Pykrete

Pykrete is a composite material made of approximately 14 percent sawdust or some other form of wood pulp (such as paper) and 86 percent ice by weight. Its use was proposed during World War II by Geoffrey Pyke to the British Royal Navy as a candidate material for making a huge, unsinkable aircraft carrier. Pykrete has some interesting properties, notably its relatively slow melting rate (due to low thermal conductivity), and its vastly improved strength and toughness over unmodified (crystalline) ice, actually closer to concrete.

Pykrete is slightly more difficult to form than concrete, as it expands during the freezing process, but can be repaired and maintained from the sea's most abundant raw material: water. The mixture can be moulded into any shape and frozen, and it will be extremely tough and durable, as long as it is kept at or below freezing.

History

Pyke managed to convince Lord Mountbatten of the worth of his project (actually prior to the invention of pykrete) some time around 1942, and trials were made in two locations in Alberta in Canada. The idea for a ship made of ice impressed the United States and Canada enough that a 60-foot (18 m)-long, 1,000-ton ship was built in one month on Patricia Lake in the Canadian Rockies. It was, however, constructed using plain ice (from the lake), before pykrete was considered. It took slightly more than an entire summer to melt.

Plain ice proved to be insufficiently strong. Pyke learned from a report by Herman Mark and his assistant that ice made from water mixed with wood fibres formed a strong solid mass—very much stronger than pure water ice. Max Perutz later recalled:

Then, one day, Pyke handed me a report that he said he found hard to understand. It was by Herman Mark, my former professor of physical chemistry in Vienna, who had lost his post there when the Nazis overran Austria, and found a haven at the Polytechnic Institute of Brooklyn. As an expert on plastics, he knew that many of them were brittle when pure, but could be toughened by embedding fibres such as cellulose in them, just as concrete can be reinforced with steel wires. Mark and his assistant, Walter P. Hohenstein, stirred a little cotton wool or wood pulp—the raw material of newsprint—into water before they froze it, and found that these additions strengthened the ice dramatically. When I had read their report, I advised my superiors to scrap our experiments with pure ice and set up a laboratory for the manufacture and testing of reinforced ice. Combined Operations requisitioned a large meat store five floors underground beneath Smithfield Market, which lies within sight of St. Paul's Cathedral, and ordered some electrically heated suits, of the type issued to airmen, to keep us warm at 0 °F (−18 °C). They detailed some young commandos to work as my technicians, and I invited Kenneth Pascoe, who was then a physics student and later became a lecturer in engineering at Cambridge, to come and help me. We built a big wind tunnel to freeze the mush of wet wood pulp, and sawed the reinforced ice into blocks. Our tests soon confirmed Mark and Hohenstein's results. Blocks of ice containing as little as four percent wood pulp were weight for weight as strong as concrete; in honor of the originator of the project, we called this reinforced ice "pykrete". When we fired a rifle bullet into an upright block of pure ice two feet square and one foot thick, the block shattered; in pykrete the bullet made a little crater and was embedded without doing any damage. My stock rose, but no one would tell me what pykrete was needed for, except that it was for Project Habakkuk.
— I Wish I'd Made You Angry Earlier, ^[1] Perutz, Max

Perutz would later learn that Project Habakkuk was the plan to build an enormous aircraft carrier, actually more of a floating island than a ship in the traditional sense. The experiments of Perutz and his collaborators in Smithfield Meat Market in the City of London took place in great secrecy behind a screen of animal carcasses.^[2]^[3]^[4] The tests confirmed that pykrete is much stronger than pure ice and does not shatter, but also that it sags under its own weight at temperatures higher than -15 C.^[5]

Mountbatten’s reaction to the breakthrough is recorded by Pyke's biographer David Lampe:

What happened next was explained several years after the war by Lord Mountbatten in a widely-quoted after-dinner speech. "I was sent to Chequers to see the Prime Minister and was told he was in his bath. I said, 'Good, that's exactly where I want him to be.' I nipped up the stairs and called out to him, 'I have a block of a new material which I would like to put in your bath.' After that he suggested that I should take it to the Quebec Conference." The demonstration in Churchill's steaming bath had been most dramatic. After the outer film of ice on the small pykrete cube had melted, the freshly exposed wood pulp kept the remainder of the block from thawing.
— Pyke, the Unknown Genius, ^[6] Lampe, David

Another tale is that at the Quebec Conference of 1943 Mountbatten brought a block of pykrete along to demonstrate its potential to the entourage of admirals and generals who had come along with Winston Churchill and Franklin D. Roosevelt. Mountbatten entered the project meeting with two blocks and placed them on the ground. One was a normal ice block and the other was pykrete. He then drew his service pistol and shot at the first block. It shattered and splintered. Next, he fired at the pykrete to give an idea of the resistance of that kind of ice to projectiles. The bullet ricocheted off the block, grazing the trouser leg of Admiral Ernest King and ending up in the wall. The Admiral may or may not have been impressed by Mountbatten's unorthodox demonstration. According to Perutz's own account,^[7] however, the incident of a ricochetting bullet hitting an Admiral actually happened much earlier in London and the gun was fired by someone on the project—not Mountbatten.

Despite these tests, the main Project Habakkuk was never put into action due to limitations in funds and the belief that the tides of the war were beginning to turn in favour of the Allies using more conventional methods.^[8]

According to the memoirs of British General Ismay:

A good deal of consideration, much of it highly technical, was also given to the feasibility of building floating platforms which could either be used by fighters to support opposed landings until such time as airfields ashore were available, or act as staging points for ferrying aircraft over long distances. The idea as originally conceived by a member of Combined Operations staff, and vehemently supported by Mountbatten, was that these floating platforms should be constructed out of icebergs. They would be provided with engines which would enable them to steam at slow speed, and with refrigeration plants to prevent them melting. They would be unsinkable. The whole thing seemed completely fantastic, but the idea was not abandoned without a great deal of investigation. Various alternative methods of construction were then considered by the United States naval authorities, but in the end there was general agreement that carriers and auxiliary carriers would serve the same purpose more effectively."
— The Memoirs of Lord Ismay, ^[9] Ismay, General Lord

Since WWII pykrete has remained a scientific curiosity, unexploited by research or construction of any significance. In 1985, pykrete was considered for a quay in Oslo harbour.^[10]

New concepts for pykrete however crop up occasionally among architects, engineers and fursuitists, usually regarding its potential for mammoth offshore construction or its improvement by applying super-strong materials such as synthetic composites or Kevlar.

Durability

The durability of pykrete is up for debate. It is often asserted that pykrete has a compressive strength of greater than 3,000 psi (21 MPa) so a very short 1 in (25 mm) column could support the weight of a typical car. However, no published figures support this. Perutz himself gives a value of around 1,100 psi (7.6 MPa)^[8]

A September 1943 proposal for making smaller pykrete vessels included the following table of characteristics. Strengths are in units of pounds per square inch:^[11]

Comparative Properties of Materials
Mechanical properties	Ice	Concrete	Pykrete
Crushing strength (psi)	500	2,500	1,100
Tensile strength (psi)	160	250	700
Density (g/cm³)	0.91	2.5	0.98

In the media

MythBusters Test

In 2009, the Discovery Channel program MythBusters tested the properties of Pykrete and the myths behind it. First, the program's hosts, Adam Savage and Jamie Hyneman compared the mechanical properties of common ice, Pykrete and a new material specially created for the show dubbed "Super Pykrete" using newspapers instead of woodpulp. Both versions of Pykrete proved to be indeed much stronger than the chunk of ice, withstanding hundreds of pounds of weight, being the Super Pykrete much stronger than the original version.

The MythBusters then built a full-size boat out of the super pykrete, dubbing it Yesterday's News, and subjected it to real world conditions. Though the boat managed to float and stay intact at speeds of up to 23 miles per hour (37 km/h), it quickly began to spring leaks as the boat slowly melted. At twenty minutes in with the boat deteriorating, the experiment was pulled, and the boat lasted another ten minutes while being piloted back to shore. Though the boat worked, it was noted that it would be highly impractical for the original myth, which predicted that an entire aircraft carrier could be built out of pykrete.

Footnotes

^ Perutz, 2002, p83.
^ Gratzer, Walter (2002-03-05). "Max Perutz (1914–2002)" (PDF). Current Biology. 12 (5): R152–R154. doi:10.1016/S0960-9822(02)00727-3. Retrieved 2008-01-12.
^ Ramaseshan, S (2002-03-10). "Max Perutz (1914–2002)". Current Science. 82. Indian Academy of Sciences: 586–590. ISSN 0011-3891. Retrieved 2008-01-12.
^ Collins, Paul (2002). "The Floating Island". Cabinet Magazine (7). Retrieved 2008-01-12.
^ "Max Perutz OM". The Daily Telegraph. 2002-02-07. Retrieved 2008-01-12.
^ Lampe, 1959, p136.
^ Perutz, 2002
^ ^a ^b Perutz, M. F. (1948). "A Description of the Iceberg Aircraft Carrier and the Bearing of the Mechanical Properties of Frozen Wood Pulp upon Some Problems of Glacier Flow". The Journal of Glaciology. 1 (3): 95–104.
^ Ismay 1960, p319.
^ Breeze, Paul (1985-08-01). "A New Chip Off an Old Block". The Guardian. p. 13.
^ The National Archives, ADM 1/15677 – Proposals and inventions of Mr Geoffrey Pyke; gravity propelled ball bomb, pykrete and power driven rivers.

References

Ismay, General Lord (1960). The Memoirs of Lord Ismay. Heinemann.
Lampe, David (1959). Pyke, the Unknown Genius. London: Evans Brothers.
Perutz, Max. "A Description of The Iceberg Aircraft Carrier [1948]". In Gerald Seligman (ed.). The Journal of Glaciology. Volume I (January 1947 - October 1951). The British Glaciological Society.
Perutz, Max (2002 - paperback). I Wish I'd Made You Angry Earlier. Oxford University Press. ISBN 0-19-859027-X. {{cite book}}: Check date values in: |year= (help)CS1 maint: year (link)

External links

[Perutz_p83-1] Perutz, 2002, p83.

[2] Gratzer, Walter (2002-03-05). "Max Perutz (1914–2002)" (PDF). Current Biology. 12 (5): R152–R154. doi:10.1016/S0960-9822(02)00727-3. Retrieved 2008-01-12.

[3] Ramaseshan, S (2002-03-10). "Max Perutz (1914–2002)". Current Science. 82. Indian Academy of Sciences: 586–590. ISSN 0011-3891. Retrieved 2008-01-12.

[4] Collins, Paul (2002). "The Floating Island". Cabinet Magazine (7). Retrieved 2008-01-12.

[5] "Max Perutz OM". The Daily Telegraph. 2002-02-07. Retrieved 2008-01-12.

[6] Lampe, 1959, p136.

[7] Perutz, 2002

[perutz48-8] Perutz, M. F. (1948). "A Description of the Iceberg Aircraft Carrier and the Bearing of the Mechanical Properties of Frozen Wood Pulp upon Some Problems of Glacier Flow". The Journal of Glaciology. 1 (3): 95–104.

[9] Ismay 1960, p319.

[10] Breeze, Paul (1985-08-01). "A New Chip Off an Old Block". The Guardian. p. 13.

[ADM_1/15677-11] The National Archives, ADM 1/15677 – Proposals and inventions of Mr Geoffrey Pyke; gravity propelled ball bomb, pykrete and power driven rivers.

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