Knocking on Heaven's Door (63 page)

BOOK: Knocking on Heaven's Door
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Technology also makes each of us the center of our own universe, as we see physically in MapQuest or metaphorically on any social networking site. But the problems of the world are far more extensive and global. Technology can enable solutions, but they are more likely to come when also prompted by clear and creative thinking—the kind we see in the best scientific work.

In the past, our nation’s attention to science and technology—along with the recognition that we need to make long-term commitments and stick to them—has proved to be a successful strategy that kept us in the forefront of new developments and ideas. We now seem to be in danger of losing these values that have worked so well for us before. We need to recommit to these principles as we seek not just short-term advances but also to understand the costs and benefits for the long term.

Rational inquiry about the world deserves more credit, so that we can use it to address some of the serious challenges that lie ahead. Bruce Alberts in his lecture also advocated scientific thinking as a way of arming people against rants, simplified TV news, and overly subjective talk radio. We don’t want people to drift away from the scientific method, since that method is essential to reaching meaningful conclusions about the many complex systems that societies today must deal with—among them the financial system, the environment, risk assessment, and health care.

One of the key elements in making advances and solving problems—whether scientific or otherwise—has been and will be an awareness of scale. Categorizing what has been observed and understood by scale has taken us very far in our understanding of physics and the world—whether the units are physical scales, population groups, or time frames. Not only scientists, but political, economic, and policy leaders too need to keep such concepts in mind.

Supreme Court Justice Anthony Kennedy, in a speech to the Ninth Judicial Circuit, referred not only to the significance of scientific thinking, but also to the important contrast between “micro” and “macro” thinking—words that apply as much to the small-scale and large-scale elements of the universe as to the detailed and global ways we think about the world. As we have seen in this book, one of the factors in addressing issues—scientific as well as practical and political—is the interplay between the two scales of thought. The awareness of both is one of the factors that contributes to creative ideas.

Justice Kennedy also noted that among the elements of science that he likes are “the ridiculous solutions [that] often turn out to be the ones that are true.” And this is indeed sometimes the case. Nonetheless, good science, even when it leads to superficially far-fetched or counterintuitive conclusions, is rooted in measurements that show these conclusions to be true, or in problems that call for the apparently crazy solutions we conjecture might be real.

Many elements combine to form the foundation of good scientific thinking. In
Knocking on Heaven’s Door
, I have attempted to convey the significance of rational scientific thought and its materialist premises, as well as the ways in which scientific thinking tests ideas through experiments and discards them when they don’t measure up. Scientific thought recognizes that uncertainty isn’t failure. It properly evaluates risks and accounts for both short- and long-term influences. It allows for creative thinking in the search for solutions. These are all modes of thought that can lead to advances—both in and out of the laboratory or office. The scientific method helps us understand the edges of the universe, but it can also guide us in critical decisions for this world that we now live in. Our society needs to absorb these principles and teach them to future generations.

We shouldn’t be afraid to ask big questions or to consider grand concepts. One of my physics collaborators, Matthew Johnson, got it right when he exclaimed, “Never before has there been such an arsenal of ideas.” But we don’t yet know the answers and are waiting for experimental tests. Sometimes answers come more quickly than expected—as when the cosmic microwave background taught us about the early exponential expansion of the universe. And sometimes they take longer—as with the LHC, which still has us waiting.

We should soon know more about the makeup and forces of the universe, as well as why matter has the properties it does. We also hope to learn more about the missing stuff that we call “dark.” So, as our “prequel” ends, let’s return to the line from the Beatles song that accompanied the introduction to my earlier book,
Warped Passages
: “Got to be good-looking ’cause he’s so hard to see.” New phenomena and understanding might be challenging to find, but the wait and challenges will be worth it.

INDEX

The pagination of this electronic edition does not match the edition from which it was created. To locate a specific passage, please use your e-book reader’s search tools.

Page references in
italic
indicate illustrations

acceleration, 71, 86–87, 98–101, 103–7, 123, 131–36
accuracy
in particle physics, 208–10
use of term, 203
Adams, John C., 368
Adler, Fred, 40
Adoration of the Magi
(Giotto), 28–29,
29
aesthetic criteria
in art, 264–68
in science, 268–70
Alberts, Bruce, 413, 415
Alda, Alan, 128
ALICE (A Large Ion Collider Experiment), 164, 216
Al-Kindi, 23
Alpha Magnetic Spectrometer (AMS-02), 392
alpha particle, 97–98,
98
AMANDA (Antarctic Muon and Neutrino Detector Array), 393
American Heritage Dictionary
, 45–46
American International Group (AIG), 183–84
AMS-02
see
Alpha Magnetic Spectrometer
anarchic principle, 311
Anderson, Carl, 99
Angels and Demons
(movie), xix
angular momentum, 80–81
animal magnetism, 9–10
ANTARES, 393
anthropic principle, 339, 351, 375
antimatter, 99–100, 375–76
antimuon, 244
antineutron, 99, 392
antiparticles, 107–13, 244, 292–93,
297
, 380, 390–91
antiproton, 99–100, 108, 111, 376, 392
antiquark,
84
, 84–87,
86
antitau, 244
Apparatus with Super Conducting Toroids
see
ASCOT
Applied Minds, 300
Aprile, Elena, 387–88
ArDM (Argon Dark Matter), 384
argon, 229–30, 234, 384
Aristotle, 29, 35, 269
Arkani-Hamed, Nima, 318
Armstrong, Karen, 47
art
and beauty, 264–68
science, and religion, 40–46
ASCOT (Apparatus with Super Conducting Toroids), 219
“As Time Goes By” (song), xxiii, 421
n
astrophysics, 121–22
asymptotic states, 262–63
ATLAS (A Toroidal LHC ApparatuS), 127–28, 151–52,
214
, 214–36
detectors,
220
, 221–25,
223
electromagnetic calorimeter, 229–31,
230
endcaps,
233
, 233–34
general principles, 217–21
hadronic calorimeter, 231
and Higgs boson discovery, 293–94
magnets, 224, 225, 234–36
muon detector, 231–32
trackers, 225–29
atomic clock, 207–8
atomic physics, 15–16
atomic scale, 77–81
atom, 15, 69, 77–87,
78
, 97–98
AT&T Bell Laboratories, 357–58
Auger Cosmic Ray Observatory, 175
Augustine, 47–49
Avatar
(movie), 349
Aymar, Robert, 149
background events, 209, 241
Bacon, Francis, 23
Baldo-Ceolin, Massimilla, 27
balloon analogy, 354–55,
354
Barings Bank, 183
beam-beam collisions,
101
, 101–3
beanbags, 237–38
beauty, 261–64
in art, 264–68
in science, 268–70
vs. the sublime, 41
belief, xv, 4, 45–46, 50–51
see also
religion
Bellarmine, Robert, 33
Bell Laboratories, 357–58
Bernanke, Ben, 196–97
Berners-Lee, Tim, xxii, 239, 329
Berra, Yogi, 236
beta decay, 114, 245
Bevatron, 99
Bible, 47–49, 57, 59, 62
Big Bang, 47, 122–23, 352–59, 362–64
Biogen, 360
biology, 74–76, 198–99
Bisphenol A
see
BPA
Bjorken, James, 100
black holes, 166–77
calculations, 169–72, 193
decay, 169, 171–73, 175, 194
see also
LHC black holes
Blake, William, 402
blood circulation, 74–75
blue shift,
353
Bohr, Niels, 10, 80–81, 244–45, 273
Born, Brooksley, 196
boson,
254–55
, 304–6
see also
gauge boson; graviton; Higgs boson
bottom quark, 217, 247, 292–93,
293
bottom-up theories, 355, 363
BPA (Bisphenol A), 206–7
BP oil spill (2010), 183, 185
Brahe, Tycho, 31, 37–38,
38
, 202, 421
n
brain and consciousness, 53–54
brane,
315
, 315–16,
323
, 324–26,
325
, 337
braneworld, 316,
317
broken symmetry, 268
Brooks, David, 400
Brooks, James L., 131
Broom Bridge (Dublin), 22
Brout, Robert, 117, 423
n
Browne, Thomas, 44
Büchmann, Anna Christina, 3
Buckley, Matthew, 226–27
bulk, 324, 329
Bullet Cluster, 370–71,
371
Burj Khalifa (Dubai), 348
Burke, Bernie, 357
busbar,
158
, 158–60
Byrne, Rhonda, 10
Calandra, Alexander, 407–8
calorimeter, 225, 229–31
Calvin, John, 64
Cambridge Roundtable on Science, Art and Religion, 63–65
Cameron, James, 348
capillary system, 74–75
carbon collimator, 141–42
Casablanca
(movie), 401–2
Cassano, Joseph, 183–84
Catholic Church, 46, 47–49, 60–62
CDMS
see
Cryogenic Dark Matter Search
CDO
see
collateralized debt obligation
celestial body, 35–36,
36
Centro Culturale Altinate (Padua), 27–28, 39
CERN (European Organization for Nuclear Research), xix, 108–9, 130–31, 144–51, 189–90
funding, 130, 146–47, 149–50, 151, 190
history of, 144–48
see also
LEP; LHC
CERN Council, 148, 150
CERN Scientific Policy Committee, 148
Chamberlain, Owen, 99
Chang, David, 409
charge, 84, 108, 109, 114,
114–15
, 116,
254
, 254–55, 307
and dark matter, 383
and detectors,
220
, 223–29, 231–32, 234–35, 243–45, 249–51, 383
and electromagnetic force, 85, 108, 223–25, 243–45, 254–55, 307, 383
and leptons, 242–46,
242
,
254
and Standard Model, 242–46, 249, 251,
254
, 254–55
and strong force, 104, 223, 246, 254–55, 262, 307, 425
n

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