Sedimentary Processes and Environmental Signals from Paired High Arctic Lakes

Cockburn, JACLYN

04 September 2008

Suspended sediment delivery dynamics in two watersheds at Cape Bounty, Melville Island, Nunavut, Canada were studied to characterize the hydroclimate conditions in which laminated sediments formed. Process work over three years determined snow-water equivalence was the primary factor that controlled sediment yield in both catchments. Cool springs (2003, 2004) enhanced runoff potential and intensity because channelized meltwater was delayed as it tunneled through the snowpack and reached the river channel (sediment supply) within 1-2 days. In warm springs (2005), meltwater channelized on the snowpack and did not immediately reach the river bed (7-10 days). Sediment transport was reduced because flow competence was lower and sediment supplies limited. Sediment deposition in the West Lake depended on surface runoff intensity. Short-lived, intense episodes of turbid inflow generated underflow activity which delivered the majority of seasonal sediment. In 2005, runoff was less intense and few underflows were detected compared to the cooler, underflow dominated 2004 runoff season. As well, grain-size analysis of trapped sediment indicated that deposition rates and maximum grain-size were decoupled, indicative of varied sediment supplies and delivery within the fluvial system. These decoupled conditions have important implications for paleohydrological interpretations from downstream sedimentary records. Two similar 600-year varve records were constructed from the lakes at Cape Bounty. Although these series were highly correlated throughout, time-dependent correlation analysis identified divergence in the early 19th century. Because the varve records were from adjacent watersheds and subject to the same hydroclimatic conditions, the divergence suggests watershed-level changes, such as increased local active layer detachments. The varve record from West Lake was highly correlated with lagged autumn snowfall and spring temperature. Similar relationships between these variables and East Lake were not as strong or significant. Long-term climatic interpretations should be carefully assessed. A single record from either of these lakes might lead to autumn snowfall and/or spring-melt intensity reconstructions, given the process work and weather record correlations. The recent divergence reveals potential changes likely to occur as warming increases variability within the Arctic System. Multidisciplinary monitoring and observations should continue in order to quantify future variability and evaluate the impact on these systems. / Thesis (Ph.D, Geography) -- Queen's University, 2008-09-02 12:11:53.483

Climate Change

Varves

Hydrology

High-Resolution Record of Vegetation and Climate Change During the Holocene in Southwestern Québec

Lagace, Amanda Lee

13 September 2019

A varved sediment sequence spanning the past ~11.0 ka was collected from Lac Noir (45.77N, 75.13W, 168 m a.s.l.) in southwestern Québec. A high-resolution pollen record documents the post-glacial vegetation history of the region over the course of the Holocene. The record shows an initial open spruce woodland, the establishment of the boreal and mixed conifer-hardwood forest into the area, as well as the expansion and contractions of tree populations in response to climate variability during the Holocene. The well known Tsuga decline at Lac Noir lasted 500 years starting at 5.5 ka and it took 1 460 years for hemlock to recover. The highest frequency of fire activity occurred during the early Holocene, and the lowest in the mid-Holocene. The late Holocene saw an increase in fire frequency, which could be attributed to a drier climate in eastern North America during this period. The impact of climate variability, fire disturbances and possible biotic factors on the Lac Noir vegetation are examined.

Paleoecology

Holocene

Pollen

Vegetation

Varves

southwestern Québec

Sedimentology and paleoenvironmental indicators in a High Arctic meromictic lake

Tomkins, Jessica Diane

08 May 2008

High Arctic meromictic lakes are frequently used to generate detailed records of past environmental variability within their sedimentary profiles. However, without detailed analyses of sedimentation influences over time, their paleoclimate records cannot be accurately interpreted. This thesis presents a comprehensive examination of the sedimentology and paleoenvironmental records of meromictic Lake A, Ellesmere Island (83°00’N, 75°30’W), including detailed analysis of the sedimentary history, development and evaluation of several paleoclimate records. The sedimentary record was primarily composed of clastic material but varying inputs of authigenic components from biological and chemical processes in the water column resulted in a complex history of lake sedimentation. Under chemically stratified conditions during the past millennium, annual laminae (varves) formed and were used to develop a sedimentary chronology. Sedimentary pellets were most likely formed by ice-rafting processes and were deposited during high melt years in this perennially ice-covered lake. The pellet frequency record indicated that the twentieth century contained the most frequent reduced ice cover summers during the past millennium, although the 1500s and 1600s were also inferred warm periods. Comparison with instrumental climate data indicated that varve thickness was primarily related to late summer and autumn snowfall in the previous year, which highlighted the importance of snow availability in spring rather than melt energy in sediment transfer to the lake in this non-glacial catchment. The varve thickness and grain size records suggested increased flow competency and autumn snowfall particularly during the late-1000s to early-1100s and first half of the 1900s. Paleoenvironmental records from Lake A corresponded well with many regional proxy records and provided a long-term framework within which to examine observed environmental change along the northern Ellesmere Island coast during the past century. Finally, these analyses would not have been possible without obtaining high quality sediment cores. This research also investigated the effectiveness of a gel seal method for preserving the fragile sediment-water interface during transport and its results could be useful for other sediment core studies. / Thesis (Ph.D, Geography) -- Queen's University, 2008-05-08 13:34:14.044

Paleoclimatology

Sedimentology

Varves

High Arctic

Meromictic lake

Sedimentation in a proglacial lake : interpreting intra- and inter-annual sedimentation in Linnévatnet, Spitsbergen, Norway /

Roop, Heidi Anne.

January 2007

Undergraduate honors paper--Mount Holyoke College, 2007. Dept. of Earth and Environment. / Includes one CD-Rom appendix of 2005-2006 grain size data. Includes bibliographical references (leaves 125-129).

Mid- to Late Holocene flood reconstruction from two varved sediment profiles of pre-alpine Lake Ammersee (Southern Germany)

Czymzik, Markus

January 2012

Climate is the principal driving force of hydrological extremes like floods and attributing generating mechanisms is an essential prerequisite for understanding past, present, and future flood variability. Successively enhanced radiative forcing under global warming enhances atmospheric water-holding capacity and is expected to increase the likelihood of strong floods. In addition, natural climate variability affects the frequency and magnitude of these events on annual to millennial time-scales. Particularly in the mid-latitudes of the Northern Hemisphere, correlations between meteorological variables and hydrological indices suggest significant effects of changing climate boundary conditions on floods. To date, however, understanding of flood responses to changing climate boundary conditions is limited due to the scarcity of hydrological data in space and time. Exploring paleoclimate archives like annually laminated (varved) lake sediments allows to fill this gap in knowledge offering precise dated time-series of flood variability for millennia. During river floods, detrital catchment material is eroded and transported in suspension by fluid turbulence into downstream lakes. In the water body the transport capacity of the inflowing turbidity current successively diminishes leading to the deposition of detrital layers on the lake floor. Intercalated into annual laminations these detrital layers can be dated down to seasonal resolution. Microfacies analyses and X-ray fluorescence scanning (µ-XRF) at 200 µm resolution were conducted on the varved Mid- to Late Holocene interval of two sediment profiles from pre-alpine Lake Ammersee (southern Germany) located in a proximal (AS10prox) and distal (AS10dist) position towards the main tributary River Ammer. To shed light on sediment distribution within the lake, particular emphasis was (1) the detection of intercalated detrital layers and their micro-sedimentological features, and (2) intra-basin correlation of these deposits. Detrital layers were dated down to the season by microscopic varve counting and determination of the microstratigraphic position within a varve. The resulting chronology is verified by accelerator mass spectrometry (AMS) 14C dating of 14 terrestrial plant macrofossils. Since ~5500 varve years before present (vyr BP), in total 1573 detrital layers were detected in either one or both of the investigated sediment profiles. Based on their microfacies, geochemistry, and proximal-distal deposition pattern, detrital layers were interpreted as River Ammer flood deposits. Calibration of the flood layer record using instrumental daily River Ammer runoff data from AD 1926 to 1999 proves the flood layer succession to represent a significant time-series of major River Ammer floods in spring and summer, the flood season in the Ammersee region. Flood layer frequency trends are in agreement with decadal variations of the East Atlantic-Western Russia (EA-WR) atmospheric pattern back to 200 yr BP (end of the used atmospheric data) and solar activity back to 5500 vyr BP. Enhanced flood frequency corresponds to the negative EA-WR phase and reduced solar activity. These common links point to a central role of varying large-scale atmospheric circulation over Europe for flood frequency in the Ammersee region and suggest that these atmospheric variations, in turn, are likely modified by solar variability during the past 5500 years. Furthermore, the flood layer record indicates three shifts in mean layer thickness and frequency of different manifestation in both sediment profiles at ~5500, ~2800, and ~500 vyr BP. Combining information from both sediment profiles enabled to interpret these shifts in terms of stepwise increases in mean flood intensity. Likely triggers of these shifts are gradual reduction of Northern Hemisphere orbital summer forcing and long-term solar activity minima. Hypothesized atmospheric response to this forcing is hemispheric cooling that enhances equator-to-pole temperature gradients and potential energy in the troposphere. This energy is transferred into stronger westerly cyclones, more extreme precipitation, and intensified floods at Lake Ammersee. Interpretation of flood layer frequency and thickness data in combination with reanalysis models and time-series analysis allowed to reconstruct the flood history and to decipher flood triggering climate mechanisms in the Ammersee region throughout the past 5500 years. Flood frequency and intensity are not stationary, but influenced by multi-causal climate forcing of large-scale atmospheric modes on time-scales from years to millennia. These results challenge future projections that propose an increase in floods when Earth warms based only on the assumption of an enhanced hydrological cycle. / Globale Klimamodelle prognostizieren eine Zunahme von Starkhochwassern infolge der Klimaerwärmung. Weiterhin werden natürliche Klimafaktoren die Intensität und Häufigkeit solcher Ereignisse auf Zeitskalen von Jahren bis Jahrtausenden beeinflussen. Für ein umfassendes Verständnis hochwassergenerierender Klimamechanismen müssen daher lange Zeiträume und regionale Muster in Betracht gezogen werden. Aufgrund der Limitierung der meisten instrumentellen Abflusszeitreihen auf die letzten 100 Jahre, bieten diese nur einen sehr begrenzten Einblick in das Spektrum möglicher Klima-Hochwasser Zusammenhänge. Die Nutzung natürlicher Hochwasserarchive, wie warvierter Seesedimente, erlaubt die Untersuchung von Hochwasseraktivität auf Zeitskalen von Jahrtausenden. Durch Hochwasser in einen See eingetragenes detritisches Material bildet, eingeschaltet in den jährlichen Sedimentationszyklus, eine charakteristische Abfolge von Hochwasserlagen auf dem Seeboden. Das Zählen jährlicher Laminierungen und die Position innerhalb eines jährlichen Sedimentationszyklus ermöglichen die Datierung von Hochwasserlagen mit saisonaler Genauigkeit. Der Ammersee bildet ein ideales Archiv zur Rekonstruktion von Hochwassern. Detritisches Material wird durch nur einen Hauptzufluss, die Ammer, in das rinnenförmige Becken transportiert. Die warvierten Sedimente erlauben eine zuverlässige Detektion und Datierung selbst mikroskopischer Hochwasserlagen. An zwei warvierten Sedimentprofilen des Ammersees sind hochauflösende Mikrofazies und Röntgenfluoreszenz (µ-XRF) Analysen durchgeführt worden. Zum besseren Verständnis der Sedimentverteilung im See lag der Fokus der Untersuchungen auf der Detektion detritischer Lagen anhand ihrer sedimentologischen und geochemischen Eigenschaften und der Korrelation dieser Lagen zwischen beiden Sedimentprofilen. Die Datierung der detritschen Lagen erfolgte durch Warvenzählung und wurde durch AMS Radiokarbondatierungen bestätigt. In den Sedimenten der letzten 5500 Jahre wurden 1573 detritische Lagen gefunden. Aufgrund ihrer Eigenschaften lassen sich diese Lagen als Ammerhochwasserlagen interpretieren: (1) Die Mikrofazies deutet auf eine Ablagerung nach Starkabflussereignissen hin. (2) Die geochemische Zusammensetzung beweist die terrestrische Herkunft des Materials. (3) Das proximal-distale Ablagerungsmuster deutet auf die Ammer als Eintragsquelle des Materials hin. Eine Kalibrierung mit instrumentellen Hochwasserdaten der Ammer im Zeitraum von AD 1926 bis 1999 bestätigt die Sukzession der detritischen Lagen als eine Zeitreihe starker Ammerhochwasser im Frühling und Sommer, der Hochwassersaison am Ammersee. Die Häufigkeit der Hochwasserlagen in den letzten 5500 Jahren weist eine deutliche dekadische Variabilität auf. Trends in der Häufigkeit von Hochwasserlagen korrelieren negativ mit dem Index der East Atlantic-Western Russia Oszillation (EA-WR) während der letzten 250 Jahre (Zeitraum der durch die genutzten atmosphärischen Daten abgedeckt ist) und der solaren Aktivität während des kompletten Zeitraums. Diese Übereinstimmungen deuten möglicherweise auf einen solaren Einfluss auf die atmosphärische Zirkulation über Europa und damit auf die Häufigkeit von Hochwassern am Ammersee hin. Weiterhin weist die Zeitreihe der Hochwasserlagen drei Veränderungen der durchschnittlichen Lagenhäufigkeit und -mächtigkeit vor etwa 5500, 2800 und 500 Jahren auf. Die Kombination der Daten beider Sedimentprofile ermöglicht es, diese Veränderungen als schrittweise Anstiege der Hochwasserintensität zu interpretieren. Vermutliche Auslöser sind graduelle Reduktion der solaren Insolation in der Nordhemisphäre und langfristige Minima der solaren Aktivität. Die wahrscheinliche atmosphärische Reaktion auf dieses Klimaforcing ist ein verstärkter Temperaturgradient zwischen den niederen und hohen Breiten, der zu einer Erhöhung der potenziellen Energie in der Atmosphäre und verstärkter Baroklinität führt. Diese Energie wird transferiert in eine Verstärkung der zyklonalen Westwindzirkulation, extremere Niederschläge und eine Intensivierung der Hochwasser am Ammersee. Die Interpretation der Häufigkeit und Mächtigkeit von Hochwasserlagen in den Sedimenten des Ammersees ermöglicht eine Rekonstruktion der Hochwassergeschichte und die Identifizierung hochwasserauslösender Klimafaktoren in der Ammerseeregion während der letzten 5500 Jahre. Hochwasserhäufigkeit und -intensität sind nicht stationär, sondern durch komplexe Veränderungen im Klimasystem auf Zeitskalen von Jahren bis Jahrtausenden geprägt. In diesem Zusammenhang erscheinen die Resultate globaler Klimamodelle, die einen Anstieg des Hochwasserrisikos allein auf Basis eines thermodynamisch intensivierten hydrologischen Kreislaufs infolge der Klimaerwärmung prognostizieren, als stark simplifiziert.

paleofloods

lake sediments

varves

climate dynamics

Earth sciences

Recent hydroclimate dynamics in southwest Alaska: understanding multidecadal climate variability through sedimentary process studies and varve sedimentology.

Kaufman, Claire Allyn

24 September 2008

Sedimentological analyses of sediment traps and 289 years (1717-2006) of varved sediments from Shadow Bay (60.01°N, 159.18°W), Lake Chauekuktuli were compared to available hydrometeorological data in order to investigate basin response to hydroclimatic variability in southwest Alaska. On a subannual timescale, the characteristics of the coarse basal unit typical of clastic varves were controlled by spring snowmelt and runoff, while the fine-grained cap was shaped by fall and winter conditions. Coarse subannual laminations within the clay cap were associated with autumn storm activity and winter warming events brought about by the interplay between regional maritime and continental air masses. Biogenic silica (BSi) profiles show two annual peaks in siliceous algal deposition; the first occurred at the end of the spring freshet, the second in the late summer. On an annual timescale, varve thickness was dependent on total annual discharge (r2=0.75, n=43, p<0.0001), while maximum annual grain size was determined to be dependent on both maximum spring discharge (r2=0.63, n=43, p<0.0001) and total annual discharge (r2=0.61, n=43, p<0.0001). On interannual timescales, relationships between climate variables (temperature, precipitation, North Pacific (NP) and Pacific Decadal Oscillation (PDO) indices) and both regional discharge and varve thickness were insignificant. When the same data sets were analyzed on multidecadal timescales, regime shifts in varve thickness and total annual discharge coherent with shifts in NP and PDO indices were identified. Periods of increased varve thickness and total annual discharge were associated with warm PDO phases and a strengthened Aleutian Low. The 289-year varve record was used to reconstruct PDO dynamics prior to 1900. Multidecadal shifts were apparent throughout the 19th century, but were absent in the 18th century. This study provides insight into the linkages between regional climate, physical and biological deposition, and can be used to improve the interpretation of seasonal and annual-scale paleoclimate reconstructions for basins similar to Shadow Bay. This study also sheds light on the nature of multidecadal climate variability in the Pacific Northwest region prior to the instrumental record. / Thesis (Master, Geography) -- Queen's University, 2008-09-23 14:13:32.943

Earth Systems Science

Paleoclimatology

Sedimentology

Limnology

Alaska

Varves

Environmental Reconstructions from Laminated Lake Sediments, Lake C3, Ellesmere Island, Canadian High Arctic

Zalzal, Kathryn S.

01 January 2009

Sediments in Lake C3, Ellesmere Island, Canada, contain annual laminations, providing a record of sediment accumulation for 1900+ years. Marine sediments are also present at base of cores, recording lake isolation following isostatic rebound of the Taconite Inlet region in the mid-Holocene. Beyond weak correlations with snowfall and summer temperature and precipitation, varve thickness comparisons with instrumental data were largely unsuccessful, likely due to turbidite-induced erosion. However, summer climate conditions are of key importance in varve thicknesses at many Arctic sites and we expect this to be true at Lake C3. Trends in the thickness record also correspond in approximate timing and response to large-scale climate events including the Little Ice Age (thin laminations) and the Medieval Warm Period (thick laminations). Long term trends and variability in the thickness record are also likely influenced by the weakening flow of the Taconite River following deglaciation as well as localized geomorphic events. Elemental profiles combined with varve thickness features identify anoxic periods resulting from ice-cover- or marine incursion- induced stratification. Through synthetic aperature radar imagery we verify the strong link between air temperature and ice-cover conditions during the summer. Modification to tephra isolation methods resulted in the successful extraction of cryptotephra. Shards are currently undergoing microprobe identification to identify volcanic source and eruption timing. Sediments at Lake C3 provide a high-resolution record of local and regional environmental change and add to the high-latitude network of reconstructions with the objective of placing current changes in a long-term context.

varves

climate change

geochemistry

tephrochronology

lake sediments

XRF

Geology

Geology

Climatic Change Causes Abrupt Shifts in Forests, Inferred from a High-resolution Lacustrine Record, Southwestern Quebec, Canada

Paquette, Nathalie

31 October 2012

A pollen profile from varved lake sediments sampled at 10-year intervals and spanning the past 1000 years is analyzed to understand the effects of climate change and anthropogenic activity on forests in southwestern Quebec. The forests responded rapidly to changes in temperature and precipitation during the Medieval Warm Period and Little Ice Age as well as to land-use changes associated with the European Settlement of the area. The transition into the Little Ice Age was abrupt and had significant impact on the pollen production within a couple of decades. A synthesis of this record with other high-resolution and well-dated pollen data from the conifer-hardwood forest of eastern North America shows consistent results across the whole area, indicating that very-high resolution pollen data can provide insight into multi-decadal climate variability and its impact on forest vegetation. Tree-ring records from the region show inter-annual fluctuations not always consistent between sites, while high-resolution pollen data record multi-decadal to century changes which enable us to interpret climatic effects on plant communities.

Varves

Québec

Holocene

Pollen

Forest Dynamics

Paleoclimate Reconstruction

Charcoal

Eastern Deciduous Forest

Lake Sediments

Research on radiocarbon calibration records, focussing on new measurements from Lake Suigetsu, Japan

Staff, Richard Andrew

January 2011

Radiocarbon calibration is a fundamental stage of the radiocarbon dating process if meaningful calendar ages are to be derived from samples’ radiocarbon determinations. However, the present limit of direct, non-reservoir-corrected, atmospheric radiocarbon calibration is 12,550 calibrated years before present (Reimer et al. 2009), leaving approximately three quarters of the radiocarbon timescale to be necessarily calibrated via less secure marine records. The sediment profile of Lake Suigetsu, Honshu Island, central Japan, offers an ideal opportunity from which to derive an extended, ‘wholly terrestrial’ and continuous record of atmospheric radiocarbon back to the limits of radiocarbon detection (circa 60,000 years before present). The presence of well-defined, annually-deposited laminae (varves) throughout this extended time period provides an independent, high resolution chronometer against which radiocarbon measurements, performed upon plant macrofossil samples retrieved from the sediment column, can be directly related. This site was first exploited for radiocarbon calibration purposes by Kitagawa and van der Plicht (1998a, 1998b), however, issues pertaining to the reliability of the calendar age scale of this work precluded the widespread uptake of this dataset. The work presented in this DPhil thesis represents a significant contribution to the broader, ‘Suigetsu Varves 2006’ project – an international collaboration centring on the re-coring of Lake Suigetsu, which was undertaken in summer 2006 to improve upon the shortcomings of the previous project and, thereby, to fully exploit the site’s potential for both radiocarbon calibration and multi-proxy palaeoenvironmental study (Nakagawa et al. 2011). This DPhil thesis describes the generation of the revised (‘SG06’) terrestrial radiocarbon calibration dataset from Lake Suigetsu, comprising 647 accelerator mass spectrometry (AMS) radiocarbon determinations, and extending across the complete range of the radiocarbon dating method. Furthermore, visual matching of archive SG93 core sections to the continuous SG06 sediment profile was undertaken, allowing the integration of the ≈ 300 radiocarbon determinations from the original Lake Suigetsu project into a higher resolution (≈ 900 radiocarbon measurements), combined Lake Suigetsu radiocarbon calibration dataset, providing a unique reconstruction of atmospheric radiocarbon across the entire radiocarbon dating timescale.

551.701

Climatic Change Causes Abrupt Shifts in Forests, Inferred from a High-resolution Lacustrine Record, Southwestern Quebec, Canada

Paquette, Nathalie

31 October 2012

A pollen profile from varved lake sediments sampled at 10-year intervals and spanning the past 1000 years is analyzed to understand the effects of climate change and anthropogenic activity on forests in southwestern Quebec. The forests responded rapidly to changes in temperature and precipitation during the Medieval Warm Period and Little Ice Age as well as to land-use changes associated with the European Settlement of the area. The transition into the Little Ice Age was abrupt and had significant impact on the pollen production within a couple of decades. A synthesis of this record with other high-resolution and well-dated pollen data from the conifer-hardwood forest of eastern North America shows consistent results across the whole area, indicating that very-high resolution pollen data can provide insight into multi-decadal climate variability and its impact on forest vegetation. Tree-ring records from the region show inter-annual fluctuations not always consistent between sites, while high-resolution pollen data record multi-decadal to century changes which enable us to interpret climatic effects on plant communities.

Varves

Québec

Holocene

Pollen

Forest Dynamics

Paleoclimate Reconstruction

Charcoal

Eastern Deciduous Forest

Lake Sediments