft, 2004). The outcome of these tests was the basis for rejection or acceptance of the hypotheses. 3 Results 3.1 Weather and water table The field season was warmer and wetter than the long term mean (1989 to 2004). Between March and August 2004, we recorded 427 mm precipitation as opposed to a long term mean of 381 mm. Mean temperature during the field season was 14.2◦C, compared a long term mean of 13.8◦C. At the www.biogeosciences.net/5/925/2008/ Biogeosciences, 5, 925–935, 2008 928 S. Glatzel et al.: Greenhouse gases German bog Fig. 2. Methane (CH4) and nitrous oxide (N2O) release from hum- mocks and hollows at the center and the edge of the Pietzmoor, Germany. Shown are means and standard deviations of CH4 and N2O release of 14 field gas flux determinations from March to Au- gust 2004 (CH4: (A), N2O: (B)) originating from five center (three hummocks and two hollows) and five edge (also three hummocks and two hollows) locations (CH4: (C), N2O: (D)). Significantly dif- ferent values (Wilcoxon test) are marked with different letters. start of the field season, water table was close to the surface (Fig. 1). Following a rather dry spring, frequent precipita- tion led to a rise in water table until early July. In July and August, water table dropped to 25 cm, but rose again in late August. In the center of the bog, water table responded more quickly than at the edge. 3.2 Field CH4 and N2O fluxes Field CH4 fluxes ranged from 0 to 7.8 mg CH4 m−2 h−1 and averaged 1.2 mg CH4 m−2 h−1. Spatial variability of CH4 fluxes was high, so we were not able to detect significant dif- ferences between the mean CH4 flux from hummocks and hollows and between the collars in the center and at the edge of the bog (Fig. 2), although there was a tendency for ele- vated CH4 release in hollows and at the center of the bog. As the water table at the center was not lower than at the edge, the absence of a significant difference between CH4 release at the two sites is not surprising. Although N2O fluxes in the field were generally low, and often 0 at some collars, we detected a N2O release of up to 574µg m−2 h−1. We found no N2O uptake. There was no difference in N2O release between hummocks and hollows, but at the edge, nitrous oxide release was higher than at the center (Fig. 1) despite the lack of a difference in water table. During the course of the season, CH4 fluxes rose from 0.5 mg m−2 h−1 to 2 mg m−2 h−1 (at some hummocks) and 4 to 8 g m−2 h−1 (at some hollows). This trend could not be noticed at all collars. There was no seasonal trend of N2O Fig. 3. Nitrous oxide (N2O) release from an Eriophorum vaginatum dominated hummock from April to August 2004 and its relation to sampling date at the edge of the Pietzmoor, Germany (n=14). fluxes, except for the collar vegetated by a large Eriopho- rum vaginatum tussock. There, N2O fluxes decreased lin- early with the course of the season (Fig. 3). 3.3 CH4 and N2O release from mesocosms 3.3.1 Methane Methane release from the cores was higher than from field sites, averaging 8.2 mg CH4 m−2 h−1. During the pre-drainage phase, there was no difference in CH4 flux between the control cores and the manipulated cores. During this phase, methane fluxes were be- tween 0.1 and 84.5 mg m−2 h−1 and averaged 7.6±9.1 to 8.7±11.7 mg CH4 m−2 h−1. (Fig. 4) During drainage, the control cores remained at the CH4 release level, emitting −0.1 to 138 mg CH4 m−2 h−1 and averaging 9.4±11.7 mg CH4 m−2 h−1. Methane release of the ma- nipulated cores dropped to 0 to 3.1 mg CH4 m−2 h−1 with a mean release of 0.3±0.4 mg CH4 m−2 h−1. During the third phase, CH4 emissions from the control plots re- mained at 0 to 99.6 mg CH4 m−2 h−1 with an average value of 8.3±12.9 mg CH4 m−2 h−1. During the post- drainage phase, CH4 emissions from the manipulated cores remained at the level of the drainage phase emitting 0 to 11.2 mg CH4 m−2 h−1 and a mean CH4 release of 0.3±0.3 mg m−2 h−1. In summary, CH4 release of the ma- nipulated cores remained at close to zero even when the wa- ter table reached the original position. 3.3.2 Nitrous oxide Variability of emissions of N2O from the cores was higher than the variability of CH4 emissions. During the first phase, N2O release from the control cores was 0 to 1571µg m−2 h−1 (Fig. 5). Previous to drainage, the ma- nipulated cores released 0 to 2255µg N2O m−2 h−1. Thus, Biogeosciences, 5, 925–935, 2008 www.biogeosciences.net/5/925/2008/ S. Glatzel et al.: Greenhouse gases German bog 929 Fig. 4. Methane (CH4) release from peat cores before, during, and following the drainage experiment (open bars). Unmanipulated control cores are black. Mean values and standard deviation from three replicates are shown. Significantly different values (Wilcoxon test) are marked with different letters. control cores released 292±361 µg N2O m−2 h−1 opposed to 163±190µg N2O m−2 h−1 from the manipulated cores, possibly showing an (non significant) effect of beginning drainage. During the drainage phase, N2O release at manip- ulated as well as control cores was lower than during the first phase. Due to the higher emission at the manipulated cores during the pre-drainage phase, this change was significant for the manipulated cores in contrast to the control. During this phase, control cores released 0 to 673µg N2O m−2 h−1 and manipulated cores emitted 0 to 348µg N2O m−2 h−1. The average values were 75±59 and 73±102µg N2O m−2 h−1 for the control and the manipulated cores, respectively. Dur- ing the post-drainage phase, N2O release from the control cores remained at 0 to 1464µg N2O m−2 h−1, with an av- erage of 72±69µg N2O m−2 h−1. The manipulated cores emitted 0 to 1590µg N2O m−2 h−1, with a mean N2O re- lease of 150±157µg m−2 h−1, showing a (non significant) sign of increasing N2O release. In summary, the extremely high variability and the multiple controls of N2O release lead to an incoherent emission pattern. Thus, the mesocosm experiment produced a clear result for CH4 and no clear result for N2O. A lasting suppression of CH4 release during a following drainage is not mirrored by a similar effect for N2O, although there is a tendency for decreased N2O release during drainage and possibly a some- what increased N2O release following drainage. 3.3.3 Properties of the peat cores Simple measures of surface peat point towards stronger de- composition of peat in the center of the bog (Table 1): C and N content in the top 15 cm of the peat cores from the center of the bog were significantly higher than from the edge of the bog. There was no significant difference in the C/N ratio from the cores sampled at the center to the ones sampled at the edge of the bog, but cores from the edge tended towards Fig. 5. Nitrous oxide (N2O) release from peat cores before, during, and following the drainage experiment (open bars). Unmanipulated control cores are black. Mean values and standard deviation from three replicates are shown. Significantly different values (Wilcoxon test) are marked with different letters. Table 1. Carbon (C) and nitrogen (N) concentration and von Post humification index in the top 15 cm of peat cores used for the water table manipulation experiment from the Pietzmoor, Germany. Mean values and standard deviation from six replicates are shown. Signif- icantly different values (Wilcoxon test) within one line are marked with different letters. Center Edge % C (%) 48.28±0.69 a 44.10±0.60 b N (%) 1.59±0.09 a 1.39±0.11 b dimensionless C/N ratio 30.42±1.54 a 31.92±2.42 a von Post index 5.3±0.8 a 2.7±0.7 b a higher C/N ratio. As evidenced by the von Post index, peat from the bog center was more humified than peat at the bog edge. 3.4 CO2 evolution from incubated disturbed samples According to the incubation experiment, N fertilization of surface peat does not control potential CO2 release. In con- trast to sampling depth or peat properties, a wide range of unfertilized and fertilized samples did not differ in the amount of CO2 release throughout the incubation period. Following 42 days of incubation, unfertilized peat released 43.7±40.1 mg CO2 per g of dry peat and fertilized peat re- leased 43.0±45.9 mg CO2 per g of dry peat (Fig. 6). www.biogeosciences.net/5/925/2008/ Biogeosciences, 5, 925–935, 2008 930 S. Glatzel et al.: Greenhouse gases German bog Fig. 6. Carbon dioxide (CO2) release from unfertilized peat and peat fertilized with ammonium nitrate from the Pietzmoor, Ger- many, following a 42 day incubation. Mean values and standard deviation from 17 samples are shown. Significantly different values (Wilcoxon test) are marked with different letters. 4 Discussion 4.1 Field CH4 and N2O fluxes The CH4 fluxes that we measured in the Pietzmoor are within the range previously reported by many authors and recently reviewed by Le Mer and Roger (2001) and Whalen (2005). Although the high spatial variability of CH4 fluxes impedes the interpretation of data, we discuss patterns of CH4 release. The elevated CH4 emissions from hollows at our sites are probably due to the proximity to the water table and a shal- lower aerobic zone of CH4 oxidation (Pelletier et al., 2007; Strack et al., 2004). Furthermore, some of the hollows are covered with Eriophorum vaginatum. Vascular plants, es- pecially sedges are known for high CH4 release (Joabsson et al., 1999; Strack et al. 2006) and Eriophorum vaginatum tussocks are CH4 emission hotspots as they provide substrate for methanogenesis and provide a pathway for CH4 release (Tuittila et al., 2000; Marinier et al., 2004). The somewhat elevated CH4 emissions at the center of the bog cannot be ex- plained by water table. However, due to the higher decompo- sition, field moisture could be higher in the center than at the edge. Only recently, Basiliko et al. (2007) state that mining, alteration and restoration modify the factors controlling CH4 production, e.g. indicated by a strong influence of soil mois- ture content on CH4 production at mined and restored sites while no such correlation could be found at natural sites. In contrast to the hot and dry summer of 2003, the wet sum- mer of 2004 did not cause any drought stress and water table in the center of the bog remained at the same level as at the edge. There was no profound drawdown of the water table. So, water table did not control CH4 release and the highest CH4 release (7.8 mg m−2 h−1) took place on 08/04/04 with 0 1 2 3 4 5 6 7 8 9 0 10 20 30 40 50 hummock hollow m g CH 4 m - 2 h- 1 Water table [cm below surface] Fig. 7. Methane release and water table from the Pietzmoor, Ger- many during the 2004 field season. Shown are individual flux de- terminations from 10 collars and 14 sampling dates from March to August 2004. Water table was corrected for elevation of hummocks by adding 20 cm distance from the bog surface. the water table at 24.5 cm below the surface (Fig. 7). This is in contrast to the well established relationship between CH4 release and water table (Moore and Knowles, 1989, Moore and Dalva, 1993) and the idea of water table acting as an “on-off-switch” for CH4 emissions. The rather steady in- crease of maximum CH4 emissions with a rising water ta- ble documented in Fig. 7 resembles the relation described by Jauhiainen et al. (2005). In contrast to data from boreal regions cited above, results from temperate regions more fre- quently do not confirm a straightforward relation between water table and CH4 release. Fiedler and Sommer (2002) conclude that the effect of water table on CH4 release in sev- eral peatlands of southern Germany is indirect and controlled by more strongly by redox potential, which is rarely deter- mined. Fiedler at al. (2005) state that the thickness of the oxidative zone above the water table does control CH4 re- lease, but also report CH4 emission peaks simultaneously to a slightly falling water table. We are not able to explain the (insignificantly) elevated CH4 emission in the center of the bog. Following the reason- ing of Glatzel et al. (2004), the low degree of humification of surface peat at the edge of the Pietzmoor as evidenced by the von Post index (Table 1) should favor elevated CH4 emission at that subsite. Consequently, the von Post index is an insufficient measure for CH4 release. This is not sur- prising, because this index cannot take into account the func- tion of living plants as Eriophorum vaginatum as conduit for CH4 (Joabbson et al., 1999) and the supply of easily degrad- able compounds in the rhizosphere of Eriophorum vagina- tum (Saarnio et al. 2004). As oligotrophic peatlands are generally N limited, they are usually no sources of N2O (Martikainen et al., 1993). Thus, the field N2O fluxes reported in this contribution are high Biogeosciences, 5, 925–935, 2008 www.biogeosciences.net/5/925/2008/ S. Glatzel et al.: Greenhouse gases German bog 931 compared with these sites. However it must be taken into account that most studies from pristine oligotrophic peat- lands are from boreal sites with rather low atmospheric N deposition (Nordin et al., 1998). Our site has a history of drainage, is located in the temperate zone, experiences high atmospheric N input and a rapid fluctuation in water table (Fig. 1), and, at drought conditions, NO3-N concentrations of 22±31 mg L−1 (Glatzel et al., 2006). The N2O release from the Pietzmoor is higher than the N2O release from a restoring peat bog in S Germany, where Dro¨sler (2005) determined an N2O emission of 1 to 31µg N2O m−1 h−1. According to our research, only cultivated or drained peat- lands release >100µg N2O m−1 h−1. Regina et al. (1999) measured N2O release of 440µg N2O m−1 h−1 in a Finnish drained tall sedge fen. On the other hand, the same authors found that rewetting reduces N2O release from a previously drained birch-pine fen from 50 to 100µg m−1 h−1. Culti- vated sites on organic soils from NW Finland released 70 to 170µg N2O m−1 h−1 (Maljanen et al., 2001). Water table did not control N2O release (Fig. 8). This is not surprising as the field campaign was rather short and N2O release is at its maximum in unsaturated soil (Granli and Bøckmann, 1994). Due to the infamously high spatial and temporal variability of soil N2O emissions (Folorunso and Rolston, 1984), the lack of a difference of N2O release between hummocks and hollows is not surprising. However, the significantly elevated N2O release from the edge of the Pietzmoor compared to its center (Fig. 2) is surprising. Even when there is no difference in water table, nitrous oxide flux from the edge of the bog is elevated. Unfortunately, no N data from peat pore water are available from 2004. How- ever, an increased peat pore water NO3 concentration at the edge of the bog is unlikely: In contrast to the center of the Pietzmoor, NO3 concentrations in the pore water at its edge never exceeded 0.5 mg L−1 between July 2002 and July 2003 (Lemke, 2004). Considering the narrow C/N ratio of surface peat at the center and the edge of the Pietzmoor and the low degree of decomposition at the edge (Table 1), it is possible that the peat itself provided the N source for denitrification. Schiller and Hastie (1996) report N2O release from the de- struction of surface moss following clearfelling, so it is pos- sible that the moss is the N source. This is in line with the findings by Lamers et al. (2000), who found that, at an at- mospheric N deposition rate of 12 to 18 kg ha−1 yr−1, excess N is accumulated in Sphagnum tissue, stored as free N or N- rich free amino acids. Our C/N ratio of 30 is not far from the threshold C/N ratio of 25 for significant N2O emissions reported by Klemedtsson et al. (2005). In Canadian bogs and the Pietzmoor, Glatzel et al. (2004, 2006) found high CO2 re- lease rates from poorly decomposed surface Sphagnum peat. Since CO2 release involves N mobilization and moderately dry conditions are accompanied by the strong CO2 emissions (Glatzel et al., 2006), in phases of moderate dryness, NO3 could be accumulated that is subject to denitrification and N2O release during subsequent wetter phases. 0 100 200 300 400 500 600 0 10 20 30 40 50 hummock hollow Water table [cm below surface] µ g N 2O m - 2 h- 1 Fig. 8. Nitrous oxide release and water table from the Pietzmoor, Germany during the 2004 field season. Shown are individual flux determinations from 10 collars and 14 sampling dates from March to August 2004. Water table was corrected for elevation of hum- mocks by adding 20 cm distance from the bog surface. The decreasing N2O release from the collar with the large Eriophorum vaginatum tussock with the progressing season suggests a competition for excess nitrogen (Silvan et al., 2005). By the end of August, plant uptake of NO3 keeps N2O emission close to 0. This mechanism has been noted by Glatzel and Stahr (2001), where it led to soil N2O uptake. It is interesting that this pattern occurred only where the col- lar was vegetated by a large cottongrass tussock and suggests effective rhizosperic N uptake. It is likely that the wet sum- mer favored rapid plant uptake of NO3 as high soil moisture was found to be connected to efficient N uptake of Phalaris arundinacea (Ru¨ckauf et al., 2004). 4.2 CH4 and N2O release from mesocosms Gas fluxes from mesocosms were higher than from the field. This is due to constantly warm temperatures in the laboratory (Regina et al., 1999) and could, despite the two month equi- libration phase, also be a consequence of an enduring distur- bance effect following field sampling. As disturbance effects are site specific and there is no standard equilibration period, the comparison of the absolute magnitude of gas fluxes from mesocosms is not useful. Thus, the purpose of CH4 and N2O flux determinations from mesocosms is the evaluation of dif- ferences between our treatments. Due to the non-equilibrium conditions caused by the ex- periment, it is difficult to relate water table to gas fluxes. However, in atlantic temperate climates frequent rainfall and subsequent dry phases are common, so the conditions created by our experiment represent the dynamic conditions encoun- tered in the field. www.biogeosciences.net/5/925/2008/ Biogeosciences, 5, 925–935, 2008 932 S. Glatzel et al.: Greenhouse gases German bog 4.2.1 Methane The variability of CH4 fluxes from all mesocosms before drainage and from the control was high, but as a conse- quence, CH4 release from the control mesocosms was not different from the mesocosms that were to be manipulated. Our finding that a water table drawdown brings CH4 re- lease to an end confirms the conclusion by Christensen et al. (2003) that water table acts as an “on-off-switch” for CH4 emissions. Strack and Waddington (2007) report a more differentiated CH4 release pattern as a result of water table drawdown. They show that CH4 release from hummocks may rise following a drawdown due to peat subsidence. CH4 release following drainage to −50 cm also did not decline to zero (Moore and Dalva, 1993), but the peat columns sam- pled by Moore and Dalva were 80 cm in length. Our ex- perimental design however eliminated the anoxic zone, – al- though anoxic pockets may have been preserved –, so dif- ferences due to a differing capacity for CH4 oxidation one might have been able to find in the bog could not be de- tected. It is still interesting that immediately following the beginning of drainage, CH4 fluxes at all mesocosms declined to close to 0. Also, CH4 release did not reappear during the third phase. This confirms findings by Freeman et al. (2002) who reports a suppression of CH4 for >1 month following a drought and Segers (1998) stated that, due slow growth rates, methanogens require a long regeneration period fol- lowing exposition to oxygen. So we are not able to report a hysteresis in CH4 release for the falling and rising limb as detected by Moore and Dalva (1993). 4.2.2 Nitrous oxide N2O fluxes from mesocosms declined with drainage, but did not fully recover following drainage. Increasing N2O release following drainage has been observed in field and laboratory experiments (Freeman et al., 1992, Martikainen et al., 1993, Regina et al., 1999). Dowrick et al. (1999) found that a mod- erate drought (with a water table at −8 cm) did not affect N2O released compared to waterlogging and that a more ex- treme drought (like the one that we simulated) causes an ex- ponential increase in N2O release with water table depth. On the other hand, Nyka¨nen et al. (2002) determined very low N2O release rates although the water table subsided up to −40 cm and one site had been fertilized with 100 kg N ha−1 prior to the experiment. Nyka¨nen et al. (2002) explain the low N2O emission despite fertilization with plant uptake and the accumulation of ammonium (NH4) below the root zone. Another reason for this is probably the low background N load of 6 kg ha−1 yr−1 and some capacity of the peat for ad- sorption of NH4. This is a profound difference to N dynamics of boreal bogs compared to temperate bogs in industrialized regions with high atmospheric N deposition an N loaded peat (Lamers et al., 2000). There is a (non-significant) rise of N2O emissions from the manipulated mesocosm in the post-drainage phase. This could be a consequence of nitrification and an accumulation of NO3 during the drainage phase and denitrification as the water table rises again, explaining the high NO3 concentra- tion in the pore water of the Pietzmoor during the drought in 2003 (Glatzel et al., 2006). Updegraff et al. (1995) em- phasized the relationship between drainage and N miner- alization. Regina et al. (1999) elaborate the link between drainage, high NO3 accumulation and increased N2O release as well as lower NO3 concentrations and N2O release as a consequence of rewetting. Van Beek et al. (2004) concluded that in low-land areas, ground water levels tend to control the magnitude of N losses via denitrification. In summary, although we do not know the reason for the rise of N2O emis- sions in the third phase, there is evidence for denitrification following NO3 accumulation. 4.3 CO2 evolution from incubated disturbed samples The purpose of laboratory incubations is the isolation of con- founding factors and the absolute values obtained by this type of experiment do not approximate field fluxes. Still, Moore and Dalva (1997) suggested that integrated potential produc- tion rates and field fluxes might be similar. In any case, CO2 productions rates from peats do not differ strongly and can be compared (Glatzel et al., 2004). The large variability of CO2 release within the unfertilized and fertilized peat is due to the wide range of peat samples used for the experiment, involving poorly as well as strongly decomposed peat as well as hummock and hollow peat. The absence of any N limitation at optimal peat moisture shows that there is no N limitation of decomposition. Thus, the high N deposition rates in the region do not necessarily di- rectly enhance peat decay, but favor N accumulation in the bog (Lamers et al., 2000). Besides the consequences on CH4 and N2O release discussed above, a change in species com- position is to be expected in case of persistent high N deposi- tion and drought stress. Specifically, the competitiveness of Sphagnum spp. (Lamers et al., 2000, Limpens et al., 2003, Tomassen et al., 2003), Calluna vulgaris (Heil and Bruggink, 1987), and Erica tetralix (Aerts and Berendse, 1988) suffers facing atmospheric N deposition and N mineralization due to water table subsidence in favor of Molinia caerulea (Lamers et al., 2000, Limpens et al., 2003, Tomassen et al., 2003, Heil and Bruggink, 1987, Aerts and Berendse, 1988) and Betula pubescens (Tomassen et al., 2003). 5 Conclusions Our investigations confirm the sensitivity of CH4 and N2O fluxes to water table manipulations. However, our examina- tions show that the water table control is modified by addi- tional factors. Thus, the first part of our first hypothesis – Biogeosciences, 5, 925–935, 2008 www.biogeosciences.net/5/925/2008/ S. Glatzel et al.: Greenhouse gases German bog 933 drought decreases the CH4 and N2O release – is accepted. We were not conclusively able to accept the second part of the first hypothesis – rewetting temporarily increases CH4 and N2O release. One of the additional factors that modify the response of CH4 and N2O fluxes to water table is the degree of decom- position. We add additional evidence to the notion that the von Post humification index can be used to explain N2O re- lease, but not CH4 release from restoring bogs. A large vari- ation of the humification index occurs within small areas. In the strongly decomposed center with scarce Sphagnum cov- erage, N2O release is lower than at the poorly decomposed edge with fresh N-rich Sphagnum. Thus, the second hypoth- esis, – decomposition controls CH4 and N2O release – can be accepted for N2O, but not for CH4. CH4 production appears to be controlled more strongly by plant mediated factors as the CH4 conduit and root exudates. N2O emission could be enhanced when N-rich plant tissue is available for decompo- sition. Our work also examined the effects of N addition to sur- face peat and leads to the rejection of the third hypothesis – atmospheric N deposition accelerates the decomposition of surface peat. The ongoing restoration process in the Pietzmoor aims at the restoration of peatland ecosystems including reestab- lishment of natural vegetation cover, especially Sphagnum mosses, and of the hydrological regime (Rochefort and Lode, 2001). Finally, the return of its functions e.g. accumula- tion of carbon and nutrient cycling is aspired. Realistically, this is only possible when aiming at developing an eutrophic ecosystem rather than restoring an oligotrophic one. Another goal of peatland restoration is the net reduction of the release of CO2 equivalents. This contribution shows that – under conditions of high rates of atmospheric N deposition – it is important to avoid frequent water table fluctuations that may increase N2O release. Especially in periods when NO3 uptake by vegetation is not strong (late autumn to early spring), a high water table must be maintained. At this point, we are not able to judge for how long a water table draw- down with subsequent restoration of high water table will decrease CH4 release. A very low water table may decrease CH4 and CO2 efflux, but likely damages peat forming vege- tation (Glatzel et al., 2006) and may favor growth of species adapted to a fluctuating water table as Molinia caerulea. For this reason, our present state of knowledge suggests that the reduction of the net release of CO2 equivalents in N loaded temperate peatlands depends on a high water table. Acknowledgements. 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