The Night Lives On (7 page)

Suddenly there was a fearful crash, sending everybody sprawling among the palms and violins. The
Arizona
had smashed head on into a giant iceberg, shattering 30 feet of her bow. But the forward bulkhead held; there were no casualties; and two days later she limped into St. John’s. In a curious twist of logic, the accident was hailed as an example of the safety of ships, rather than the dangers of ice.

There were other close calls too. In 1907 the North German Lloyd Liner
Kronprinz Wilhelm
dented her bow and scarred her starboard side, brushing a berg in the
pre-dawn darkness. In 1909 the immigrant Ship
Volturno
barely escaped damage, running through a huge ice field. In 1911 the Anchor Liner
Columbia
struck a berg off Cape Race, driving her bow plates back ten feet. The jar injured several crewmen and broke one passenger’s ankle. It was foggy at the time; so perhaps the accident was discounted.

Such incidents were ignored; most captains continued to run at full speed. Always dangerous, the practice became even more so with the vast leap in the size of ships at the turn of the century. It was one thing to dodge an iceberg in the 10,000-ton
Majestic
, Captain Smith’s command in 1902, but quite a different matter only ten years later in the 46,000-ton
Titanic.
The momentum of such a huge ship was enormous, and she just couldn’t stop suddenly or turn on a dime.

The
Titanic
tested making an emergency stop only once during those brief trials in Belfast Lough, and that at the very moderate speed of 18 knots. Her turning tests seem almost as minimal: she apparently made two complete circles at 18-20 knots and then carried out three other turns at 11, 19½, and 21¼ knots. Her performance at maximum speed remains a mystery. Once again the question arises: how much did Captain Smith really know about the great vessel under his feet?

Arguably, the practice of maintaining speed might have been a practical necessity in the days before wireless, for who knew where the ice really was? The sightings came from vessels reaching port several days later, and by that time the information was too stale to pinpoint the danger. But Signor Marconi’s genius changed everything. The reports reaching the
Titanic
told exactly where the ice could be found, only hours away.

Why couldn’t Captain Smith and his officers see the difference? Certainly they knew the importance of wireless in an emergency. The help summoned by the sinking liner
Republic
in 1909 proved that. But no one on the
Titanic’s
bridge seemed to appreciate the value of wireless as a constant, continuous navigational aid. Basically, they still thought of it as a novelty—something that lay outside the normal running of the ship. It was a mindset tellingly illustrated by the way the wireless operators were carried on the roster of the crew. Phillips and Bride were not listed with the Deck Department; they came under the Victualling Department—like stewards and pastry chefs.

So the
Titanic
raced on through the starlit night of April 14. At 10
P.M.
First Officer Murdoch arrived on the bridge to take over Second Officer Lightoller’s watch. His first words: “It’s pretty cold.”

“Yes, it’s freezing,” answered Lightoller, and he added that the ship might be up around the ice any time now. The temperature was down to 32°, the water an even colder 31°. A warm bunk was clearly the place to be, and Lightoller quickly passed on what else the new watch needed to know: the carpenter and engine room had been told to watch their water, keep it from freezing…the crow’s nest had been warned to keep a sharp lookout for ice, “especially small ice and growlers”…the Captain had left word to be called “if it becomes at all doubtful.”

Lightoller later denied that the sudden cold had any significance. He pointed out that on the North Atlantic the temperature often took a nose dive without any icebergs in the area. Indeed this was true. The sharp drop in temperature did not necessarily mean ice, but it was
also true that it
could
mean ice. It was, in short, one more signal calling for caution. After all, that was the whole point of taking the temperature of the water every two hours.

There’s no evidence that either Lightoller or Murdoch saw it that way. The bitter cold and the reported ice remained two separate problems. Lightoller had passed on all the information he could; so now he went off on his final rounds, while Murdoch pondered the empty night.

A few yards aft along the Boat Deck, First Wireless Operator Phillips dug in to a stack of outgoing messages. His set had a range of only 400 miles during daylight, and the American traffic had piled up. Now at last he was in touch with Cape Race and was working off the backlog. Some were passenger messages for New York—arrival times, requests for hotel reservations, instructions to business associates. Others were being relayed for ships no longer in direct touch with the land.

At 11
P.M
. the steamer
Californian
suddenly broke in: “I say, old man, we’re stopped and surrounded by ice.” She was so close that her signal almost blasted Phillips’s ears off.

“Shut up, shut up,” he shot back, “I’m busy. I’m working Cape Race.” Then he went back to the outgoing pile—messages like this one relayed to a Los Angeles address from a passenger on the
Amerika
:

NO SEASICKNESS. ALL WELL. NOTIFY ALL INTERESTED. POKER BUSINESS GOOD. AL.

In the crow’s nest Lookouts Fleet and Lee peered into the dark. There was little conversation; they were keeping an extra-sharp lookout. At 11:40 Fleet suddenly spotted something even blacker than the night. He banged the crow’s-nest bell three times and lifted the phone to the bridge. Three words were enough to explain the trouble: “Iceberg right ahead.”

Now it was Murdoch’s problem. He put his helm hard astarboard, hoping to “port around” the ice, and at the same time pulled the engine room telegraph to STOP, and then REVERSE ENGINES. But it was too late: 37 seconds later the
Titanic
brushed by the berg with that faint, grinding jar that every student of the disaster knows so well.

The 37 seconds—based on tests later made with the
Olympic
—are significant only for what they reveal about human miscalculations. At 22½ knots the
Titanic
was moving at a rate of 38 feet a second…meaning that the berg had been sighted less than 500 yards away. But all the experts agreed that on a clear night like this the ice should have been seen much farther off. Lightoller thought at least a mile or so, and this undoubtedly reflected Captain Smith’s opinion, for they both had gone over this very point on the bridge shortly after 9:00. The search immediately began for some extenuating circumstance that could explain the difference.

Suspicion focused first on the lookouts. How good were their eyes? Fleet’s had not been tested in five years, and Lee’s not since the Boer War. Yet tests after the collision showed both men had sound vision. Nor were they inexperienced. Unlike most lines, White Star used trained, full-time lookouts, who received extra pay for their work.

Next it was the lookouts’ turn to complain. They charged that there were no binoculars in the crow’s nest. A pair had been supplied during the trip from Belfast to Southampton, but during a last-minute shake-up of personnel they had been removed and never replaced. After hearing numerous experts on the subject, the British Inquiry decided that it really didn’t matter. Binoculars were useful in identifying objects, but not in initially sighting them. That was better done by the naked eye. Here, there was no problem of identification; Fleet knew all too well what he had seen.

Then Lookout Lee came up with a “haze” over the water. He described dramatically how Fleet had said to him, “Well, if we can see through that, we will be lucky.” Fleet denied the conversation and said the haze was “nothing to talk about.” Lightoller, Boxhall, and Quartermaster Hitchens, who had been at the wheel, all described the night as perfectly clear. In the end, the British Inquiry wrote off Lee’s “haze” as an understandable bit of wishful thinking.

Lightoller himself contributed what became known as the “blue berg” theory. He argued that the iceberg had recently capsized and was showing only the dark side that had previously been under water, making it almost invisible. But this theory did not seem to fit the recollections of the few survivors who actually saw the berg. It was anything but invisible to Quartermaster Rowe, standing on the after bridge. He estimated that it was about 100 feet high, and he initially mistook it for a windjammer gliding along the side of the ship with all sails set.

The only explanation left was “fate.” As Lightoller put it, the
Titanic
was the victim of an extraordinary set
of circumstances that could only happen once in a hundred years. Normally there would have been no problem, but on this particularly freakish night “everything was against us.”

But this explanation implies that Captain Smith didn’t know—and couldn’t be expected to know—the nature of the night he was up against. But he
did
know. He fully realized that the sea was flat calm, that there was no moon, no wind, no swell. He understood all this and took it into account in deciding not to reduce speed. Under these circumstances the collision quickly loses its supernatural quality and becomes simply a case of miscalculation.

Given the competitive pressures of the North Atlantic run, the chances taken, the lack of experience with ships of such immense size, the haphazard procedures of the wireless room, the casualness of the bridge, and the misassessment of what speed was safe, it’s remarkable that the
Titanic
steamed for two hours and ten minutes through ice-infested waters without coming to grief any sooner.

“Everything was against us”? The wonder is that she lasted as long as she did.

W
HAT DID THE ICEBERG
really do to the
Titanic
, and could anything have been done to save her? The report of the official British Inquiry found that “the damage extended over a length of about 300 feet,” and this is generally taken to mean a continuous gash running from the bow for 300 feet along the starboard side of the ship. Countless illustrators have depicted it in books and magazines—a single, jagged slash, ugly and lethal-looking.

Actually, such a gash would have sunk the
Titanic
in less than an hour. The true nature of the damage may be partly revealed as exploration of the wreck continues over the coming years, but it will often be hard to tell what was done by the iceberg and what was caused by the impact as she struck the ocean floor. The bow ploughed into a plateau of mud and sand some 13,000 feet down, at a speed of possibly 30-40 miles per hour. The forward end of the ship is buried to a depth of 50 feet, well hidden from the lens of any camera. Even the most sophisticated equipment will probably tell us less than a little-known witness at the British Inquiry, who was nowhere near the
Titanic
that night, but who knew
her far better than any survivor or future investigator.

Edward Wilding was a naval architect at Harland & Wolff. His primary concern had been the design of the
Titanic
, and he seemed to have at his fingertips every conceivable dimension of the ship. He knew, for instance, the exact length of each watertight compartment. Using these figures, he estimated that any continuous gash along the starboard side had to run some 249 feet—the length of the first five compartments plus the first two feet of the sixth.

Estimating the width of such a gash was more complicated, but he found some clues in the testimony of various witnesses who had been on the spot. Ten minutes after the crash, Leading Fireman Fred Barrett saw eight feet of water in Boiler Room 6, which was five feet above the keel of the ship. Ten minutes later, Third Officer Pitman watched bags of registered letters floating around the mail room, 24 feet above the keel. Another five minutes and the squash court was awash, 32 feet above the keel. Fifteen minutes more, and the sea was flooding into the seamen’s quarters on E Deck forward, 48 feet above the keel. Putting the evidence together, Edward Wilding estimated that 16,000 cubic feet of water had entered the shattered hull in the first 40 minutes.

What size hole would produce this result? Here Wilding’s educated guess had to be built on certain basic assumptions. First, he assumed that the witnesses were accurate in their estimates of time and the depth of the water at their particular vantage point. He also assumed that the draft of the
Titanic
would be the same as that of the
Olympic
at the same stage in the voyage. All this granted, he then calculated that the area of damage
had to be 12 square feet. Anything else would not fit his timetable.

But this posed a new problem. If the damage was really a continuous gash 249 feet long, then it could only have averaged ¾ of an inch high. Nothing else would work out at 12 square feet. Since this was most unlikely, it followed that the gash was not continuous, but rather a series of random pokes and stabs as the berg bumped along the side of the
Titanic.
Occasionally, bits of the berg broke off, making the pattern of holes still more irregular.

Based on photographs recently taken of the wreck, it appears that there were fewer of these pokes and stabs than Wilding thought. The berg seems to have struck the
Titanic
a heavy glancing blow, now hidden by the mud, springing plates and popping rivets along the starboard side forward. It was through these opened seams that the water cascaded in, dooming the ship.

Whatever the nature of the wound, there was no doubt that it was fatal. It completely flooded the first five compartments, pulling the bow down so far that the water in the fifth compartment eventually slopped over the top of the after bulkhead into the sixth, which in turn overflowed into the seventh, and so on until the ship had to sink.

Later, much was made of the fact that the watertight bulkhead between the fifth and sixth compartments went only as high as E Deck. If this bulkhead had been carried one deck higher, to D Deck, the
Titanic
would not have sunk. This is true, assuming that the only damage to the sixth compartment came from the two-foot gash in Boiler Room 5. This was easily controlled by the pumps.