Peatland development is affected by changing climates, disturbances such as fire, and autogenic processes. Peatlands may be susceptible to periods of peat loss or reduced accumulation resulting in hiatuses in the peat stratigraphy. At eight minerotrophic peatlands in isolated topographic depressions in western Washington State, peat accumulation rates were reconstructed using radiocarbon-dated continuous peat cores. Age-depth models, fit to 7 to 11 radiocarbon dates and known tephra ages per peatland, were built using a Bayesian approach that constrains the range of potential peat accumulation rates and specifies potential hiatus events at abrupt changes in organic soil composition, tephras, and abrupt changes in the bulk-density profile. The among-site mean long-term rate of organic matter accumulation varied from 30 to 40 g/m2/year during the Late Holocene but was much lower, 18–22 g/m2/year, between 9500 and 6500 year before present. Fifteen modeled hiatuses encompassed 22% of the period in the age depths models and were more common during 9500 to 6500 year before present. During this period, hiatuses suggest that 50% of the potential peat accumulation is missing. Compared to nearby pollen and charcoal records, the hiatal intervals were likely the result of peat loss from a lower water table, fire, or burial by 4–7 cm of Mazama tephra. Sites with small watershed:peatland area ratios had the largest hiatuses and small peatlands in kettle depressions had the smallest hiatuses, consistent with water-table sensitivity to climate change. Charcoal and pollen stratigraphy from hummocks at three sites indicate that fires during the last century occurred near the peat core sites with little impact on organic matter accumulation. The variability in peat accumulation, among sites and over time, suggests site-dependent climatic sensitivity of these biologically and hydrologically significant sites.
AbatzoglouJTDobrowskiSZParksSA, et al. (2018) TerraClimate, a high-resolution global dataset of monthly climate and climatic water balance from 1958–2015. Scientific Data5(1): 170191, Nature Publishing Group.
2.
Aquino-LópezMAAndersonLSanchez-CabezaJ-A, et al. (2024) Bayesian approaches to proxy uncertainty quantification in paleoecology: a mathematical justification and practical integration. Journal of Agricultural, Biological and Environmental Statistics. DOI: 10.1007/s13253-024-00647-5.
3.
BaconKLBairdAJBlundellA, et al. (2017) Questioning ten common assumptions about peatlands. Mires and Peat19: 1–23.
4.
BaiJPerronP (2003) Computation and analysis of multiple structural change models. Journal of Applied Econometrics18(1): 1–22.
5.
BaigJGavinDG (2023) Postglacial vegetation and fire history with a high-resolution analysis of tephra impacts, high Cascade Range, Oregon, USA. Quaternary Science Reviews303: 107970.
6.
BelyeaLRBairdAJ (2006) Beyond “the limits to peat bog growth”: cross-scale feedback in peatland development. Ecological Monographs76(3): 299–322.
7.
BelyeaLRMalmerN (2004) Carbon sequestration in peatland: patterns and mechanisms of response to climate change. Global Change Biology10(7): 1043–1052.
8.
BlaauwMChristenJA (2011) Flexible paleoclimate age-depth models using an autoregressive gamma process. Bayesian Analysis6(3): 457–474.
9.
BlaauwMHeegaardE (2012) Estimation of age-depth relationships. In: Tracking Environmental Change Using Lake Sediments: Data Handling and Numerical Techniques. Developments in Paleoenvironmental Research. Springer, pp. 379–413.
10.
BlaauwMChristenJAMauquoyD, et al. (2007) Testing the timing of radiocarbon-dated events between proxy archives. The Holocene17(2): 283–288.
11.
BlaauwMChristenJABennettKD, et al. (2018) Double the dates and go for Bayes — impacts of model choice, dating density and quality on chronologies. Quaternary Science Reviews188: 58–66.
12.
BrownKJFittonRJSchoupsG, et al. (2006) Holocene precipitation in the coastal temperate rainforest complex of southern British Columbia, Canada. Quaternary Science Reviews25(21–22): 2762–2779.
13.
BrubakerLB (1991) Climate change and the origin of old-growth Douglas-fir forests in the Puget Sound Lowland. In: RuggieroLFAubryKBCareyAB, et al. (eds) Wildlife and Vegetation of Unmanaged Douglas-Fir Forests. USDA Forest Service, Pacific Northwest Research Station, pp. 17–24.
14.
ChambersFMBeilmanDWYuZ (2010) Methods for determining peat humification and for quantifying peat bulk density, organic matter and carbon content for palaeostudies of climate and peatland carbon dynamics. Mires and Peat7(7): 1–10.
15.
CharmanDJAmesburyMJHinchliffeW, et al. (2015) Drivers of Holocene peatland carbon accumulation across a climate gradient in northeastern North America. Quaternary Science Reviews121: 110–119.
ClymoRSFoggGE (1984) The limits to peat bog growth. Philosophical Transactions of the Royal Society of London. B, Biological Sciences303(1117): 605–654, Royal Society.
18.
CrausbaySDHigueraPESprugelDG, et al. (2017) Fire catalyzed rapid ecological change in lowland coniferous forests of the Pacific Northwest over the past 14,000 years. Ecology98(9): 2356–2369.
19.
CwynarLC (1987) Fire and forest history of the North Cascade Range. Ecology68: 791–802.
20.
Dachnowski-StokesAP (1930) Peat profiles in the Puget sound basin of Washington. Journal of the Washington Academy of Sciences20: 193–209.
21.
DaviesMAMcLaughlinJWPackalenMS, et al. (2023) Using Holocene paleo-fire records to estimate carbon stock vulnerabilities in Hudson Bay Lowlands peatlands. FACETS8: 1–26, Canadian Science Publishing.
22.
Delignette-MullerMLDutangC (2015) fitdistrplus: an R package for fitting distributions. Journal of Statistical Software64: 1–34.
23.
DiseNB (2009) Peatland response to global change. Science326(5954): 810–811.
24.
DongYLiHWangS, et al. (2023) The development process of a temperate montane peatland and its controlling factors since the middle Holocene. Science China Earth Sciences66(3): 594–608.
25.
EganJStaffRBlackfordJ (2015) A high-precision age estimate of the Holocene Plinian eruption of Mount Mazama, Oregon, USA. The Holocene25(7): 1054–1067.
26.
EganJFletcherWJAllottTEH, et al. (2016) The impact and significance of tephra deposition on a Holocene forest environment in the North Cascades, Washington, USA. Quaternary Science Reviews137: 135–155.
27.
EhnvallBRatcliffeJLOlidC, et al. (2025) Carbon accumulation in recently deposited peat is reduced by increased nutrient supply. Nature Communications16(1): 4271, Nature Publishing Group.
28.
FaegriKIversenJ (2000) Textbook of Pollen Analysis. 4th edition. Blackburn Press.
29.
Fiałkiewicz-KoziełBKołaczekPPiotrowskaN, et al. (2014) High-resolution age-depth model of a peat bog in Poland as an important basis for paleoenvironmental studies. Radiocarbon56(1): 109–125.
30.
FracassoIDinellaAGiammarchiF, et al. (2022) Climate and human impacts inferred from a 1500-year multi-proxy record of an alpine peatland in the south-eastern alps. Ecological Indicators145: 109737.
31.
Gallego-SalaAVCharmanDJBrewerS, et al. (2018) Latitudinal limits to the predicted increase of the peatland carbon sink with warming. Nature Climate Change8: 907–913.
32.
GarcinYSchefußEDargieGC, et al. (2022) Hydroclimatic vulnerability of peat carbon in the central Congo Basin. Nature612: 1–6, Nature Publishing Group.
33.
GavinDGBrubakerLB (2015) Late Pleistocene and Holocene Environmental Change on the Olympic Peninsula, Washington. Ecological Studies 222. Springer International Publishing. DOI: 10.1007/978-3-319-11014-1_1.
34.
GavinDGBrubakerLBMcLachlanJS, et al. (2005) Correspondence of pollen assemblages with forest zones across steep environmental gradients, Olympic Peninsula, Washington, USA. The Holocene15(5): 648–662.
35.
GorhamE (1991) Northern peatlands: role in the carbon cycle and probable responses to climatic warming. Ecological Applications1(2): 182–195.
36.
GorhamEJanssensJAGlaserPH (2003) Rates of peat accumulation during the postglacial period in 32 sites from Alaska to Newfoundland, with special emphasis on Northern Minnesota. Canadian Journal of Botany81(5): 429–438, NRC Research Press.
37.
GorhamELehmanCDykeA, et al. (2007) Temporal and spatial aspects of peatland initiation following deglaciation in North America. Quaternary Science Reviews26(3): 300–311.
38.
GoringSWilliamsJWBloisJL, et al. (2012) Deposition times in the northeastern United States during the Holocene: establishing valid priors for Bayesian age models. Quaternary Science Reviews48: 54–60.
HansenBCSEasterbrookDJ (1974) Stratigraphy and palynology of late quaternary sediments in the Puget Lowland, Washington. Geological Society of America Bulletin85: 587–602.
41.
HaugerudRA (2020) Deglaciation of the Puget Lowland, Washington. In: WaittRBThackrayGDGillespieAR (eds) Untangling the Quaternary Period—A Legacy of Stephen C. Porter. Geological Society of America, pp. 279–298.
42.
HeiriOLotterAFLemckeG (2001) Loss on ignition as a method for estimating organic and carbonate content in sediments: reproducibility and comparability of results. Journal of Paleolimnology25(1): 101–110.
43.
HuaQTurnbullJCSantosGM, et al. (2022) Atmospheric radiocarbon for the period 1950–2019. Radiocarbon64(4): 723–745.
44.
HuberPJRonchettiEM (2009) Robust Statistics. John Wiley & Sons.
45.
HughesPDMMallonGBrownA, et al. (2013) The impact of high tephra loading on late-Holocene carbon accumulation and vegetation succession in peatland communities. Quaternary Science Reviews67: 160–175.
46.
IrelandAWBoothRKHotchkissSC, et al. (2013) A comparative study of within-basin and regional peatland development: implications for peatland carbon dynamics. Quaternary Science Reviews61: 85–95.
47.
JensenBJLBeaudoinABClynneMA, et al. (2019) A re-examination of the three most prominent Holocene tephra deposits in western Canada: Bridge River, Mount St. Helens Yn and Mazama. Quaternary International500: 83–95.
48.
Karpińska-KołaczekMKołaczekPMarciszK, et al. (2024) Kettle-hole peatlands as carbon hot spots: unveiling controls of carbon accumulation rates during the last two millennia. Catena237: 107764.
49.
KuntzemannCEWhitmanEStralbergD, et al. (2023) Peatlands promote fire refugia in boreal forests of Northern Alberta, Canada. Ecosphere14(5): e4510.
50.
KunzeLM (1986) Puget trough coastal wetlands: a summary report of biologically significant sites. Phase I: Northern Puget trough impounded Wetlands. Washington Department of Ecology. p. 160.
51.
KutzbachJGallimoreRHarrisonS, et al. (1998) Climate and biome simulations for the past 21,000 years. Quaternary Science Reviews17(6–7): 473–506.
52.
LacourseTDaviesMA (2015) A multi-proxy peat study of Holocene vegetation history, bog development, and carbon accumulation on northern Vancouver Island, Pacific coast of Canada. The Holocene25(7): 1165–1178, SAGE Publications Ltd.
53.
LacourseTBeerKWCraigKB, et al. (2019) Postglacial wetland succession, carbon accumulation, and forest dynamics on the east coast of Vancouver Island, British Columbia, Canada. Quaternary Research92(1): 232–245.
LeopoldEBNickmanRHedgesJI, et al. (1982) Pollen and lignin records of late-quaternary vegetation, Lake Washington. Science218: 1305–2307.
56.
LiuHWuHZhangW, et al. (2025) Spatiotemporal distribution of global peatland area during the Holocene. Scientific Data12(1): 37, Nature Publishing Group.
57.
LoiselJYuZBeilmanDW, et al. (2014) A database and synthesis of northern peatland soil properties and Holocene carbon and nitrogen accumulation. The Holocene24(9): 1028–1042.
58.
LongmanJVeresDHaliucA, et al. (2021) Carbon accumulation rates of Holocene peatlands in central–eastern Europe document the driving role of human impact over the past 4000 years. Climate of the Past17(6): 2633–2652.
59.
MathijssenPJHGałkaMBorkenW, et al. (2019) Plant communities control long term carbon accumulation and biogeochemical gradients in a Patagonian bog. Science of The Total Environment684: 670–681.
60.
McLachlanJBrubakerLB (1995) Local and regional vegetation change on the northeastern Olympic Peninsula during the Holocene. Canadian Journal of Botany73: 1618–1627.
61.
MiddeldorpAA (1982) Pollen concentration as a basis for indirect dating and quantifying net organic and fungal production in a peat bog ecosystem. Review of Palaeobotany and Palynology37(3): 225–282.
62.
MinardJPBoothDB (1988) Geologic Map of the Redmond Quadrangle, King County, Washington; Map MF-2016. Miscellaneous Field Studies. U.S. Geological Survey.
63.
NicholsonBJSwinehartJB (2005) Evidence of Holocene climate change in a Nebraska Sandhills wetland. Great Plains Research15: 45–67.
64.
NiinemetsUValladaresF (2006) Tolerance to shade, drought, and waterlogging of temperate Northern Hemisphere trees and shrubs. Ecological Monographs76(4): 521–547.
65.
PorterSCSwansonTW (1998) Radiocarbon age constraints on rates of advance and retreat of the Puget lobe of the Cordilleran Ice Sheet during the last glaciation. Quaternary Research50: 205–213.
66.
RatcliffeJLLoweDJSchipperLA, et al. (2020) Rapid carbon accumulation in a peatland following Late Holocene tephra deposition, New Zealand. Quaternary Science Reviews246: 106505.
67.
ReimerPJBrownTAReimerRW (2004) Discussion: reporting and calibration of post-bomb 14C data. Radiocarbon46(3): 1299–1304.
68.
ReimerPJAustinWENBardE, et al. (2020) The IntCal20 northern hemisphere radiocarbon age calibration curve (0–55 cal kBP). Radiocarbon62(4): 725–757, Cambridge University Press.
RiggGBGouldHR (1957) Age of the Glacier Peak eruption and chronology of post-glacial peat deposits in Washington and surrounding areas. American Journal of Science255: 341–363.
71.
RocchioFJRamm-GranbergTShawJR, et al. (2023) Sphagnum-Dominated Peatlands in the Puget Lowlands: Ecology and Response to Adjacent Land Use. Natural Heritage Report 2023-01. Washington Natural Heritage Program Washington Department of Natural Resources.
72.
RocchioFJRamm-GranbergTShawJR, et al. (2025) Hydrogeochemical and vegetation characterization of sphagnum-dominated peatlands in the Puget Lowlands of Washington State, USA. Wetlands45(5): 49.
73.
RuwaimanaMGavinDGAnshariG (2024) Interplay of climate, fires, floods, and anthropogenic impacts on the peat formation and carbon dynamic of coastal and inland tropical peatlands in West Kalimantan, Indonesia. Ecosystems27(3): 361–375.
74.
SchnurrenbergerDRussellJKeltsK (2003) Classification of lacustrine sediments based on sedimentary components. Journal of Paleolimnology29(2): 141–154.
75.
SimTGSwindlesGTMorrisPJ, et al. (2023) Regional variability in peatland burning at mid-to high-latitudes during the Holocene. Quaternary Science Reviews305: 108020.
76.
Soil Survey Staff, Natural Resource Conservation Service, United States Department of Agriculture (2024) Soil survey geographic (SSURGO) database for Western Washington. Available online. accessed 15 November 2024.
77.
SugitaSTsukadaM (1982) The vegetation history in western North America 1. Mineral and Hall Lakes. Japanese Journal of Ecology32(4): 499–516.
78.
TolonenKTurunenJ (1996) Accumulation rates of carbon in mires in Finland and implications for climate change. The Holocene6(2): 171–178.
79.
UhelskiDMKaneESHeckmanKA, et al. (2023) Fire history and long-term carbon accumulation in hemi-boreal peatlands. Ecosystems26(7): 1573–1586.
80.
van GeelBHeijnisHCharmanDJ, et al. (2014) Bog burst in the eastern Netherlands triggered by the 2.8 kyr BP climate event. The Holocene24(11): 1465–1477.
81.
WADNR (2025) 2025 state of Washington natural heritage plan. Washington Department of Natural Resources.
82.
WangLZhengCZhouW, et al. (2021) A new principle for tuning-free Huber regression. Statistica Sinica31: 2153–2177.
83.
WiederRKScottKDKammingaK, et al. (2009) Postfire carbon balance in boreal bogs of Alberta, Canada. Global Change Biology15(1): 63–81.
84.
XingWBaoKGallego-SalaAV, et al. (2015) Climate controls on carbon accumulation in peatlands of Northeast China. Quaternary Science Reviews115: 78–88.
85.
YoungDMBairdAJGallego-SalaAV, et al. (2021) A cautionary tale about using the apparent carbon accumulation rate (aCAR) obtained from peat cores. Scientific Reports11(1): 9547.
86.
YuZBeilmanDWJonesMC (2009) Sensitivity of northern peatland carbon dynamics to Holocene climate change. In: Carbon Cycling in Northern Peatlands. American Geophysical Union (AGU), pp. 55–69. DOI: 10.1029/2008GM000822.
87.
ZacconeCReinGD’OrazioV, et al. (2014) Smouldering fire signatures in peat and their implications for palaeoenvironmental reconstructions. Geochimica et Cosmochimica Acta137(Supplement C): 134–146.
88.
ZeileisAKleiberCKrämerW, et al. (2003) Testing and dating of structural changes in practice. Computational Statistics & Data Analysis44: 109–123.
89.
ZhangZXingWWangG, et al. (2015) The peatlands developing history in the Sanjiang Plain, NE China and its response to East Asian monsoon variation. Scientific Reports5(1): 11316.
90.
ZoppiUCryeJSongQ, et al. (2007) Performance evaluation of the new AMS system at accium biosciences. Radiocarbon49: 173–182.
