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Lawrence Krauss - The Greatest Story Ever Told--So Far

Page 14

by Why Are We Here (pdf)


  the neutron loses energy when it gets bound in a nucleus, its mass

  gets smaller. But since its mass when it is isolated is just a smidgen

  more than the sum of the masses of a proton and an electron, when

  it loses mass, it no longer has sufficient energy to decay into a proton

  and an electron. If it were to decay into a proton, it would have to

  either release enough energy to also eject the proton from the

  nucleus, which, given standard nuclear-binding energies, it would

  not have, or else release enough energy to allow the new proton to

  remain in a new stable nucleus. Since the new nucleus would be that

  of a different element, adding one additional positive charge to the

  nucleus also generally requires more energy than the minute amount

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  available when a neutron decays. As a result, the neutron and most

  atomic nuclei containing neutrons remain stable.

  The entire stability of the nuclei that make up everything we see,

  including most of the atoms in our body, is an accidental

  consequence of the fact that the neutron and proton differ in mass

  by only 0.1 percent, so that a small shift in the mass of the former,

  when embedded in nuclei, means it can no longer decay into the

  latter. That is what I learned from Tommy Gold.

  It still amazes me when I think about it. The existence of complex

  matter, the periodic table, everything we see, from distant stars to

  the keyboard I am typing this on—hinges on such a remarkable

  coincidence. Why? Is it an accident, or do the laws of physics require

  it for some unknown reason? Questions such as these drive us

  physicists to search deeper for possible answers.

  The discovery of the neutron, and the subsequent observation of

  its decay, introduced more than one new particle into the subatomic

  zoo. It suggested that perhaps two of the most fundamental

  properties of nature—the conservation of energy and the

  conservation of momentum—might break down on the

  microscopic-distance scales of nuclei.

  Almost twenty years before discovering the neutron, James

  Chadwick had observed something strange about beta rays, well

  before he or anyone else knew that they originated from decaying

  neutrons. The spectrum of energy carried by electrons emitted in

  neutron decay is continuous, going from essentially zero energy up

  to a maximum energy, which depends on the energy available after

  the neutron has decayed—for a free neutron this maximum energy is

  the energy difference between the mass of the neutron and the sum

  of the masses of the proton and electron.

  There is a problem with this, however. It is easiest to see the

  problem if we imagine for the moment that the proton and the

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  electron have equal masses. Then, if the proton carries off more

  energy than the electron after the decay, it would be moving faster

  than the electron. But if they have the same mass, then the proton

  would also have more momentum than the electron. But if the

  neutron decays at rest, then its momentum before the decay would

  be zero, so the momentum of the outgoing proton would have to

  cancel that of the outgoing electron. But that is impossible unless

  they have equal momenta, going in opposite directions. So the

  magnitude of the proton’s momentum could never be greater than

  that of the electron. In short, there is only one value for the energy

  and the momentum of the two particles after the decay if they have

  equal masses.

  The same reasoning, though mathematically a bit more involved,

  applies even if the proton and electron have different masses. If they

  are the only two particles produced in the decay of the neutron, their

  speeds, and hence their energy and momenta, would be required to

  each have unique, fixed values that depend on the ratio of their

  respective masses.

  As a result, if electrons from beta decay of neutrons come off with

  a range of different energies, this would violate the conservation of

  energy and momentum. But, as I subtly suggested above, this is only

  true if the electron and proton are the only particles produced as

  products of the neutron decay.

  Again, in 1930, only a few years before the discovery of the

  neutron, the remarkable Austrian theoretical physicist Wolfgang

  Pauli wrote a letter to colleagues at the Swiss Federal Institute of

  Technology, beginning with the immortal header “Dear radioactive

  ladies and gentlemen,” in which he outlined a proposal to resolve

  this problem, which he also said he didn’t “feel secure enough to

  publish anything about.” He proposed that a new electrically neutral

  elementary particle existed, which he called a neutron, and that in

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  addition to the electron and the proton this new neutral particle was

  produced in beta decay so that the electron, proton, and this particle

  together could share the energy available in the decay, allowing a

  continuous spectrum.

  Pauli, who later won the Nobel Prize for his “exclusion principle”

  in quantum mechanics, was no fool. In fact, he had no patience for

  fools. He was famous for supposedly rushing up to the blackboard

  during lectures and removing the chalk from the speaker’s hand if he

  felt nonsense was being spouted. He could be scathingly critical of

  theories he didn’t like, and his worst criticism was reserved for any

  idea that was so vague, as he put it, “it isn’t even wrong.” (A dear old

  colleague of mine when I taught at Yale, the distinguished

  mathematical physicist Feza Gürsey, once responded to a reporter

  who asked what was the significance of an announcement of some

  overhyped idea proposed by some scientists seeking publicity by

  saying, “It means Pauli must be dead.”)

  Pauli realized that proposing a new elementary particle that

  hadn’t been observed was speculative in the extreme, and he argued

  in his letter that such a particle was unlikely both because it had

  never been seen and would therefore have to interact weakly with

  matter, and also because it would have to be very light to be

  produced along with an electron, given that the energies available in

  beta decay were so small compared to the proton’s mass.

  The first problem that arose with his idea was the name he chose.

  After Chadwick’s 1932 experimental discovery of the particle we

  now call the neutron, appropriate for a neutral cousin of the proton

  with comparable mass, Pauli’s hypothesized particle needed another

  name. The brilliant Italian physicist and colleague of Pauli’s—Enrico

  Fermi—came up with a solution in 1934, changing its name to

  neutrino, an Italian pun for “little neutron.”

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  It would take twenty-six years for Pauli’s neutrino to be

  discovered, enough time for the little particle, and its heavier cousin,

  the neutron, to force physicists to totally revamp their views on the

  forces that govern the cosmos, the nature of light, and even the

  nature of empty space.

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  C h a p t e
r 1 0

  F R O M

  H E R E T O

  I N F I N I T Y:

  S H E D D I N G L I G H T O N T H E

  S U N

  I have fought a good fight, I have finished my course, I have kept

  the faith.

  —2 TIMOTHY 4:7

  The physicist Enrico Fermi is largely unsung in the public’s

  eyes, but he remains one of the greatest twentieth-century physicists.

  He, together with Richard Feynman, more than any of the other

  remarkable figures from that equally remarkable period in physics,

  most influenced my own attitude and approach to the field, as well

  as my own understanding of it. I only wish I were as talented as

  either of them.

  Born in 1901, Fermi died at the age of fifty-three of cancer,

  perhaps brought on by his work on radioactivity. In 1954, when he

  died, he was nine years younger than I am as I write this. But in his

  short life he pushed forward the frontiers of both experimental and

  theoretical physics in a way that no one has since repeated, and no

  one is ever likely to do again. The complexity of the array of

  theoretical tools now used to develop physical models, and the

  complexity of machinery now used to test them, are separately too

  sophisticated to allow any single individual today, no matter how

  talented, to remain on the vanguard of both endeavors at the level

  Fermi achieved in his time.

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  In 1918, when Fermi graduated from high school in Rome, the

  possibilities open to a brilliant young scientific mind were far less

  constrained. Quantum mechanics had just been born, new ideas

  were everywhere, and the rigorous mathematics necessary to deal

  with these ideas had not yet been developed or applied.

  Experimental physics had yet to enter the domain of “big science”;

  experiments could be performed by individual researchers in

  makeshift laboratories, and they could be completed in weeks

  instead of months.

  Fermi applied to the prestigious Scuola Normale Superiore in

  Pisa, which required an essay as part of the entrance exam. The

  theme that year was “specific characteristics of sounds.” Fermi

  submitted an “essay” that included solving partial differential

  equations for a vibrating rod and applying a technique called Fourier

  analysis. Even today, these mathematical techniques are not

  normally encountered until maybe the third year of an

  undergraduate degree, and for some students not until graduate

  school. But as a seventeen-year-old, Fermi sufficiently impressed the

  examiners to receive first place in the exam.

  At the university, Fermi first majored in mathematics but

  switched to physics and largely taught himself General Relativity—

  which Einstein had only developed a few years earlier—as well as

  quantum mechanics and atomic physics, which were then emerging

  fields of research. Within three years of arriving at the university he

  published theoretical papers in major physics journals on subjects

  from General Relativity to electromagnetism. At the age of twenty-

  one, four years after beginning his university studies, he received his

  doctoral degree for a thesis exploring the applications of probability

  to X-ray diffraction. At the time a thesis on purely theoretical issues

  was not acceptable for a physics doctorate in Italy, so this

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  encouraged Fermi to ensure his competence in the laboratory as well

  as with pen and paper.

  Fermi moved to Germany, the center of the emerging research on

  quantum mechanics, and then to Leiden, Holland, where he met

  with the most famous physicists of the day—Born, Heisenberg, Pauli,

  Lorentz, and Einstein, to name a few—before returning to Italy to

  teach. In 1925, Wolfgang Pauli proposed the “exclusion principle,”

  which disclosed that two electrons could not occupy exactly the

  same quantum state at the same time and place, and which laid the

  basis of all of atomic physics. Within a year, Fermi applied this idea

  to systems of many such identical particles that, like electrons, have

  two possible values of spin, angular momentum, which we call spin

  up, and spin down. He thus established the modern form of the field

  called statistical mechanics, which is at the basis of almost all

  materials science, semiconductors, and those areas of physics that

  led to the creation of modern electronic components such as

  computers.

  As I earlier emphasized, there is no intuitive way to picture a

  point particle as spinning around some axis. It is simply one of the

  ways that quantum mechanics evades our notions of common sense.

  Electrons are called spin ½ particles because the magnitude of their

  spin angular momentum turns out to be half as big as the lowest

  value of angular momentum associated with the orbital motion of

  electrons in atoms. Any spin ½ particle such as an electron is called a

  fermion, named in Fermi’s honor.

  At the tender age of twenty-six Fermi was elected to a new chair

  in theoretical physics at the University of Rome and thereafter led a

  vibrant group of students, including several subsequent Nobel

  laureates, as they explored atomic and then nuclear physics.

  In 1933, Fermi was motivated by another proposal of Pauli’s, that

  for the new particle produced in the decay of neutrons, which Fermi

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  labeled a neutrino. But naming the new particle was just an aside.

  Fermi had much bigger fish to fry, and he produced a theory for

  neutron decay that revealed the possible existence of a new

  fundamental force in nature, the first new force known to science

  beyond electromagnetism and gravity—which was in its own way

  inspired by thinking about light. Although it wasn’t obvious at the

  time, this was to be the first of two new forces associated with

  atomic nuclei, which together with electromagnetism and gravity,

  comprise all the forces known to operate in nature, from the

  smallest subatomic scales to the motion of galaxies.

  When Fermi submitted his proposal to the journal Nature, the

  editor turned it down because it was “too remote from physical

  reality to be of interest to readers.” For many of us who have since

  had papers rejected by equally high-handed editors at that journal, it

  is comforting to know that Fermi’s paper, one of the most important

  proposals in twentieth-century physics, also didn’t make the cut.

  This inappropriate rejection was undoubtedly frustrating to

  Fermi, but it did have a useful side effect. Fermi decided instead to

  return to experimental physics, and in short order he began to

  experiment with the neutrons discovered by Chadwick two years

  earlier. Within several months Fermi had developed a powerful

  radioactive source of neutrons and found that he was able to induce

  radioactive decays in otherwise stable atoms by bombarding them

  with neutrons. Bombarding uranium and thorium with neutrons, he

  also witnessed nuclear decays and thought he had created new

  elements. In fact, he had actually caused the nuclei to split, or
fission,

  into lighter nuclei, which were later found to also emit more

  neutrons than they absorbed in the process—as other scientists

  discovered in 1939.

  Fermi’s segue into experiment turned out to be good for him.

  Four years later, in 1938, at the age of thirty-seven, he was awarded

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  the Nobel Prize for introducing artificial radioactivity, creating new

  radioactive elements by neutron bombardment. Yet by 1938 the

  Nazis had begun to establish their racial laws in Germany, and Italy

  had followed suit, so Fermi’s Jewish wife, Laura, was endangered. So,

  after receiving the prize in Stockholm, Fermi and his family didn’t

  return to Italy but moved to New York City, where he accepted a

  position at Columbia.

  When Fermi learned the news about nuclear fission in 1939 in

  New York, following a lecture by Niels Bohr at Princeton, Fermi

  amended his earlier Nobel acceptance speech to clarify his earlier

  error and in short order reproduced the German results. Before long,

  he and his collaborators realized that this produced the possibility of

  a chain reaction. Neutrons could bombard uranium, causing it to

  fission and release energy, and to release more neutrons that could

  bombard more uranium atoms and so on.

  Soon after, Fermi gave a lecture to the US Navy warning of the

  potential significance of this result, but few took him seriously. Later

  that year, Einstein’s famous letter made its way to President

  Roosevelt and changed the course of history.

  Fermi had recognized the potential dangers inherent in releasing

  the energy of the atomic nucleus even earlier. A year after getting his

  doctorate, in 1923, he wrote the appendix for a book on relativity

  and talked of the potential of E = mc2, writing at the time, “It does

  not seem possible, at least in the near future, to find a way to release

  these dreadful amounts of energy—which is all to the good because

  the first effect of an explosion of such a dreadful amount of energy

  would be to smash into smithereens the physicist who had the

  misfortune to find a way to do it.”

  That idea must have been on his mind in 1941 when, as part of

  the newly established Manhattan Project, Fermi was assigned the

  task of creating a controlled chain reaction—namely creating a

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  nuclear reactor. While those in charge were understandably worried

 

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