Athabasca Read online




  ALISTAIR MACLEAN

  Athabasca

  Table of Contents

  Prologue

  Chapter 1

  Chapter 2

  Chapter 3

  Chapter 4

  Chapter 5

  Chapter 6

  Chapter 7

  Chapter 8

  Chapter 9

  Chapter 10

  Chapter 11

  Chapter 12

  Chapter 13

  Chapter 14

  Chapter 15

  Chapter 16

  Map

  About the Author

  Copyright

  About the Publisher

  PROLOGUE

  This book is not primarily about oil, but is based on oil and the means whereby oil is recovered from the earth, so it may be of some interest and help to look briefly at these phenomena.

  What oil is, and how it is formed in the first place, no one quite seems to know. The technical books and treatises on this subject are legion—I am aware that, personally, I haven’t seen a fraction of them—and they are largely, so I am assured, in close agreement—except when they come to what one would have thought was a point of considerable interest: how, precisely, does oil become oil? There appear to be as many divergent theories about this as there are about the origins of life. Confronted with complexities, the well-advised layman takes refuge in over-simplification—which is what I now do, as I can do no other.

  Only two elements were needed for the formation of oil—rock, and the incredibly abundant plants and primitive living organisms that teemed in rivers, lakes and seas as far back as perhaps a billion years ago. Hence the term fossil fuels.

  The Biblical references to the rock of ages give rise to misconceptions about the nature and permanency of rock. Rock—the material of which the earth’s crust is made—is neither eternal nor indestructible. Nor is it even unchanging. On the contrary, it is in a state of constant change, movement and flux, and it is salutary to remind ourselves that there was a time when no rock existed. Even today there is a singular lack of agreement among geologists, geo-physicists and astronomers as to how the earth came into being; but there is a measure of agreement that there was a primary incandescent and gaseous state, followed by a molten state, neither of which was conducive to the formation of anything, rock included. It is erroneous to suppose that rock has been, is and ever shall be.

  Yet we are not concerned here with the ultimate origins of rock, but rock as we have it today. It is, admittedly, difficult to observe this process of flux, because a minor change may take ten million years, a major change a hundred million.

  Rock is constantly being destroyed and rebuilt. In the destructive process weather is the main factor; in the rebuilding, the force of gravity.

  Five main weather elements act upon rock. Frost and ice fracture rock. It can be gradually eroded by airborne dust. The action of the seas, whether through the constant movement of waves and tides or the pounding of heavy storm waves, remorselessly wears away the coastlines. Rivers are immensely powerful destructive agencies—one has but to look at the Grand Canyon to appreciate their enormous power; and such rocks as escape all these influences are worn away over the aeons by the effect of rain.

  Whatever the cause of erosion, the end result is the same: the rock is reduced to its tiniest possible constituents—rock particles or, simply, dust. Rain and melting snow carry this dust down to the tiniest rivulets and the mightiest rivers, which in turn transport it to lakes, inland seas and the coastal regions of the oceans. Dust, however fine and powdery, is still heavier than water, and whenever the water becomes sufficiently still, it will gradually sink to the bottom, not only in lakes and seas but also in the sluggish lower reaches of rivers and, where flood conditions exist, inland in the form of silt.

  And so, over unimaginably long reaches of time, whole mountain ranges are carried down to the seas and in the process, through the effects of gravity, new rock is born as layer after layer of dust accumulates on the bottom, building up to a depth of ten, a hundred, perhaps even a thousand feet, the lowermost layers being gradually compacted by the immense and steadily-increasing pressures from above, until the particles fuse together and re-form as new rock.

  It is in the intermediate and final processes of this new rock formation that oil comes into being. Those lakes and seas of hundreds of millions of years ago were almost choked by water plants and the most primitive forms of aquatic life. On dying, they sank to the bottom of the lakes and seas along with the settling dust particles and were gradually buried deep under the endless layers of more dust and more aquatic and plant life that slowly accumulated above them. The passing of millions of years and the steadily increasing pressures from above gradually changed the decayed vegetation and dead aquatic life into oil.

  Described thus simply and quickly, the process sounds reasonable enough. But this is where the grey and disputatious area arises. The conditions necessary for the formation of oil are known: the cause of the metamorphosis is not. It seems probable that some form of chemical catalyst is involved, but this catalyst has not been isolated. The first purely synthetic oil, as distinct from secondary synthetic oils such as those derived from coal, has yet to be produced. We just have to accept that oil is oil, that it is there, bound up in rock strata in fairly well-defined areas throughout the world but always on the sites of ancient seas and lakes, some of which are now continental land, some buried deep under the encroachment of new oceans.

  Had the oil remained intermingled with those deeply-buried rock strata, and were the earth a stable place, that oil would have been irrecoverable. But our planet is a highly unstable place. There is no such thing as a stable continent securely anchored to the core of the earth. The continents rest on the so-called tectonic plates which, in turn, float on the molten magma below, with neither anchor nor rudder, free to wander in whichever haphazard fashion they will. This they unquestionably do: they are much given to banging into each other, grinding alongside each other, overriding or dipping under each other in a wholly unpredictable fashion and, in general, resembling rocks in the demonstration of their fundamental instability. As this banging and clashing takes place over periods of tens or hundreds of millions of years, it is not readily apparent to us except in the form of earthquakes, which generally occur where two tectonic plates are in contention.

  The collision of two such plates engenders incredible pressures, and two of the effects of such pressures are of particular concern here. In the first place the huge compressive forces involved tend to squeeze the oil from the rock strata in which it is embedded and to disperse it in whichever direction the pressure permits—up, down or sideways. Secondly, a collision buckles or folds the rock strata themselves, the upper strata being forced upwards to form mountain ranges—the northern movement of the Indian tectonic plate created the Himalayas—and the lower strata buckling to create what are virtually subterranean mountains, folding the layered strata into massive domes and arches.

  It is at this point, insofar as oil recovery is concerned, that the nature of the rocks themselves becomes of importance. The rock can be porous or non-porous, the porous rock—such as gypsum—permitting liquids, such as oil, to pass through them, while the non-porous—such as granite—does not. In the case of porous rock the oil, influenced by those compressive forces, will seep upwards through the rock until the distributive pressure eases, when it will come to rest at or very close to the surface of the earth. In the case of non-porous rock, the oil will become trapped in a dome or arch, and in spite of the great pressures from below can escape neither sideways nor upwards but must remain where it is.

  In this latter case what are regarded as conventional methods are used in the recovery of oil. Geologists locate a dome, a
nd a hole is drilled. With reasonable luck they hit an oil dome and not a solid one, and their problems are over—the powerful subterranean pressures normally drive the oil to the surface.

  The recovery of seepage oil which has passed upwards through porous rock presents a quite different and far more formidable problem, the answer to which was not found until as late as 1967. Even then it was only a partial answer. The trouble, of course, is that this surface seepage oil does not collect in pools, but is inextricably intermixed with foreign matter such as sand and clay from which it has to be abstracted and refined.

  It is, in fact, a solid and has to be mined as such; and although this solidified oil may go as deep as six thousand feet, only the first two hundred feet, in the limits of present-day knowledge and techniques, are accessible, and that only by surface mining. Conventional mining methods—the sinking of vertical shafts and the driving of horizontal galleries—would be hopelessly inadequate, as they would provide only the tiniest fraction of the raw material required to make the extraction process commercially viable. The latest oil extraction plant, which went into operation only in the summer of 1978, requires 10,000 tons of raw material every hour.

  Two excellent examples of the two different methods of oil recovery are to be found in the far north-west of North America. The conventional method of deep drilling is well exemplified by the Prudhoe Bay oilfield on the Arctic shore of northern Alaska; its latter-day counterpart, the surface mining of oil, is to be found—and, indeed, it is the only place in the world where it can be found—in the tar sands of Athabasca.

  1

  “This,” said George Dermott, “is no place for us.” He eased his considerable bulk back from the dining-table and regarded the remains of several enormous lamb chops with disfavour. “Jim Brady expects his field operatives to be lean, fit and athletic. Are we lean, fit and athletic?”

  “There are desserts,” Donald Mackenzie said. Like Dermott he was a large and comfortable man with a rugged, weatherbeaten face, a little larger and a little less comfortable. Observers often took him and his partner for a pair of retired heavyweight boxers. “I can see cakes, cookies and a wide variety of pastries,” he went on. “You read their food brochure? Says that the average man requires at least five thousand calories a day to cope with Arctic conditions. But we, George, are not average men. Six thousand would do better in a pinch. Nearer seven would be safer, I’d say. Chocolate mousse and double cream?”

  “He had a notice about it on the staff bulletin board,” Dermott said wryly. “Heavy black border, for some reason. Signed, too.”

  “Senior operatives don’t look at staff boards,” Mackenzie sniffed. He heaved his 220 pounds erect and headed purposefully for the food counter. There was no doubt that B.P./Sohio did extremely well by their staff. Here at Prudhoe Bay, on the bitter rim of the Arctic Ocean in midwinter, the spacious, light and airy dining-room, with multi-coloured pastel walls back-dropping the recurrent five-pointed star motif, was maintained at a pleasantly fresh 72 degrees by the air-conditioned central heating. The temperature difference between the dining-room and the outside world was 105°F. The range of excellently-cooked food was astonishing.

  “Don’t exactly starve themselves up here,” he said as he returned with a mousse for each of them and a pitcher of heavy cream. “I wonder what any of the old Alaskan sourdoughs would have made of it.”

  The first reaction of a prospector or trapper of yesteryear would have been that he was suffering from hallucinations. All in all, it was hard to say what feature he would have found the most astonishing. Eighty per cent of the items on the menu would have been unknown to him. But he would have been still more amazed by the forty-foot swimming-pool and the glassed-in garden, with its pine-trees, birches, plants and profusion of flowers, that abutted on the dining-room.

  “God knows what the old boy would have thought,” said Dermott. “You might ask him, though.” He indicated a man heading in their direction. “Jack London would have recognised this one right away.”

  Mackenzie said: “More the Robert Service type, I’d say.”

  The newcomer certainly wasn’t of current vintage. He wore heavy felt boots, moleskin trousers and an incredibly faded mackinaw, which went well enough with the equally faded patches on the sleeves. A pair of sealskin gloves was suspended from his neck, and he carried a coonskin cap in his right hand. His hair was long and white and parted in the middle. He had a slightly hooked nose and clear blue eyes with deeply entrenched crow’s feet, which could have been caused by too much sun, too much snow or a too highly developed sense of humour. The rest of his face was obscured by a magnificent grizzled beard and moustache, both of which were at that moment rimed by droplets of ice. The yellow hard hat swinging from his left hand struck a jarring note. He stopped at their table, and from the momentary flash of white teeth it could be assumed that he was smiling.

  “Mr Dermott? Mr Mackenzie?” He offered his hand. “Finlayson. John Finlayson.”

  Dermott said: “Mr Finlayson. Field operations manager’s office?”

  “I am the field operations manager.” He pulled out a chair, sat, sighed and removed some ice particles from his beard. “Yes, yes, I know. Hard to believe.” He smiled again, gestured at his clothing. “Most people think I’ve been riding the rods. You know, hobo on the box-cars. God knows why. Nearest railroad track’s a long, long way from Prudhoe Bay. Like Tahiti and grass skirts. You know, gone native. Too many years on the North Slope.” His oddly staccato manner of speech was indeed suggestive of a person whose contact with civilisation was, at best, intermittent. “Sorry I couldn’t make it. Meet you, I mean. Deadhorse.”

  Mackenzie said: “Deadhorse?”

  “Airstrip. A little trouble at one of the gathering centres. Happens all the time. Sub-zero temperatures play hell with the molecular structure of steel. Being well taken care of, I hope?”

  “No complaints.” Dermott smiled. “Not that we require much care. There the food counter, here Mackenzie. The watering hole and the camel.” Dermott checked himself: he was beginning to talk like Finlayson. “Well, one little complaint, perhaps. Too many items on the lunch menu, too large a helping of any item. My colleague’s waist-line—”

  “Your colleague’s waist-line can take care of itself,” Mackenzie said comfortably. “But I do have a complaint, Mr Finlayson.”

  “I can imagine.” Another momentary flash of teeth, and Finlayson was on his feet. “Let’s hear it in my office. Just a few steps.” He walked across the dining-hall, stopped outside a door and indicated another door to the left. “Master operations control centre. The heart of Prudhoe Bay—or the western half of it, at least. All the computerized process control facilities for the supervision of the field’s operations.”

  Dermott said: “An enterprising lad with a satchelful of grenades could have himself quite a time in there.”

  “Five seconds, and he could close down the entire oilfield. Come all the way from Houston just to cheer me up? This way.”

  He led them through the outer door, then through an inner one to a small office. Desks, chairs and filing cabinets, all in metal, all in battleship grey. He gestured them to sit and smiled at Mackenzie. “As the French say, a meal without wine is like a day without sunshine.”

  “It’s this Texas dust,” Mackenzie said. “Sticks in the gullet like no other dust. Laughs at water.”

  Finlayson made a sweeping motion with his hand. “Some big rigs out there. Damned expensive and damned difficult to handle. It’s pitch dark, say, forty below and you’re tired—you’re always tired up here. Don’t forget we work twelve hours a day, seven days a week. A couple of Scotches on top of all that, and you’ve written off a million dollars’ worth of equipment. Or you damage the pipeline. Or you kill yourself. Or, worst of all, you kill some of your mates. Comparatively, they had it easy in the old prohibition days—bulk smuggling from Canada, bathtub gin, illicit stills by the thousand. Rather different on the North Slope here—get caug
ht smuggling in a teaspoonful of liquor, and that’s it. No argument, no court of appeal. Out. But there’s no problem—no one is going to risk eight hundred dollars a week for ten cents’ worth of bourbon.”

  Mackenzie said: “When’s the next flight out to Anchorage?”

  Finlayson smiled. “All is not lost, Mr Mackenzie.” He unlocked a filing cabinet, produced a bottle of Scotch and two glasses and poured with a generous hand. “Welcome to the North Slope, gentlemen.”

  “I was having visions,” said Mackenzie, “of travellers stranded in an Alpine blizzard and a St Bernard lolloping towards them with the usual restorative. You’re not a drinking man?”

  “Certainly. One week in five when I rejoin my family in Anchorage. This is strictly for visiting V.I.P.s. One would assume you qualify under that heading?” Thoughtfully, he mopped melting ice from his beard. “Though frankly, I never heard of your organisation until a couple of days ago.”

  “Think of us as desert roses,” Mackenzie said. “Born to blush and bloom unseen. I think I’ve got that wrong, but the desert bit is appropriate enough. That’s where we seem to spend most of our time.” He nodded towards the window. “A desert doesn’t have to be made of sand. I suppose this qualifies as an Arctic desert.”

  “I think of it that way myself. But what do you do in those deserts? Your function, I mean.”

  “Our function?” Dermott considered. “Oddly enough, I’d say our function is to reduce our worthy employer, Jim Brady, to a state of bankruptcy.”

  “Jim Brady? I thought his initial was A.”

  “His mother was English. She christened him Algernon. Wouldn’t you object? He’s always known as Jim. Anyway, there are only three people in the world any good at extinguishing oil-field fires, particularly gusher fires, and all three are Texas-based. Jim Brady’s one of the three.

  “It used to be commonly accepted that there are just three causes of such oil fires: spontaneous combustion, which should never happen but does; the human factor, i.e. sheer carelessness; and mechanical failure. After twenty-five years in the business Brady recognised that there was a fourth and more sinister element involved, that would come broadly speaking under the heading of industrial sabotage.”