Search for: All records

Abstract. The mid-17th century is characterized by a clusterof explosive volcanic eruptions in the 1630s and 1640s, climatic conditionsculminating in the Maunder Minimum, and political instability andfamine in regions of western and northern Europe as well as China and Japan. This contribution investigates the sources of the eruptions of the 1630s and 1640s and their possible impact on contemporary climate using ice core, tree-ring, and historical evidence but will also look into thesocio-political context in which they occurred and the human responses theymay have triggered. Three distinct sulfur peaks are found in the Greenlandice core record in 1637, 1641–1642, and 1646. In Antarctica, only oneunambiguous sulfate spike is recorded, peaking in 1642. The resultingbipolar sulfur peak in 1641–1642 can likely be ascribed to the eruption ofMount Parker (6∘ N, Philippines) on 26 December 1640, but sulfateemitted from Komaga-take (42∘ N, Japan) volcano on 31 July 1641has potentially also contributed to the sulfate concentrations observed inGreenland at this time. The smaller peaks in 1637 and 1646 can bepotentially attributed to the eruptions of Hekla (63∘ N, Iceland)and Shiveluch (56∘ N, Russia), respectively. To date, however,none of the candidate volcanoes for the mid-17th century sulfate peakshave been confirmed with tephra preserved in ice cores. Tree-ring andwritten sources point to cold conditions in the late 1630s and early 1640sin various parts of Europe and to poor harvests. Yet the early 17thcentury was also characterized by widespread warfare across Europe – and in particular the Thirty Years' War (1618–1648) – rendering any attribution of socio-economic crisis to volcanism challenging. In China and Japan, historical sources point to extreme droughts and famines starting in 1638 (China) and 1640 (Japan), thereby preceding the eruptions of Komaga-take (31 July 1640) and Mount Parker (4 January 1641). The case of the eruptioncluster between 1637 and 1646 and the climatic and societal conditionsrecorded in its aftermath thus offer a textbook example of difficulties in(i) unambiguously distinguishing volcanically induced cooling, wetting, ordrying from natural climate variability and (ii) attributing politicalinstability, harvest failure, and famines solely to volcanic climaticimpacts. This example shows that while the impacts of past volcanism mustalways be studied within the contemporary socio-economic contexts, it isalso time to move past reductive framings and sometimes reactionaryoppositional stances in which climate (and environment more broadly) eitheris or is not deemed an important contributor to major historical events. 

Abstract. Volcanic eruptions are a key source of climatic variability, andreconstructing their past impact can improve our understanding of theoperation of the climate system and increase the accuracy of future climateprojections. Two annually resolved and independently dated palaeoarchives –tree rings and polar ice cores – can be used in tandem to assess thetiming, strength and climatic impact of volcanic eruptions over the past∼ 2500 years. The quantification of post-volcanic climateresponses, however, has at times been hampered by differences betweensimulated and observed temperature responses that raised questions regardingthe robustness of the chronologies of both archives. While manychronological mismatches have been resolved, the precise timing and climaticimpact of two major sulfate-emitting volcanic eruptions during the 1450s CE, including the largest atmospheric sulfate-loading event in the last 700 years, have not been constrained. Here we explore this issue through acombination of tephrochronological evidence and high-resolution ice-corechemistry measurements from a Greenland ice core, the TUNU2013 record. We identify tephra from the historically dated 1477 CE eruption of theIcelandic Veiðivötn–Bárðarbunga volcanic system in directassociation with a notable sulfate peak in TUNU2013 attributed to thisevent, confirming that this peak can be used as a reliable and precisetime marker. Using seasonal cycles in several chemical elements and 1477 CEas a fixed chronological point shows that ages of 1453 CE and 1458 CE can beattributed, with high precision, to the start of two other notablesulfate peaks. This confirms the accuracy of a recent Greenland ice-corechronology over the middle to late 15th century and corroborates thefindings of recent volcanic reconstructions from Greenland and Antarctica.Overall, this implies that large-scale Northern Hemisphere climatic coolingaffecting tree-ring growth in 1453 CE was caused by a Northern Hemispherevolcanic eruption in 1452 or early 1453 CE, and then a Southern Hemisphereeruption, previously assumed to have triggered the cooling, occurred laterin 1457 or 1458 CE. The direct attribution of the 1477 CE sulfate peak to the eruption ofVeiðivötn, one of the most explosive from Iceland in the last 1200 years, also provides the opportunity to assess the eruption's climaticimpact. A tree-ring-based reconstruction of Northern Hemisphere summertemperatures shows a cooling in the aftermath of the eruption of −0.35 ∘C relative to a 1961–1990 CE reference period and−0.1 ∘C relative to the 30-year period around the event, as well as arelatively weak and spatially incoherent climatic response in comparison tothe less explosive but longer-lasting Icelandic Eldgjá 939 CE and Laki1783 CE eruptions. In addition, the Veiðivötn 1477 CE eruptionoccurred around the inception of the Little Ice Age and could be used as achronostratigraphic marker to constrain the phasing and spatial variabilityof climate changes over this transition if it can be traced in moreregional palaeoclimatic archives. 

Abstract. The 852/3 CE eruption of Mount Churchill, Alaska, was one of the largestfirst-millennium volcanic events, with a magnitude of 6.7 (VEI 6) and atephra volume of 39.4–61.9 km3 (95 % confidence). The spatial extent of the ash fallout from this event is considerable and the cryptotephra (White River Ash east; WRAe) extends as far as Finland and Poland. Proximal ecosystem and societal disturbances have been linked with this eruption; however, wider eruption impacts on climate and society are unknown. Greenland ice core records show that the eruption occurred in winter 852/3 ± 1 CE and that the eruption is associated with a relatively moderate sulfate aerosol loading but large abundances of volcanic ash and chlorine. Here we assess the potential broader impact of this eruption using palaeoenvironmental reconstructions, historical records and climate model simulations. We also use the fortuitous timing of the 852/3 CE Churchill eruption and its extensively widespread tephra deposition of the White River Ash (east) (WRAe) to examine the climatic expression of the warm Medieval Climate Anomaly period (MCA; ca. 950–1250 CE) from precisely linked peatlands in the North Atlantic region. The reconstructed climate forcing potential of the 852/3 CE Churchill eruptionis moderate compared with the eruption magnitude, but tree-ring-inferredtemperatures report a significant atmospheric cooling of 0.8 ∘Cin summer 853 CE. Modelled climate scenarios also show a cooling in 853 CE, although the average magnitude of cooling is smaller (0.3 ∘C). The simulated spatial patterns of cooling are generally similar to those generated using the tree-ring-inferred temperature reconstructions. Tree-ring-inferred cooling begins prior to the date of the eruption suggesting that natural internal climate variability may have increased the climate system's susceptibility to further cooling. The magnitude of the reconstructed cooling could also suggest that the climate forcing potential of this eruption may be underestimated, thereby highlighting the need for greater insight into, and consideration of, the role of halogens and volcanic ash when estimating eruption climate forcing potential. Precise comparisons of palaeoenvironmental records from peatlands acrossNorth America and Europe, facilitated by the presence of the WRAe isochron,reveal no consistent MCA signal. These findings contribute to the growingbody of evidence that characterises the MCA hydroclimate astime-transgressive and heterogeneous rather than a well-defined climaticperiod. The presence of the WRAe isochron also demonstrates that nolong-term (multidecadal) climatic or societal impacts from the 852/3 CEChurchill eruption were identified beyond areas proximal to the eruption.Historical evidence in Europe for subsistence crises demonstrate a degree of temporal correspondence on interannual timescales, but similar events were reported outside of the eruption period and were common in the 9thcentury. The 852/3 CE Churchill eruption exemplifies the difficulties ofidentifying and confirming volcanic impacts for a single eruption, even whenthe eruption has a small age uncertainty. 

Abstract Tree-ring chronologies underpin the majority of annually-resolved reconstructions of Common Era climate. However, they are derived using different datasets and techniques, the ramifications of which have hitherto been little explored. Here, we report the results of a double-blind experiment that yielded 15 Northern Hemisphere summer temperature reconstructions from a common network of regional tree-ring width datasets. Taken together as an ensemble, the Common Era reconstruction mean correlates with instrumental temperatures from 1794–2016 CE at 0.79 ( p  < 0.001), reveals summer cooling in the years following large volcanic eruptions, and exhibits strong warming since the 1980s. Differing in their mean, variance, amplitude, sensitivity, and persistence, the ensemble members demonstrate the influence of subjectivity in the reconstruction process. We therefore recommend the routine use of ensemble reconstruction approaches to provide a more consensual picture of past climate variability.