Study Site

Our study area is the S1 Bog of the Marcell Experimental Forest (MEF; 47°30.476′N; 93°27.162′N) in north-central Minnesota, USA (Figure 1). Climate at the MEF is continental with warm moist summers and cold dry winters. Mean annual air temperature from 1961 to 2009 AD was 3.4±1.1°C with a corresponding mean annual precipitation of 780±97 mm (Sebestyen et al. Reference Sebestyen, Dorrance, Olson, Verry, Kolka, Elling and Kyllander2011). Late Wisconsin glacial retreat occurred in the area approximately 13,000 calendar BP (Mooers and Lehr Reference Mooers and Lehr1997) and subsurface ice remained until approximately 11,000 calendar BP (Verry and Janssens Reference Verry and Janssens2011). As this ice melted, overlying sediment collapsed, forming ice block depressions that were the precursors to the area bogs.

Figure 1 Location of SPRUCE site (star in inset map of contiguous US). SPRUCE plots (black points and bolded numbers) with peat cores included in this analysis, overlaying a peat depth map (shading) for S1 Bog. Straight black lines indicate Transects 1–3. Thick outline indicates bog lagg. “D” inside black oval indicates the highest elevation of the raised dome. Map courtesy of Stephen Sebestyen. Elevation maps are available at http://mnspruce.ornl.gov/spatial-data.

The S1 Bog is a 0.081 km^–2 weakly ombrotrophic peatland with a perched water table and little or no regional groundwater influence. Elevation change is minimal across the site (412.7–413.1 m asl). Overstory vegetation is dominated by Picea mariana (Mill.) B.S.P. with Larix laricina (Du Roi) K. Koch also present. The understory is a carpet of mosses in the Sphagnum genus, along with ericaceous shrubs Chamaedaphne calyculata (L.) Moench and Rhododendron groenlandicum (Oeder) Koch. The bog surface is characterized by hummock and hollow microtopography and peat depths range from approximately 2–3 m near the middle of the bog to as much as 11 m near the bog outlet (Parsekian et al. Reference Parsekian, Slater, Ntarlagiannis, Nolan, Sebesteyen, Kolka and Hanson2012). The perched water table, which defines the generally aerobic shallow peat (acrotelm) from the persistently anaerobic deeper peat (catotelm) below, typically ranges from 0 to 30 cm below the hollow surface, but was drawn down to 140 cm below the hollow surface during historical dry periods (Sebestyen et al. Reference Sebestyen, Dorrance, Olson, Verry, Kolka, Elling and Kyllander2011). Previous work on peat characteristics at S1 Bog has supported a lower boundary for the acrotelm at about 30 cm below the hollow surface (Tfaily et al. Reference Tfaily, Cooper, Kostka, Chanton, Schadt, Hanson, Iversen and Chanton2014).

Of particular relevance to our data analyses and interpretations, one 782-cm-long peat core and several shorter cores were sampled from the nearby S2 Bog at MEF between 1983 and 1994 AD (Verry and Janssens Reference Verry and Janssens2011). This site is approximately 1.5 km northwest of the S1 Bog. Details on the methods used and interpretation of measurements made on these peat cores and soil pits can be found in Verry and Janssens (Reference Verry and Janssens2011). These data provide some of the context for interpretation of results reported here, though they may not perfectly reflect the history of the S1 Bog as the two bogs differ in depth to the underlying groundwater aquifer, peat depth, and peat accumulation rates, which are all greater at the S2 Bog. In addition, although both bogs are dominated by a black spruce overstory with sphagnum mosses, the overstory of the S1 Bog was strip-cut in winters 1969–1975 AD (see below) while S2 was not disturbed and some differences in understory shrub and herbaceous communities have persisted since at least 1968 AD (Verry Reference Verry1969).

Two events in the recent past that are specific to the S1 Bog took place during the 20th Century. First, a stand-replacing disturbance, most likely fire or a windstorm, affected the southern end of the bog (where the SPRUCE plots are located) in approximately 1905 AD (Verry Reference Verry1969). This disturbance does not appear to have affected the S2 Bog. Second, the S1 Bog was subject to a strip-cut harvest with initial strip-cutting occurring in 1969 AD and remaining uncut strips harvested in winter 1974–1975 AD (Sebestyen et al. Reference Sebestyen, Dorrance, Olson, Verry, Kolka, Elling and Kyllander2011). Picea and Larix naturally reseeded into each set of strip cuts; the strips harvested in 1969 AD tend to be taller, with a larger basal area, as they were reseeded from mature adjacent strips (1974–1975 AD cuts were reseeded from immature adjacent strips that had been harvested 5 years prior or from a legacy seedbank).

SPRUCE Experiment

The SPRUCE experiment evaluates the response of northern peatland ecosystems to increases in temperature and exposures to elevated atmospheric CO₂ concentrations. The experimental work in the S1 Bog includes a climate change manipulation in 10 enclosures that are 12-m diameter by 8-m tall, focusing on the combined responses to multiple levels of warming including +0, +2.25, +4.5, +6.75 and +9°C (Barbier et al. Reference Barbier, Hanson, Todd, Belcher, Jekabson, Thomas and Riggs2012; Hanson et al. Reference Hanson, Riggs, Nettles, Phillips, Krassovski, Hook, Gu, Richardson, Aubrecht, Ricciuto, Warren and Barbier2017). Half of the warming treatments are also conducted at eCO₂ (~900 ppm). Treatments began in 2014 AD, and both direct and indirect effects of these experimental perturbations are being analyzed to develop and refine models needed for full Earth system analyses. Prior to the selection of 10 plots for the SPRUCE experimental chambers, 16 plots, approximately 20 m apart were laid out across three transects in southern half of the S1 Bog, and were characterized for peatland C patterns and processes prior to the initiation of experimental treatments.

Core Collection and Processing

Peat cores for this study were collected in 2012 AD from the 16 pre-treatment plot locations, which were located in the southern portion of the S1 Bog (Figure 1). Peat physical and chemical data and the metadata describing sampling, handling, and analyses are available online (Iversen et al. Reference Iversen, Hanson, Brice, Phillips, McFarlane, Hobbie and Kolka2014) and have been partly described elsewhere (Griffiths et al. Reference Griffiths, Hanson, Ricciuto, Iversen, Jensen, Malhotra, McFarlane, Norby, Sargsyan, Sebesteyen, Shi, Walker, Ward, Warren and Weston2017; Hobbie et al. Reference Hobbie, Chen, Hanson, Iversen, McFarlane, Thorp and Hofmockel2017). Briefly, and focusing on samples used for this analysis, the SPRUCE plots are located along 3 transects running parallel and roughly northeast to southwest from the western edge of the bog across the domed center. Transect 1 (including plots 4–7) is the southernmost of the 3 transects and is closest to the bog outlet. Transect 2, includes plots 8–11 and 13–14. Transect 3 is the northernmost and includes plots 15–17 and 19–21. Plots 4, 8, 15, and 19 are closest to the bog lagg, a transition zone along the bog edge where runoff collects and is transported laterally to the bog outlet. In contrast, plots 6, 10, 13, 17, 20, and 21 are farthest from the lagg edge. Elevation increases from south to north and from west to east such that plots 21 and 17 are closest to the bog’s higher elevation, domed center (Figure 1 and Table 1).

Table 1 Profile locations, peat depths, estimated basal ages, and long-term apparent carbon accumulation rates, and depth to peak radiocarbon content.

¹ Profile names followed by NT are cores taken from non-treed locations. All other profiles are from treed locations.

² Elevation from central wells of SPRUCE plots from Griffiths et al. (Reference Griffiths, Hook and Hanson2016).

³ Position refers to proximity to the bog edge and lagg area. N=near lagg, M=middle of transect, F=far from lagg.

⁴ Basal ages derived from age-depth profiles that extended to the bottom of the deepest dated depth increment.

Peat cores were from the hollow surface assigned the depth of 0 cm; all depths below the surface of the hollow are assigned negative values throughout the remainder of the text. Cores were taken from locations within 1.5 m of Picea mariana or Larix laricina trees. For plots 4 and 5, additional peat cores from areas with no trees in the immediate vicinity were taken to assess the potential effect of tree cover on peat characteristics (referred to as non-treed). Cores were taken using a 7.6-cm-diameter, 18-cm-long hole saw for surface peat (to –30 cm) and a 5-cm-diameter, 50-cm-long Russian corer for deeper peat (from –30 to –200 or –300 cm). Cores were cut in the field into 10-cm depth increments to –100 cm depth, cut into 25-cm increments from –100 to –200 cm depth, and left in 50-cm increments from –200 to –300 cm depth (or shallower depth if mineral soil was encountered). For each plot, 3 adjacent cores were taken from each sampling location type (treed/non-treed) and peat was bulked and homogenized for each location type, depth increment, and plot. Samples were frozen at –20°C; and shipped to Oak Ridge National Laboratory for further processing.

Each peat depth increment was thawed, oven-dried at 70°C to determine gravimetric water content, and the dried peat was then ground into a fine powder; vascular plant material was not removed prior to these analyses. Carbon concentration was measured on a LECO TruSpec elemental analyzer (LECO Corporation, St. Joseph, MI) at Oak Ridge National Laboratory. Carbon stock was calculated using carbon concentration, depth increment, and bulk density, which was calculated from dried mass and sample volume. Ash content was determined after combustion at 450°C for 6 hr. A subset of 180 peat samples was selected for ¹⁴C analysis. This subset included one peat profile from treed locations for each plot and one additional profile from non-treed locations for plots 4 and 5. Cost precluded ¹⁴C of all depth increments, so for depths below –50 cm, only alternating depth increments were selected for this analysis. The deepest increments were excluded from further analysis if these samples included high mineral content, identified as samples with ash contents ≥23% as these had higher bulk densities, lower carbon concentrations, and younger ¹⁴C ages than the overlying peat layers because we suspect bulk peat included mineral material from the ancient lake bottom below the peat bog (see Table 1 for maximum peat depth by profile).

To provide higher-resolution dates and to test the validity of using large increment bulk peat ¹⁴C measurements to construct age-depth profiles and model C accumulation rates, three additional shallow (to –50 or –100 cm) cores were collected from hollow locations in three of the SPRUCE plots in June 2015. These cores were collected using the same methods as those collected in 2012, except that only one core was taken and peat was cut into 1–2 cm depth increments in the field. These samples were stored frozen and a subset thawed for the selection of specimens for ¹⁴C analyses from depths of interest. For peat slices above –35 cm, Sphagnum moss tissues were picked for ¹⁴C analysis to reduce integration or reservoir effects to the greatest degree possible (i.e., by avoiding fungal and vascular plant tissues including roots). A few deeper peat samples were selected to provide additional dates for specific layers of interest. In August 2015, SPRUCE collaborators found charcoal in 2 additional peat cores collected for other analyses and provided the appropriate peat layers (–55 cm and –68 cm depths) for ¹⁴C measurement. For pre-bomb peat layers, plant macrofossils or charcoal were selected, rinsed with DI water, and pretreated with 0.5 N NaOH to remove dissolved organic carbon (DOC), which has been found to be young relative to the bulk peat at the site even at depth (Tfaily et al. Reference Tfaily, Cooper, Kostka, Chanton, Schadt, Hanson, Iversen and Chanton2014).

Radiocarbon Measurements and Statistical Analysis

Radiocarbon (¹⁴C) values were measured on the Van de Graaff FN accelerator mass spectrometer (AMS) at the Center for AMS at Lawrence Livermore National Laboratory. Samples were prepared by sealed-tube combustion to CO₂ in the presence of CuO and Ag and were then reduced onto Fe powder in the presence of H₂ (Vogel et al. Reference Vogel, Southon, Nelson and Brown1984). ¹⁴C values are reported here in fraction modern, also referred to as FM or F¹⁴C (Reimer et al. Reference Reimer, Brown and Reimer2004), and had an average AMS precision of 0.0026 F¹⁴C. ¹⁴C values were corrected for mass-dependent fractionation with measured δ¹³C values (analyses conducted at the Department of Geological Sciences Stable Isotope Laboratory at University of California-Davis using a GVI Optima Stable Isotope Ratio Mass Spectrometer).

Calibrated Ages

Calibrated peat ages were determined using Calib Version 7.1 (http://calib.qub.ac.uk/calib/) with the IntCal13 calibration curve (Reimer et al. Reference Reimer, Bard, Bayliss, Beck, Blackwell, Bronk Ramsey, Buck, Cheng, Edwards, Friedrich, Grootes, Guilderson, Haflidason, Hajdas, Hatté, Heaton, Hoffmann, Hogg, Hughen, Kaiser, Kromer, Manning, Niu, Reimer, Richards, Scott, Southon, Staff, Turney and van der Plicht2013). For modern samples, calibrated ages were determined using CaliBomb (http://calib.qub.ac.uk/CALIBomb/) run with a compilation of calibration datasets that included IntCal13 (Reimer et al. Reference Reimer, Bard, Bayliss, Beck, Blackwell, Bronk Ramsey, Buck, Cheng, Edwards, Friedrich, Grootes, Guilderson, Haflidason, Hajdas, Hatté, Heaton, Hoffmann, Hogg, Hughen, Kaiser, Kromer, Manning, Niu, Reimer, Richards, Scott, Southon, Staff, Turney and van der Plicht2013) for the pre-bomb period and monthly atmospheric ¹⁴C for the Northern Hemisphere Zone 1 for 1950–2009 AD (Hua et al. Reference Hua, Barbetti and Rakowski2013). For surface peat, a smoothing factor was used based on linear peat accumulation rates for modern peat (generally 10 years to –20 cm and 20 years for –20 cm to –30 cm). Pre-modern peat was insensitive to smoothing. For very young surface samples, age distributions for the recent side of the bomb curve overlapped the end of the calibration curve (2009 AD). These ages were checked manually using NH Zone 1 annual growing season averages in Table 2a from Hua et al. (Reference Hua, Barbetti and Rakowski2013) and assuming an annual decline of 0.0050 F¹⁴C for 2009–2012 AD. For modern peat with 2 distinct calibrated ages, one corresponding to either side of the atmospheric bomb curve, profile ¹⁴C values and calculated peat accumulation rates were used to identify the correct calibrated age. Calibrated dates for picked Sphagnum mosses, plant macrofossils, and charcoal from small depth increments were determined using the same approach as described above, except that for modern Sphagnum, a smoothing of 4 months (a single growing season) was used and calibrated ages that corresponded only to winter months were excluded.

Table 2 Carbon accumulation rates and standard errors in g C m^–2 yr^–1 for all profiles and time periods during the Holocene. For non-linear regression models, standard errors were propagated from parameter errors. (For model fit and parameters, see Tables S3 and S4.)

¹ Carbon accumulation rates calculated using Equation 1 from modeled I and k with standard errors propagated from model generated standard errors on I and k.

² Carbon accumulation rates and standard errors determined by linear regression where accumulation rate is equal to the slope of the fitted line. In cases with only 2 data points, no error can be determined.

³ Carbon accumulation rates modeled for entire late Holocene period or calculated from a time-weighted average of sub-periods (if there are data in the Late_a and Late_b columns). Rates for profiles 13 and 15 were determined using linear regression over the entire late Holocene period.

⁴ Unusually low bulk density in one of the peat increments included in the Recent Accumulation model resulted in very low carbon accumulation with a high propogated error.

Age-Depth Models

Age-depth models were determined for each profile separately using Bacon 2.2 (Blaauw and Christen Reference Blaauw and Christen2011) and with IntCal13 and Northern Hemisphere Zone 1 calibration curves. For each age-depth model, the age at the surface (0 cm depth) was set at the year of sampling. The middle depth for peat depth increments was used for constructing the age-depth models and models only extended to the bottom of the deepest depth increment for which ¹⁴C was measured. Prior information for accumulation rate was set as a gamma distribution with shape 2 and mean 20. In addition to being the default values used in Bacon and described and demonstrated in Blaauw and Christen (Reference Blaauw and Christen2011), this was a reasonable estimate based on peat accumulation data available for the area (Verry and Janssens Reference Verry and Janssens2011). Prior information for memory (high values correspond to high correlation in accumulation rate between peat layers) was set with mean=0.4 and strength=10, because our core data suggested a weaker correlation between depths than the default value of 0.7 and our preliminary model runs suggested a sharper peak for the distribution of the memory effect than the default value of 4.

Linear Apparent Carbon Accumulation Rates

Apparent long-term rate of carbon accumulation (LORCA) was calculated for each complete profile to provide an indicator of carbon accumulation over the lifespan of the peatland. Because we used relatively thick peat layers and assumed the bulk mean age is the age of the peat in the middle depth of the peat layer, extrapolated median ages for the bottom of the deepest peat layer from the age-depth models served as estimates for basal peat age. Total carbon storage in the profile was divided by estimated basal age to provide LORCA for each profile. To investigate apparent carbon accumulation rates (CAR) over time, we also calculated CAR for each individual peat layer as the carbon stock divided by the difference in median age (derived from the profile age-depth model) of the top and bottom of the peat layer.

Non-Linear Carbon Accumulation Rates

LORCA and CAR are simple linear calculations and do not account for input and decomposition. To provide additional insight into the mechanisms behind changes in CAR over time and to provide estimates of input and decomposition rates for other modeling activities, we modeled carbon accumulation rates over time (Trumbore and Harden Reference Trumbore and Harden1997; Hicks Pries et al. Reference Hicks Pries, Schuur and Crummer2012) based on the model for peat bog carbon accumulation described in Clymo (Reference Clymo1984). The model assumes that the net change in carbon storage (dC/dt) is determined by the balance between annual carbon inputs (I in g C m^–2yr^–1) and decomposition (kC, where k is the first-order decomposition rate constant in yr^–1 and C _t is the organic C inventory in year t):

(1) $$dC/dt{\equals}I-kC$$

Solving this equation yields:

(2) $$C_{t} {\equals}C_{0} {\times}e^{{-kt}} {\plus}\left( {I/k} \right){\times}\left( {1-e^{{-kt}} } \right)$$

None of the accumulation curves required a positive C₀, so the C₀ term was dropped and an x-axis intercept, t_i, was introduced:

(3) $$C_{t} {\equals}\left( {I/k} \right){\times}\left( {1-e^{{-k\left( {t-ti} \right)}} } \right)$$

This time shift can be interpreted as a period in time prior to sampling in 2012 that carbon accumulation stopped. Only 3 of the 18 profiles could be fit to a single curve because of a considerable shift in CAR around 3300 cal BP (see Results section, Figure 5b, and Figure S1). Therefore, three separate curves were fitted for recent accumulation rates (in the acrotelm) and two time-periods in the catotelm, before and after 3300 cal BP. Using this non-linear approach, we provide additional insight into the role of changes in input rates versus decay rates in explaining this distinct shift in carbon accumulation.

For each peat profile, Equation 3 was fit to a plot of accumulated carbon inventory (C _t ) versus time (t) using the “nls” function in R to obtain estimates of I and k. For depth increments with ¹⁴C measurements (most cases, including shallow peat layers), calibrated ages were used for t. Measured ages were used when possible to remove biases in ages from age-depth models for recent peat and because little difference was found between modeled and measured ages for deeper peat (see Results and Figure 3). For depth increments with C inventory data but no ¹⁴C measurements, ages for the middle of the increment were taken from the Bacon age-depth model. Accumulation rates were then calculated using model-derived I and k and measured cumulative C inventory using Equation 1, where dC/dt is equal to accumulation rate.

Statistical Analyses

Where appropriate, means are reported ±1 standard deviation. The role of sampling location within the study area on estimated basal ages and LORCA was assessed using transect as an indicator of proximity to bog outlet and proximity to the bog lagg area as assessed from site maps and aerial photos. Relationships between profile location, peat properties, age, and CAR or LORCA were assessed with correlation analysis (reported r values are Pearson correlation coefficients), mixed effects analysis of variance, and multiple linear regression with an alpha value of 0.1. Because CAR was extremely high and variable in the acrotelm compared to the catotelm, an additional set of statistical tests was conducted with only the catotelm portion of the peat profiles, defined as depths below 30 cm. All data analyses were performed in R version 3.1.1 (R Core Team 2014).