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Mike Baillie – Slices of Time

Published online by Cambridge University Press:  21 October 2024

Gill Plunkett Open the ORCID record for Gill Plunkett [Opens in a new window] ,
Paula J Reimer Open the ORCID record for Paula J Reimer [Opens in a new window] ,
Maarten Blaauw Open the ORCID record for Maarten Blaauw [Opens in a new window] ,
David M Brown Open the ORCID record for David M Brown [Opens in a new window] ,
Jonathan Palmer Open the ORCID record for Jonathan Palmer [Opens in a new window]  and
Jonathan Pilcher
Gill Plunkett
Affiliation:
Archaeology & Palaeoecology, School of Natural and Built Environment, Queen’s University Belfast, Belfast BT7 1NN, UK
Paula J Reimer*
Affiliation:
Archaeology & Palaeoecology, School of Natural and Built Environment, Queen’s University Belfast, Belfast BT7 1NN, UK Centre for Climate, the Environment and Chronology (14CHRONO), School of Natural and Built Environment, Queen's University Belfast, Belfast, BT7 1NN, UK
Maarten Blaauw
Affiliation:
Archaeology & Palaeoecology, School of Natural and Built Environment, Queen’s University Belfast, Belfast BT7 1NN, UK Centre for Climate, the Environment and Chronology (14CHRONO), School of Natural and Built Environment, Queen's University Belfast, Belfast, BT7 1NN, UK
David M Brown
Affiliation:
Archaeology & Palaeoecology, School of Natural and Built Environment, Queen’s University Belfast, Belfast BT7 1NN, UK
Jonathan Palmer
Affiliation:
Chronos Radiocarbon Facility, School of Biological, Earth and Environmental Sciences, University of New South Wales, Sydney, NSW 2052, Australia
Jonathan Pilcher
Affiliation:
Archaeology & Palaeoecology, School of Natural and Built Environment, Queen’s University Belfast, Belfast BT7 1NN, UK
*
Corresponding author: Paula J Reimer; Email: [email protected]
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Keywords

Baillie, Mikedendrochronologyradiocarbon
Type
Obituary
Information
Radiocarbon , Volume 66 , Issue 4 , August 2024 , pp. 605 - 609
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Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of University of Arizona

Photo courtesy of Deborah Baillie

Mike Baillie

1944–2023

Michael “Mike” George Lockhart Baillie was born in Belfast where he attended the Belfast Royal Academy. He graduated from Queen’s University Belfast with a Physics degree and joined the Palaeoecology Laboratory as a research assistant in 1968. His first job was assisting with sample preparation for the newly commissioned Radiochemistry Inc. “Radiocarbon Laboratory” marking Mike’s first foray into the world of chronology building. This self-contained machine had the gas-chemistry, counters and electronics in a single unit. Unusually at the time, it was based on proportional counting of methane rather than carbon dioxide. His work in the laboratory was part-time allowing him to pursue a PhD in dendrochronology a technique that was only just being pioneered in Europe. He set off to build an oak tree-ring chronology for Ireland, initially building a tree-ring sequence from living trees in Ireland and England which he extended using timbers from a range of historic buildings. Mike and others in the laboratory were then building a series of floating chronologies from the hordes of bog oaks revealed by motorway construction and wetland drainage in the 1970 and 1980s. Mike was able to forge the links between these floating sections, most notably by using the chance discovery of bog oaks from northeast England first seen from a train window (Pilcher and Brown Reference Pilcher and Brown2024). The completed 7272-year oak chronology was published in 1984 (Pilcher et al. Reference Pilcher, Baillie, Schmidt and Becker1984). This annual sequence became the basis for the radiocarbon calibration curves in use today. Mike also participated in the development of the Irish pine chronology (Pilcher et al. Reference Pilcher, Baillie, Brown, McCormac, Macsweeney and Mclawrence1995). The Irish pine chronology extends from 3451 to 2569 BC, with an additional section from 6327 BC to 5553 BC which has since been linked to the Irish oak chronology (Torbenson et al. Reference Torbenson, Plunkett, Brown, Pilcher and Leuschner2015).

Mike took a sabbatical at the Laboratory of Tree-ring Research in Tucson, Arizona, in 1986. While there, it’s likely he discussed the frost-damaged rings in the bristlecone pines, which LaMarche et al. (Reference Lamarche and Hirschboeck1984) suggested were indications of cooling events caused by sulfur emissions from volcanoes in the past including the Bronze Age eruption of Thera. This may have inspired his interest in the “narrowest ring” events in Irish oak sequence—places in the tree-ring chronology where the tree-rings were narrower than average—particularly 4375 BC, 3195 BC, 2345 BC, 1628 BC, 1159 BC, 207 BC and AD 540 (Baillie Reference Baillie, Wefer, Berger, Behre and Jansen2002). Mike speculated that some of these narrow rings could be due to volcanic dust, noting the close timing between many narrowest ring events and large acid signals in Greenland ice cores (Baillie and Munro Reference Baillie and Munro1988; Baillie Reference Baillie1989, Reference Baillie1996). That the trees from Europe and North America experienced adverse growing conditions in the same years signalled climate events of global scale. As Mike was fond of saying, “Trees don’t lie, and they were there.”

Mike had a dogged interest in “getting it right” when it came to chronology. He and his colleagues showed that some of the English oak chronologies constructed from art-historical panels did not give consistent cross-dating and were most likely wood imported from the Baltic (Baillie et al. Reference Baillie, Hillam, Briffa and Brown1985). Through cross-dating trees from northern England, Ireland and Germany, they also found an error in the German oak chronology, resulting in a shift in the German chronology before 550 BC to 71 years older (Baillie Reference Baillie2009). The adjustment enabled consistent cross-dating between the Irish and German chronologies back to 3000 BC and a joint publication with the German dendrochronologists (Pilcher et al. Reference Pilcher, Baillie, Schmidt and Becker1984).

Mike extended his thinking about environmental impacts on trees to the potential effects of the same events on past societies, noting frequent clusters of historical and archaeological instances of societies experiencing a range of socio-economic or political upheavals spanning Europe and Asia (Baillie Reference Baillie1992, Reference Baillie1993, Reference Baillie1994, Reference Baillie1996; Baillie and Brown Reference Baillie and Brown2002). Pulling together supporting evidence from other archives, notably those dated by radiocarbon, led Mike to write his insightful “Suck-in and Smear” paper in which he highlighted the importance of chronological precision for recognising short-lived events and their repercussions in the past (Baillie Reference Baillie1991): chronological imprecision gave rise to the “smearing” of an event over an extended time period, but the flipside was the tendency to “suck in” and attribute potentially unconnected but closely contemporaneous events to a common cause. A case in point was the construction of seemingly defensive hillforts in later prehistoric Ireland, which emerging radiocarbon dates were starting to date to the period between 1200–900 cal BC (Grogan and Condit Reference Grogan and Condit1994; Mallory Reference Mallory1991; Mallory and Warner Reference Mallory and Warner1988). The imprecision of the radiocarbon dates from the archaeological sites raised the possibility that the sites were constructed in response to a societal crisis triggered by the same environmental downturn that caused an 18-year-long tree growth anomaly beginning in 1159 BC (Baillie Reference Baillie, Waddell and Twohig1995a)—or, to use one of Mike’s favourite double-negatives, the radiocarbon dates were “not inconsistent” with a scenario of environmentally-driven societal response. More recent dating of Irish hillforts now demonstrates that their construction began centuries before this specific tree-ring event (O’Brien and O’Driscoll Reference O’Brien and O’Driscoll2017), but Mike’s provocation of discussion on human-environment relations in the past ensured that his legacy to Irish and British archaeology extended well beyond the confines of dating archaeological sites (Baillie Reference Baillie1999). His contribution to archaeological discourses included reflections on the manifestation of mass mortalities such as the Black Death on the frequency of dendro-datable archaeological timbers (Baillie Reference Baillie2006) and the significance of similar fluctuations in dendro-dated sites further back in time (Baillie Reference Baillie1995b; Baillie and Brown Reference Baillie, Brown and Raftery1996).

Mike also considered seriously the possibility that some of the narrow-ring events could be cosmic in origin. The regular 470-year recurrence of some of the events suggested the regular return times of comets. He explored these ideas and the relation of the timings to historic and folklore mentions of catastrophes arriving from the sky in his book Exodus to Arthur, catastrophic encounters with comets. In his book with Patrick McCafferty The Celtic Gods, comets in Irish mythology (McCafferty and Baillie Reference McCafferty and Baillie2005), he examined the folklore and folk images that also suggest regular cometary effects in history and prehistory.

Mike’s meticulous scrutiny of tree-ring, ice-core, archaeological and historical sources eventually led to a consilience: the past had been marked by distinct episodes of sudden and drastic environmental events that could be pinpointed to the year. With improvements in ice-core chronologies, he recognised similar time gaps between growth anomalies in the trees and volcanic signals in the ice cores (Baillie Reference Baillie2010). The ice-core community resisted his suggestion that they revisit their chronology, and the interchange of correspondence was the subject of many an entertaining coffee-break at the Palaeoecology Centre. By this stage, tephrochronology had been added to the chronological repertoire of the Palaeoecology Centre, and Mike’s colleagues were collaborating with the Danish ice-core community on the search for tephras in Greenland ice cores. Notably, they looked for ash from the AD 79 eruption of Vesuvius, as well as the AD 1104 eruption of Hekla, two events that underpinned the precise dating of the last two millennia of the Greenland ice core chronology (Vinther et al. Reference Vinther, Clausen, Johnsen, Rasmussen, Andersen, Buchardt, Dahl-Jensen, Seierstad, Siggaard-Andersen, Steffensen, Svensson, Olsen and Heinemeier2006). They found neither (Coulter et al. Reference Coulter, Pilcher, Plunkett, Baillie, Hall, Steffensen, Vinther, Clausen and Johnsen2012). Reports of minute particles with a geochemistry consistent with Vesuvius seemed to support the ice core chronology (Barbante et al. Reference Barbante, Kehrwald, Marianelli, Vinther, Steffensen, Cozzi, Hammer, Clausen and Siggaard-Andersen2013), however, implying a lack of correspondence between tree-ring and ice-core “events” and resulting in an unsatisfactory understanding of the link between these two critical palaeoenvironmental records. A resolution was soon at hand, however, as cosmogenic radionuclide signals common to both the tree-rings (14C) and ice cores (10Be) were recognised by Sigl et al. in the ice cores (Reference Sigl, Winstrup, Mcconnell, Welten, Plunkett, Ludlow, Büntgen, Caffee, Chellman and Dahl-Jensen2015). Aligning these signals demonstrated that Mike’s deduction of an ice-core chronology offset was indeed correct. The independent synchronisation of the two records has since enabled greater recognition and understanding of volcanic impacts on climate and society, a long-lasting legacy of which Mike could be very proud. As for the impact of the Thera eruption, subsequent research has since corroborated Mike’s assertion that the ∼1641 CE sulfate spike in the Greenland ice cores was indeed contemporary with the precisely dated growth anomaly in North American and European trees, but recognition of tephra in the ice cores revealed the culprit eruption to be that of Aniakchak, Alaska (Coulter et al. Reference Coulter, Pilcher, Plunkett, Baillie, Hall, Steffensen, Vinther, Clausen and Johnsen2012; McAneney and Baillie Reference McAneney and Baillie2019; Pearson et al Reference Pearson, Sigl, Burke, Davies, Kurbatov, Severi, Cole-Dai, Innes, Albert and Helmick2022). The search for the precise date of the Thera eruption and its impact continues.

Mike made several visits to New Zealand in the late 1990s and accompanied Jonathan Palmer, Alan Hogg and Ed Cook on field trips in both the North and South Islands. The trip to the North Island involved visiting various subfossil kauri (Agathis australis) sites, and Mike continued to have an active interest in the immense time span of preserved log material (Hogg et al. Reference Hogg, Fifield, Turney, Palmer, Galbraith and Baillie2006; Palmer et al. Reference Palmer, Lorrey, Turney, Hogg, Baillie, Fifield and Ogden2006). On one trip to the South Island, with Palmer, Pilcher, Hogg and Cook, the team were seeking to add subfossil sections of silver pine (Manoao colensoi) at Oroko Swamp to extend the chronology further back in time. The bog site was densely forested, making walking difficult because of the tangled roots and water-filled hollows. They were stopping for lunch, and as luck would have it, Mike leant on a heavily mossed mound that turned out to be a very large old fallen log. It was sampled and immediately named “Baillie’s Wall.”

In addition, Mike was one of the founding members of the IntCal Working Group which was established in 2002 to update and extend the international radiocarbon calibration curves (Reimer et al. Reference Reimer, Hughen, Guilderson, McCormac, Baillie, Bard, Barratt, Beck, Buck, Damon, Friedrich, Kromer, Ramsey, Reimer, Remmele, Southon, Stuiver and van der Plicht2002). He provided valuable insights into the tree-ring data included in the curves and closely followed, and commented on, the discussions and controversies leading to the present calibration curves.

Mike Baillie was a true polymath with knowledge spanning science, archaeology and history. His wit and wisdom will be sorely missed.

References

Baillie, MGL (1989) Hekla-3—How big was it. Endeavour 13, 7882.CrossRefGoogle Scholar
Baillie, MGL (1991) Suck-in and smear: Two related chronological problems for the 90s. Journal of Theoretical Archaeology 2, 1216.Google Scholar
Baillie, MGL (1992) Dendrochronology and past environmental change. Proceedings of the British Academy 77, 523.Google Scholar
Baillie, MGL (1993) Dark Ages and dendrochronology. Emania 11, 312.Google Scholar
Baillie, MGL (1994) Dendrochronology raises questions about the nature of the AD 536 dust-veil event. The Holocene 4, 212217.CrossRefGoogle Scholar
Baillie, MGL (1995a) Dendrochronology and the chronology of the Irish Bronze Age. In Waddell, J and Twohig, ES (eds), Ireland in the Bronze Age. Dublin: The Stationery Office, 3037.Google Scholar
Baillie, MGL (1995b) A Slice through Time: Dendrochronology and Precision Dating, 1st edn. Routledge.Google Scholar
Baillie, MGL (1996) Extreme environmental events and the linking of the tree-ring and ice-core records. Radiocarbon 38, 703711.Google Scholar
Baillie, MGL (1999) A view from outside: Recognising the big picture. Quaternary Proceedings 7, 625635.Google Scholar
Baillie, MGL (1999) Exodus to Arthur—Catastrophic Encounters with Comets. London: Batsford.Google Scholar
Baillie, MGL (2002) “Narrowest-ring” events in the Irish oak chronology: uncertainties in reconstructing cause and effect in prehistory. In Wefer, G, Berger, WH, Behre, K-E and Jansen, E (eds), Climate Development and History of the North Atlantic Realm. Springer, 377385.CrossRefGoogle Scholar
Baillie, MGL (2006) New Light on the Black Death: The Cosmic Connection. Tempus, Stroud.Google Scholar
Baillie, MGL (2009) The radiocarbon calibration from an Irish oak perspective. Radiocarbon 51, 361371.CrossRefGoogle Scholar
Baillie, MGL (2010) Volcanoes, ice-cores and tree-rings: One story or two? Antiquity 84, 202215.CrossRefGoogle Scholar
Baillie, MGL and Brown, DM (1996) Dendrochronology of Irish bog trackways. In Raftery, B (ed), Trackway excavations in the Mountdillon Bogs, Co. Longford, 1985-1991. Dublin: Irish Archaeological Wetland Unit Transactions 3, Crannóg Publication, 395402.Google Scholar
Baillie, MGL and Brown, DM (2002) Oak dendrochronology: Some recent archaeological developments from an Irish perspective. Antiquity 76, 497505.CrossRefGoogle Scholar
Baillie, MGL, Hillam, J, Briffa, KR and Brown, DM (1985) Re-dating the English art-historical tree-ring chronologies. Nature 315, 317319.CrossRefGoogle Scholar
Baillie, MGL and Munro, MAR (1988) Irish tree rings, Santorini and volcanic dust veils. Nature 332, 344–346.CrossRefGoogle Scholar
Barbante, C, Kehrwald, N, Marianelli, P, Vinther, B, Steffensen, J, Cozzi, G, Hammer, C, Clausen, H and Siggaard-Andersen, M-L (2013) Greenland ice core evidence of the 79 AD Vesuvius eruption. Climate of the Past 9, 12211232.CrossRefGoogle Scholar
Coulter, SE, Pilcher, JR, Plunkett, G, Baillie, MGL, Hall, VA, Steffensen, JP, Vinther, BM, Clausen, HB and Johnsen, SJ (2012) Holocene tephras highlight complexity of volcanic signals in Greenland ice cores. Journal of Geophysical Research: Atmospheres 117, D21303. doi: 10.1029/2012JD017698.CrossRefGoogle Scholar
Grogan, E and Condit, T (1994) New hillfort date gives clue to Late Bronze Age. Archaeology Ireland 28, 7.Google Scholar
Hogg, A, Fifield, KL, Turney, CSM, Palmer, JG, Galbraith, R and Baillie, M (2006) Dating ancient wood by high-sensitivity liquid scintillation counting and accelerator mass spectrometry—Pushing the boundaries. Quaternary Geochronology 1, 241248. doi: 10.1016/j.quageo.2006.11.001.CrossRefGoogle Scholar
Lamarche, VC and Hirschboeck, KK (1984) Frost rings in trees as records of major volcanic eruptions. Nature 307, 121126.CrossRefGoogle Scholar
McAneney, J and Baillie, M (2019) Absolute tree-ring dates for the Late Bronze Age eruptions of Aniakchak and Thera in light of a proposed revision of ice-core chronologies. Antiquity 93, 99112.CrossRefGoogle Scholar
McCafferty, P and Baillie, MGL (2005) The Celtic Gods, Comets in Irish Mythology. Tempus, Stroud.Google Scholar
Mallory, JP and Warner, RB (1988) The date of Haughey’s Fort. Emania 5, 3640.Google Scholar
Mallory, JP (1991) Further dates from Haughey’s Fort. Emania 9, 6465.Google Scholar
O’Brien, W and O’Driscoll, J (2017) Hillforts, Warfare and Society in Bronze Age Ireland. Oxford: Archaeopress.CrossRefGoogle Scholar
Palmer, J, Lorrey, A, Turney, CS, Hogg, A, Baillie, M, Fifield, K and Ogden, J (2006) Extension of New Zealand kauri (Agathis australis) tree-ring chronologies into Oxygen Isotope Stage (OIS) 3. Journal of Quaternary Science 21, 779787.CrossRefGoogle Scholar
Pearson, C, Sigl, M, Burke, A, Davies, S, Kurbatov, A, Severi, M, Cole-Dai, J, Innes, H, Albert, PG and Helmick, M (2022) Geochemical ice-core constraints on the timing and climatic impact of Aniakchak II (1628 BCE) and Thera (Minoan) volcanic eruptions. PNAS Nexus 1, pgac048.CrossRefGoogle ScholarPubMed
Pilcher, JR, Baillie, MGL, Brown, DM, McCormac, FG, Macsweeney, PB and Mclawrence, AS (1995) Dendrochronology of subfossil pine in the north of Ireland. Journal of Ecology 83, 665671.CrossRefGoogle Scholar
Pilcher, JR, Baillie, MGL, Schmidt, B and Becker, B (1984) A 7,272-year tree-ring chronology for western-Europe. Nature 312, 150152.CrossRefGoogle Scholar
Pilcher, J and Brown, D (2024) In memoriam: Michael Lockhart Baillie 1944–2023. Tree-Ring Research 80, 5254.CrossRefGoogle Scholar
Reimer, PJ, Hughen, KA, Guilderson, TP, McCormac, G, Baillie, MGL, Bard, E, Barratt, P, Beck, JW, Buck, CE, Damon, PE, Friedrich, M, Kromer, B, Ramsey, CB, Reimer, RW, Remmele, S, Southon, JR, Stuiver, M and van der Plicht, J (2002) Preliminary report of the first workshop of the IntCal04 radiocarbon calibration/comparison working group. Radiocarbon 44, 653661.CrossRefGoogle Scholar
Sigl, M, Winstrup, M, Mcconnell, J, Welten, K, Plunkett, G, Ludlow, F, Büntgen, U, Caffee, M, Chellman, N and Dahl-Jensen, D (2015) Timing and climate forcing of volcanic eruptions for the past 2,500 years. Nature 523, 543.CrossRefGoogle ScholarPubMed
Torbenson, MC, Plunkett, G, Brown, DM, Pilcher, JR and Leuschner, HH (2015) Asynchrony in key Holocene chronologies: Evidence from Irish bog pines. Geology 43, 799802.CrossRefGoogle Scholar
Vinther, BM, Clausen, HB, Johnsen, SJ, Rasmussen, SO, Andersen, KK, Buchardt, SL, Dahl-Jensen, D, Seierstad, IK, Siggaard-Andersen, M-L, Steffensen, JP, Svensson, AM, Olsen, J and Heinemeier, J (2006) A synchronized dating of three Greenland ice cores throughout the Holocene. Journal of Geophysical Research 111, D13102. doi: 10.1029/2005JD006921.CrossRefGoogle Scholar