Then he realized it was covered in thousands of bees.

“This is called a swarm board,” said the professor. “A swarm is group of bees that has left its hive. The swarm has but one job: to find a new location for a hive. And it’s a life-or-death decision.” Bees came and went from the swarm, a cloud of them swirling around the buzzing mass. Pete had always pictured beekeepers draped in white, protective clothing, with pith helmets and protective face masks. But everyone present other than him seemed unbothered by the tens of thousands of stinging insects that undulated in a mass in front of them. Everyone was dressed like the professor, shorts and T-shirts, not even gloves to protect them.

“Are they looking for a new home right now?” asked Pete. “They don’t look like they’re doing anything.”

The professor nodded. “The swarm is made up of about ten thousand worker bees. Of that, the oldest, most experienced bees — about three hundred — become scouts. They go out, look for suitable locations, and come back and communicate the location to the swarm.” Pete wanted to get a better look at the swarm but didn’t want to stick his face any closer.

“With the waggle dance?”

“Exactly,” said the professor. “But then they collectively decide, over a day or so, what the best location is.”

“And they get it right?”

“Always,” said the professor.

“What makes one location better than another?”

The professor nudged one of the grad students, who was staring into space. “Will, you tell him.”

“Height,” answered Will. “They want to be high off the ground so animals can’t get into it. Ideally, they want a small entrance, also to keep predators away. And volume. The bigger the better.”

“Good!” said the professor, slapping him on the back. The professor was obviously brilliant, Pete knew from his credentials. But he also clearly enjoyed working with young people.

Suddenly a bee stung Pete on his forearm.

“Ouch!” he said, sweeping the dead bee away. It fell to the ground. The pain spread through his arm as he looked down at the small black stinger that still protruded from his skin. He plucked it out and looked at the painful red spot that the bee had given its life for.

The professor smiled. “OK, now you’re really one of us!”

“You guys get stung too?”

“All the time,” said Will. “We’re just used to it.”

Another bee landed on Pete’s arm. He stayed perfectly still until it flew away.

“Feel like moving somewhere else?” said the professor.

“Sure,” said Pete.

“Let’s go look at their potential homes.”

They walked back into the woods down another path, Pete occasionally rubbing his arm where he’d been stung. When they came into a clearing, Pete saw another wooden structure, this time a box. A lone grad student was sitting in a chair beside it, sheltered from the sun by a large multicolored umbrella. She was in a beach chair, relaxed, her long legs crossed.

“We have four boxes set up like this all around the woods,” said Healy. “They’re all identical, except for size. One is forty liters, the others are fifteen.”

“This one?” said Pete, pointing.

“This one is not the forty-liter dream home,” said Healy. “This one is the small fixer-upper.”

“Do all the scouts look at all the sites?”

“No,” said Healy, “and this is what’s fascinating. The same scouts will visit this site over and over, bring that information back to the swarm. But in their communications, which are always truthful, the swarm will choose the right site.”

“How do you know which scouts go to which site?” said Pete.

“I’ll show you!” said Healy, and they marched forward.

The potential home was a small wooden box inside a three-sided shelter. But Pete couldn’t tear his eyes away from the young woman in the beach chair.

“Pamela!” said Healy. “My star pupil.”

She rolled her eyes at the praise.

“Tell our guest what you are doing.…”

“Watching and waiting…” she said, making a dramatic flourish with her hand. She then leaned back in the chair, folded her arms, and waited for Pete to react. She was blond, and tall — he could tell, even with her sitting down, by the length of her tanned, athletic legs. She had piercing blue eyes that she trained on Pete without mercy. He could tell that she was used to paralyzing guys like him with a glance, enjoyed the sport of it. The professor, an experienced observer of all things living, recognized what was going on and was amused.

Suddenly, she leaned forward. A bee had landed on the sill of the box, in front of the small hole that was the entrance. As it wandered inside, Pamela placed a small net in front of the opening.

When the bee came out, it was trapped. She pulled it away and gripped the bee by its wings. With her free hand she took a tiny paint brush, the kind you might use on a model airplane, and painted a tiny yellow dot on the back of the bee. She released the bee, and it flew away. The entire operation had taken extraordinary delicacy.

“That’s how we know, back at the swarm, which bees come from which box. Each has a different color.”

Pete felt pressure to say something, anything, to look intelligent, as Pamela leaned over to catch another scout bee that was leaving the hive.

“Doesn’t that bother them?” he said. “Getting held and painted?”

“No,” she said brightly, looking up at him and waiting for the bee to enter the net. “They don’t even know they’ve been caught.”

Quality versus quantity is an ancient military debate. Is it better to have a few expensive weapons systems with exquisite capabilities, or vast quantities of less capable systems that can be thrown at the enemy en masse? Overwhelmingly, the history of combat teaches that quantity almost always wins over quality. Put three noisy, slow submarines against a quiet, modern submarine, and the slow submarines will probably win. Raise the ratio to 5:1, and the modern sub is doomed. It might shoot the first enemy, maybe even the second, but in doing so it will reveal its position and deplete its torpedoes. Similar logic can be applied to tanks, planes, and even platoons of infantrymen. This idea was first quantified in World War I by British military theorist Frederick Lanchester, who created Lanchester’s law: all things being equal, a twofold increase in combat units will result in a fourfold increase in combat power.

World War II proved the truth of Lanchester’s law again and again. The Germans produced better planes and tanks than the Allies. The Panzer and the Stuka were superior to anything the Allies could put together, especially early in the war. But the Allies’ sheer quantity, driven primarily by American manufacturing might, overwhelmed any German advantage. By 1944, the Allies were producing a ship every day, and a plane, incredibly, every five minutes. The Russians, too, always believers in the power of numbers, outmanufactured their enemies to the point that any German technological advantage was negated. The spectacle of the Soviet May Day parade was an annual manifestation of this philosophy, endless columns of men and munitions. Stalin summed it up memorably with his quote: “Quantity has a quality of its own.”

After World War II, however, the United States backed away from this proven philosophy. Unable to produce either vast quantities of arms or massive standing armies, due to both political and budgetary limitations, the United States banked on its technological prowess. The result was fewer and fewer platforms of ever-increasing power. This was true across all branches, as the Pentagon procured ever-more-expensive tanks, submarines, and airplanes. In a vicious cycle, as the cost of each platform went up, the number of them procured went down. Norman Augustine, former under secretary of the Army, theorized only partially tongue-in-cheek that by 2054, at the historic rate of increase, the entire US defense budget would be used to procure a single airplane. He suggested that it be used three and a half days a week each by the Navy and the Air Force, with the Marine Corps getting it once every leap year.