Hostname: page-component-cd9895bd7-8ctnn Total loading time: 0 Render date: 2024-12-22T15:47:55.907Z Has data issue: false hasContentIssue false

The 1789 Christmas Eve collision of the HMS Guardian with an iceberg in the southwest Indian Ocean

Published online by Cambridge University Press:  14 April 2023

Seelye Martin*
Affiliation:
School of Oceanography, University of Washington, Seattle WA 98195, USA
*
Author for correspondence: Seelye Martin, E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

In the evening of 24 December 1789, 2100 km southeast of Cape Town and after encountering three icebergs, the HMS Guardian under Captain Edward Riou collided with the submerged foot of a large iceberg. Despite severe damage to the ship and its abandonment by many of its crew and passengers, Riou sailed the hulk back to Cape Town, arriving on 22 February 1790. From present-day research and field studies, the formation of the foot in the collision is consistent with the above-freezing seawater temperatures inferred from Riou's commentary. Further, the observed 60 m iceberg height suggests that it calved from the Filchner Ice Shelf in the Weddell Sea. Comparison of the positions of Riou's icebergs with historic sightings, satellite observations and iceberg drift and fracture models also shows that they originated in the Weddell Sea and that their likelihood of occurrence in the collision region is small.

Type
Letter
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of The International Glaciological Society

1. Introduction

On 11 December 1789, the HMS Guardian under command of 26-year-old Captain Edward Riou departed Cape Town for the new Australian colony. The ship sailed southeast to reach 44°S, the latitude of the strong westerly winds, then continued east in the Antarctic Circumpolar Current (ACC).

The Guardian was a Roebuck-class warship refitted as a supply ship. It had a 35 m deck length, a 43 m overall length, a 12 m width, a draft of 5–6 m and a main mast height of ~30 m (Best ship models, 2022; Model ship builder, 2022) The ship carried 1000 tonnes of supplies, and 124 people, including 88 crew, 25 convicts and 11 passengers and wardens. The only female was a 10-year-old girl, Elizabeth Schaeffer, daughter of colonist Phillip Schaeffer.

Eleven days after leaving Cape Town on 22 December, Riou was surprised to observe two icebergs that he recorded at the position of his noon sighting (Table 1). His dates were in ‘nautical time,’ with days running from noon to noon, and his positions determined at local noon. Before the collision, he determined latitude from sextant observations and longitude from a chronometer; after the collision, when his chronometers were stolen, his longitudes were from dead reckoning and less accurate. The first iceberg was saddle-shaped and measured ~10 m high and 300 m long at the waterline; the second was similarly sized and visible only from the masthead (Riou, Reference Riou1790, 4–5). Thirteen years earlier during 1776–80, Riou sailed this course as a midshipman on Cook's third voyage without observing icebergs, and Cook during his 1772–75 circumnavigation of Antarctica saw no icebergs north of 51°S, which was seven degrees south of Riou's observations (Martin and others, Reference Martin, Long and Schodlok2022).

Table 1. The dates and positions of Riou's icebergs

This letter describes Riou's encounters with these icebergs, and the physical interpretation of his observations. The next section gives a detailed description of the Guardian collision with the submerged foot of another iceberg and the resultant severe damage. The post-collision section describes the flooding of the ship, and the panic among the crew, some of whom with Riou's concurrence abandoned ship in five small boats, of which four were lost. It then describes how Riou sailed the ship back to Cape Town. The discussion section shows that the properties of the iceberg foot are consistent with contemporary research, and that from a comparison of historic ship collisions, iceberg positions from ships and modelling results, the likelihood of Riou's icebergs in the collision region is small. Finally, the 60 m freeboard of the collision iceberg suggests it calved from the Filchner Ice Shelf.

2. Collision

Two days after his first iceberg observations, in the afternoon of Christmas Eve, at 43.3°S, 42.7°E, Riou observed a third iceberg with a waterline length of ~200 m and hummocks at each end, the larger 60 m high, the smaller 15 m high. In the late afternoon, Riou deployed two boats in a downwind approach to the iceberg, which this letter calls ‘Oasis,’ to collect fragments of freshwater ice in the water around the iceberg (Fig. 1). As the boats approached the ice, he observed that tonnes of ice occasionally fell from the larger hummock, providing ‘convincing proof of [its] rapid decay…’ (Riou, Reference Riou1790, 7–13) At 7:30 pm, the operation was complete, the boats were taken onboard, and the Guardian departed Oasis to the northwest.

Fig. 1. Schematic of the Guardian location from the late afternoon recovery of freshwater ice at the Oasis iceberg to the 8:30 pm collision.

At 7:45 pm, Sailing Master Thomas Clements wrote they ‘were shut up in a thick close general mist…from this it was apprehended there were many more such islands of ice floating [around us], which appeared very dangerous, but being sensible that every precaution had been taken [extra lookouts had been posted], it was hoped our fears were imaginary’ (Dickson, Reference Dickson2012, 31). The wind remained from the northeast (45°), and the ship was sailing east-south-east (112°) at 12 km h−1 (Fig. 1).

At 8:00 pm, after estimating that the Guardian had cleared Oasis to the south, Riou went to his cabin. Half an hour later, he felt the ship move ‘with instantaneous and unaccustomed velocity.’ He immediately left his cabin and started to run toward the bow, when he observed from ‘the countenances of horror of the men on the forecastle that the danger [was] on the lee [downwind] bow…they screamed out “put the helm down” [meaning turn into the wind]’ (Riou, Reference Riou1790, 14–15).

Riou ordered this done. He then ran aft to the quarter deck, looked forward and on the downwind side, saw ‘a sight which will admit no description − a body of ice full twice as high as our masthead, showing itself through the thickest fog I ever witnessed’ (Fig. 2a; Dickson, Reference Dickson2012, 23).

Fig. 2. The four stages of the Guardian collision with the iceberg foot.

As the ship continued its turn, Riou thought it was entering ‘a vast cavern…large enough to receive her completely’ (Dickson, Reference Dickson2012, 23). He watched the jib-boom, the forward extension of the bowsprit, which he expected to be the first part of the ship to collide with the ice. Instead, a minute later, the downwind submerged part of the bow struck ‘a piece of ice, which projected out from main body underwater,’ leaving the jib-boom intact, but shaking the ship (Fig. 2a; Dickson, Reference Dickson2012, 23, 31).

Riou was relieved that the ship survived the encounter. Since the ship had rotated such that the wind was now incident on its starboard [right] side, he ordered the foresails set so that the rotation would continue. Quoting Riou, ‘the wind blowing fresh around a projecting precipice which acted upon the head sails that were aback and thereby enabled her to tack completely’ (Dickson, Reference Dickson2012, 23). The ship continued turning until the wind was ‘abaft the beam’ or ~110° off the bow (Fig. 2b).

The stern of the Guardian drifted back over the foot (Fig. 2c). As Clements observed, the propagation over the shallow foot of the ocean swell and its reflection from the iceberg wall increased its amplitude and the flow of water on and off the foot. This meant as the water flowed off, the ship ‘was dashed with great force’ onto the submerged foot, severely damaging the hull. The ship ‘had her rudder carried away, the tiller broke in two places, …. three of the [deck] planks were raised a foot [0.3 m] higher…and she shook from stem to stern in so violent a manner we expected her to part in every joint…,’ following which the ship grounded on the foot (Dickson, Reference Dickson2012, 31).

Riou, looking out over the port [left] or the new downwind side, described the ship as being in the cavern, with ice overhanging the mizen [aft] mast (Dickson, Reference Dickson2012, p. 23). Given the ice they had seen falling from the Oasis iceberg, both Riou and Clements were greatly concerned about whether the ship would survive. After ~6 min, there was sufficient wind on the foresails to carry the ship off the foot. As Clements observed, the ship ‘…began to forge off and the same instant stuck a third time with greater force if possible than before, nearly abreast of the main chains [mid-ship], [then] kept crashing for some time along the ice under her, [until] entirely clear of it’ (Dickson, Reference Dickson2012, 31). Finally, the ship sailed free (Fig. 2d).

3. Post-collision

As the ship took on water, Riou ordered the men to start pumping, but the water level continued to rise. He ordered heavy objects such as cannon, anchors, supplies and livestock thrown overboard. He then worked on fothering the hull. This complicated process involved lowering a sail underwater and wrapping it around the damaged hull. Since increasing winds and heavy seas caused the ship to pitch and roll, this was a nearly impossible operation.

On Christmas Day, although Riou felt that the ship would remain intact and afloat for at least another day, the crew gained access to the spirit room and a panic fueled by their excessive alcohol consumption ensued (Dickson, Reference Dickson2012, 26). Riou, firm about his desire to remain on the Guardian, supported those who wished to abandon it and deployed five boats. He asked Clements to command the 11 m long launch, and to carry a letter to the Admiralty.

Sixty-three men abandoned ship. As Riou described, ‘at least twenty people had jumped overboard’ into the swell to reach the boats, of whom two may have drowned immediately (Dickson, Reference Dickson2012, 28). Figure 3 shows a fanciful illustration made in London of the abandonment, with the stern sinking, ice chunks in the water and ice overhanging the ship. Of the five boats and 63 men, only the 19 men in Clements' launch survived. They were picked up 9 days after leaving the Guardian by a French merchant ship and transported to Cape Town.

Fig. 3. Period image of the collision, attributed to ‘possibly Robert Dighton.’ Out of copyright, courtesy of the Mitchell Library, State Library of New South Wales (Mitchell Library, 2022).

In the evening of 27 December, Riou saw his last iceberg, ‘a large island of ice’ on the port bow ~8 km distant (Table 1). Because all Riou's watches were stolen in the panic, he could only determine longitude from dead reckoning. Riou hoped that the remaining crew would not see this iceberg, since ‘I was not a little alarmed at the effect this sight might have on their minds…’ For safety that night, he reduced the ship speed so that the iceberg remained in sight during the next day (Dickson, Reference Dickson2012, 39).

The theft of his watches meant that he was unable to navigate the ship to the nearest land, the Prince Edward and Marion Islands (46.9°S, 37.7°E), ~600 km to the southwest. Instead, he sailed the ship 2100 km back to Cape Town. He accomplished this by sailing northwest until he reached a latitude above the southern tip of Africa, continuing west until he encountered the coast, then following the coast until on 22 February 1790, they reached Cape Town. Of the 124 people initially on board, 80 survived (Dickson, Reference Dickson2012, 30, 55–67).

Elizabeth Schaeffer was among them. Her father said that ‘the ship's captain, Edward Riou, behaved like a savage for the whole nine weeks… My poor child had to stand all night in water and serve the men with liquor when they rested from the pumps and do other work as well. …[At Cape Town] my poor child and I were left with nothing but our lives…’ (Schaeffer, Reference Schaeffer1790).

4. Discussion

4.1. Formation of the underwater foot

The formation and growth of an iceberg foot is important to understanding not only the Guardian collision but also the mechanism through which Riou's icebergs arrived at their locations. As England and others (Reference England, Wagner and Eisenman2020, Fig S3) describe, the foot grows from the presence of warm surface water and ocean waves, which through wave-induced melting, cuts a notch into the iceberg at its waterline. After the notch grows in several meters, the ice above the waterline becomes unstable and sloughs off, leaving the underwater foot intact. For an above-freezing seawater temperature, the growth rate of the notch into the iceberg is ~1 m day−1 °C−1, so that a 5°C temperature elevation yields 35 m week−1 (Wagner and others, Reference Wagner2014).

The growth of the buoyant foot on a large iceberg exerts an increasing torque, which when it becomes large enough, fractures the iceberg (Scambos and others, Reference Scambos, Sergienko, Sargent, MacAyeal and Fastook2005; Wagner and others, Reference Wagner, Dell and Eisenman2017). This process, called edge wasting, can repeat multiple times, leading to a relatively rapid disintegration (Scambos and others, Reference Scambos2008). The properties of the foot with which the Guardian collided are consistent with the observations of Wagner and others (Reference Wagner2014; Fig. 2b). From a multi-beam sonar survey of the underwater portion of a 100 m long, 70 m thick iceberg, they found a 26 m long, 60 m thick foot located ~5 m below sea level.

Although Riou did not measure seawater temperature, on 22 December, he reported air temperatures of 50° to 60°F (10–15°C), and on Christmas Day, his observation of 20 men in the water also suggests the seawater was above freezing. These inferred above-freezing water temperatures combined with the ocean swell satisfy the necessary conditions for ice-foot formation and for edge wasting to occur.

4.2. Iceberg frequency in the southwest Indian Ocean

Several datasets address the likelihood of icebergs at the Guardian sites. Shipwrecks (2022) lists 775 shipwrecks on the route between the UK and Australia. Before the 1869 opening of the Suez Canal, the route from the UK went around the Cape of Good Hope and across the Indian Ocean; after that time, some ships continued traveling on the Cape-to-Australia route. Between 1789 and 1922, on this route, four ships including the Guardian were reported lost to or severely damaged by icebergs in the southwest Indian Ocean. This small number, which ignores ships that simply disappeared, shows that the passage from the Cape to Australia was much safer than the Europe-to-North-America route on which the Titanic was lost.

Second, the iceberg dataset maintained by the Scientific Committee for Antarctic Research (SCAR) for 1978 through 2012 contains the positions of 374 142 icebergs (Orheim and others, Reference Orheim, Giles, Moholdt, Jacka and Bjørdal2022). In box 44°–52°S and 30°–40°E of their Figure 1, corresponding to Riou's first and western-most observations, they report two to three icebergs, while farther east toward Australia and north of 44°S, there were no icebergs.

Third, the Brigham Young University/National Ice Center (BYU/NIC) Antarctic Iceberg Tracking Database is derived from satellite scatterometer observations taken during 1978 and from 1992 to the present (Stuart and Long, Reference Stuart and Long2011; Budge and Long, Reference Budge and Long2018). The low scatterometer resolution also means that their smallest observable iceberg has a length of 5–10 km. Further, because of the loss of scatterometer contrast in summer when the iceberg surfaces become wet, their dataset consists of several hundred complete and fragmented trajectories. Examination of their data shows that the two closest BYU/NIC trajectories to Riou's icebergs originate from the Weddell Sea and lie respectively 1000 and 3000 km to their west in the ACC (Fig 2 in Martin and others, Reference Martin, Long and Schodlok2022).

Since the BYU/NIC icebergs continue to drift when their size falls below the scatterometer resolution, England and others (Reference England, Wagner and Eisenman2020) apply a combined drift and fracture model based on the ice-foot mechanism to these trajectories. Their model extends the icebergs represented by the two BYU/NIC trajectories to the site of the Guardian icebergs, so that for the ~600 trajectories in the 2020 BYU/NIC dataset, only two reach the positions of Riou's icebergs. Each of the datasets and the England and others (Reference England, Wagner and Eisenman2020) model results show that the likelihood of icebergs in the collision region is very small.

During the collision, Riou reported that the iceberg had a cavern large enough to receive the ship and towered two mast heights above the ship, implying that the iceberg had a 60 m freeboard and 500 m thickness. Even though Riou's observations were made under conditions of extreme stress, they imply that the iceberg had a much greater freeboard than the others. Its large freeboard and thickness suggest it calved from the Filchner Ice Shelf, the thickest in the Weddell Sea, drifted along the Antarctic Peninsula to the ACC, which carried it to the site of the collision (Lambrecht and others, Reference Lambrecht, Sandhäger, Vaughan and Mayer2007, their Fig. 3c).

5. Conclusions

The collision of the HMS Guardian with an iceberg foot provides a dramatic story in a region of sparse icebergs. The properties of the iceberg foot with which the ship collided are consistent with modern theory and the warm seawater inferred from Riou's observations. His estimated 60 m height of the collision iceberg suggests it originated from the Filchner Ice Shelf in the Weddell Sea. Existing ship iceberg and collision datasets plus the low-resolution scatterometer data show the small likelihood of his sightings. The model for iceberg drift with fracture allows for theoretical tracking of their drift at sizes below the resolution of the scatterometers, also shows that they originated in the Weddell Sea, provides a mechanism for icebergs to reach the site and is consistent with the small likelihood of Riou's icebergs in the collision region.

Acknowledgements

The author thanks Douglas MacAyeal, David F. Long and Michael P. Schodlok for inspiration, and Jenny Uglow for introducing him to the HMS Guardian. He further thanks Harry Stern for comments, the University of Washington Libraries and Gordon Aamot for help with publication costs, and editors Douglas MacAyeal and Tavi Murray plus two unnamed reviewers for their comments, questions, and suggested revisions.

References

Best ship models (2022) Frigate HMS Roebuck 1774 ship model plans. Available at https://new.bestshipmodels.com/product/frigate-hms-roebuck-1774-ship-model-plans (last viewed December 2022).Google Scholar
Budge, JS and Long, DG (2018) A comprehensive database for Antarctic iceberg tracking using scatterometer data. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing 11(2), 434442. doi: 10.1109/JSTARS.2017.2784186Google Scholar
Dickson, R (ed.) (2012) HMS Guardian and the Island of ice: The Lost Ship of the First Fleet and Lieutenant Edward Riou, 1789–1790. Carlisle, Australia: Hesperian Press, 128 pp.Google Scholar
England, MR, Wagner, TJW and Eisenman, I (2020) Modeling the breakup of tabular icebergs. Science Advances 6(51). doi: 10.1126/sciadv.abd1273Google Scholar
Lambrecht, A, Sandhäger, H, Vaughan, D and Mayer, C (2007) New ice thickness maps of Filchner–Ronne Ice Shelf, Antarctica, with specific focus on grounding lines and marine ice. Antarctic Science 19(4), 521532. doi: 10.1017/S0954102007000661Google Scholar
Martin, S, Long, DG and Schodlok, MP (2022) Comparison of Antarctic iceberg observations by Cook in 1772–75, Halley in 1700, Bouvet in 1739 and Riou in 1789 with modern data. Journal of Glaciology, 18. doi: 10.1017/jog.2022.111Google Scholar
Mitchell Library (2022) Item 01: the perilous situation of ‘The Guardian’ Frigate as she appeared striking on the rocks of ice – with the departure of the crew – and the wonderful intrepidity of the Commander Lieutenant Riou [possibly by Robert Dighton], call number ML 1112 (a). Available at https://collection.sl.nsw.gov.au/record/9ALqjqBY (last viewed August 2022).Google Scholar
Model ship builder (2022) Discussion of and plans for the Roebuck class fifth-rate ship of the Royal Navy. Available at http://modelshipbuilder.com/e107_plugins/forum/forum_viewtopic.php?30203 (last viewed December 2022).Google Scholar
Orheim, O, Giles, AB, Moholdt, G, Jacka, TH and Bjørdal, A (2022) Antarctic iceberg distribution revealed through three decades of systematic ship-based observations in the SCAR International Iceberg Database. Journal of Glaciology, 115. doi: 10.1017/jog.2022.84Google Scholar
Riou, E (1790) Volume 02: Riou's narrative of the wreck of the Guardian, 8 September–25 December 1789, probably written 1790, State Library of New South Wales, Online State Library Digital Collections, call number SAFE/MLMSS 5711/2 (Safe 1/233b). Available at https://collection.sl.nsw.gov.au/record/YEGmzlyn/Rpd8Db7RvrO02, transcript at https://acms.sl.nsw.gov.au/_transcript/2012/D01277/a2686.htm (last viewed July 2022).Google Scholar
Scambos, T and 7 others (2008) Calving and ice-shelf break-up processes investigated by proxy: Antarctic tabular iceberg evolution during northward drift. Journal of Glaciology 54(187), 579591. doi: 10.3189/002214308786570836Google Scholar
Scambos, T, Sergienko, O, Sargent, A, MacAyeal, D and Fastook, J (2005) ICES at profiles of tabular iceberg margins and iceberg breakup at low latitudes. Geophysical Research Letters 32, L23S09. doi: 10.1029/2005GL023802Google Scholar
Schaeffer, P (1790) Letter, transcribed on the website Free Settler or Felon, Convict Ship Guardian 1790. Available at https://www.freesettlerorfelon.com/convict_ship_guardian_1790.htm (last viewed September 2022).Google Scholar
Shipwrecks (2022) Shipwrecks on the UK – Australia run. Available at http://oceans1.customer.netspace.net.au/austrun-wrecks.html (last viewed January 2023).Google Scholar
Stuart, KM and Long, DG (2011) Tracking large tabular icebergs using the SeaWinds Ku-band microwave scatterometer. Deep-Sea Research II: Topical Studies in Oceanography 58(11-12), 12851300. doi: 10.1016/j.dsr2.2010.11.004.Google Scholar
Wagner, TJW and 8 others (2014) The ‘footloose’ mechanism: iceberg decay from hydrostatic stresses. Geophysical Research Letters 41, 55225529. doi: 10.1002/2014GL060832Google Scholar
Wagner, TJW, Dell, RW and Eisenman, I (2017) An analytical model of iceberg drift. Journal of Physical Oceanography 47(7), 16051616. doi: 10.1175/JPO-D-16-0262.1Google Scholar
Figure 0

Table 1. The dates and positions of Riou's icebergs

Figure 1

Fig. 1. Schematic of the Guardian location from the late afternoon recovery of freshwater ice at the Oasis iceberg to the 8:30 pm collision.

Figure 2

Fig. 2. The four stages of the Guardian collision with the iceberg foot.

Figure 3

Fig. 3. Period image of the collision, attributed to ‘possibly Robert Dighton.’ Out of copyright, courtesy of the Mitchell Library, State Library of New South Wales (Mitchell Library, 2022).