Computing with Quantum Cats (34 page)
Read Computing with Quantum Cats Online
Authors: John Gribbin
Every effort has been made to trace the copyright holders of photos reproduced in the book. Copyright holders not credited are invited to get in touch with the publishers.
PHOTOS IN THE TEXT
7: the Granger Collection, New York; 9: King's College Library, Cambridge/AMT/K/7/12; 53: Time & Life Pictures/Getty Images; 97: provided with kind permission of Dr. Tonomura; 99: CERN/Science Photo Library; 135: © 1982 CERN; 181: Winfried Hensinger, University of Sussex; 183: Lulie Tanett; 226: Getty Images
PHOTO INSERT
Credits are listed clockwise on each spread, starting from the top left.
Alan Turing on Waterloo Station, c. 1926 (detail):
King's College Library, Cambridge/AMT/K/7/3;
Letter from Alan Turing, April 1, 1923:
King's College Library, Cambridge/AMT/K/1/1, © P. N. Furank;
Alan Turing finishing a race:
National Physical Laboratory © Crown copyright/Science Photo Library
Hut 3, Bletchley Park:
© Edifice/Corbis;
Colossus, 1943:
SSPL via Getty Images;
codebreakers, Bletchley Park, c. 1942:
SSPL via Getty Images
ENIAC:
Associated Press;
advertisement for the Bendix G-15 computer:
courtesy of the Computer History Museum;
J. Robert Oppenheimer and John von Neumann:
Emilio Segre Visual Archives/American Institute of Physics/Science Photo Library
Fred Hoyle:
BBC Photo Library;
bio-wall:
Philippe Plailly/Science Photo Library
Fifth Solvay Physics Conference, Brussels, 1927:
SSPL via Getty Images;
quantum cryptography equipment:
Volker Steger/Science Photo Library;
MRI scanner, 2010: Boston Globe
via Getty Images;
double-slit refraction:
GIPhotostock/Science Photo Library
John Stewart Bell, 1989:
Corbin O'Grady Studio/Science Photo Library;
David Bohm, 1971:
Getty Images;
Alain Aspect:
Ãsterreichische Zentralbibliothek für Physik (Austrian Central Library for Physics);
Hans Georg Dehmelt:
Emilio Segre Visual Archives/American Institute of Physics/Science Photo Library
Brian Josephson, November 23, 1973:
PA/PA Archive/Press Association Images;
David Wineland adjusting an ultraviolet laser, 2003:
© Geoffrey Wheeler/National Institute of Standards and Technology;
Nobel laureates David J. Wineland and Serge Haroche, December 2012:
AFP/Getty Images;
Gary Kasparov vs. a computer, May 3, 1997:
AFP/Getty Images
Ion trap laboratory and chip:
Winfried Hensinger, University of Sussex
Aberdeen Proving Ground,
68
,
74
,
76
,
79
Abramson, Albert,
72
ACE (Automatic Computing Engine),
47
â
8
,
50
Adleman, Len,
204
Aiken, Howard,
69
American Physical Society,
165
,
166
American Telephone and Telegraph Company (AT&T),
33
artificial intelligence,
82
Atkins, James,
16
Atomic Energy Research Establishment (AERE),
149
,
152
,
153
â
4
atoms: cavity quantum electrodynamics,
227
,
260
â
2
; donor,
246
,
247
; Manhattan Project,
63
; manipulation of,
1
,
217
,
224
â
5
,
243
; nanotechnology,
94
; NMR,
250
â
1
; number in visible Universe,
208
; quantum computing,
134
; quantum dots,
242
â
3
automata,
83
; cellular model,
85
â
6
; self-reproducing,
84
â
6
Bates, Audrey,
49
Bell, John Stewart: Aspect's visit,
171
; career,
152
,
153
â
5
; childhood,
149
â
50
; death,
174
; education,
150
â
2
; on experiments,
169
â
70
; on FAPP,
106
; Feynman's work,
133
; on “hidden variables” theory,
137
; on “many-universes interpretation,”
174
â
5
,
185
â
6
; marriage,
152
â
3
; Nobel nomination,
174
; refutation of von Neumann's argument,
156
â
7
; on wave function,
184
; writings: “On the Einstein-Podolsky-Rosen Paradox,”
158
â
62
,
163
,
171
; “On the Problem of Hidden Variables in Quantum Mechanics,”
156
â
7
,
165
;
see also
Bell's inequality, Bell's theorem
Bell Laboratories,
33
,
69
,
125
,
233
Bell-state measurement,
257
Bell's inequality,
159
; Aspect's work,
172
; Chinese experiments,
258
; Clauser's work,
166
,
167
; Feynman's work,
133
; Fry's work,
168
; Holt's work,
165
,
167
â
8
; Horne's work,
164
; teleportation,
256
Bell's theorem,
159
,
174
,
189
; Aspect's work,
171
â
3
; Clauser and Freedman's work,
166
â
7
,
171
; Fry's work,
168
; Holt's work,
167
â
8
; Josephson's work,
231
; Shimony and Horne's work,
164
; testing,
161
,
163
,
164
,
166
â
70
Bendix Corporation,
48
Berkeley, University of California at,
145
â
6
,
164
,
166
,
204
,
253
Billings, John,
66
Birkbeck College, London,
51
,
149
bits (binary digits),
2
,
134
,
176
,
242
Bletchley Park,
29
â
35
,
37
â
9
,
41
â
3
,
44
,
204
Bliss, Gilbert,
74
Bohm, David: career,
145
â
6
,
148
â
9
; on entanglement,
163
; on EPR puzzle,
146
â
8
; on hidden variables,
147
â
9
,
156
; influence,
154
,
157
,
164
,
165
,
170
; writings:
Quantum Theory
,
146
â
8
Bohr, Niels: Copenhagen institute,
59
,
105
; Copenhagen Interpretation,
105
,
138
,
142
,
145
,
146
Boole, George,
123
Boolean algebra,
123
Boston University,
163
Boulder, Colorado,
216
,
219
,
220
,
253
BQP (bounded-error quantum polynomial) problems,
213
Bristol, University of,
264
â
5
British Tabulating Machine Company,
30
â
1
Bronowski, Jacob,
89
Brooker, Tony,
50
Brown, Julian,
207
Budapest, University of,
55
â
6
Burks, Arthur,
79
Cambridge University,
16
â
21
,
77
,
231
cavity quantum electrodynamics (CQED),
227
,
260
central processing unit (CPU),
79
Center for Quantum Computation, Oxford,
190
Center for Quantum Photonics, Bristol,
264
â
5
charge qubit,
243
Children's Hour
(BBC),
50
CHSH paper,
166
Chuang, Isaac,
223
Church-Turing principle,
196
CIP Technologies,
264
ciphers and codes: Enigma,
25
â
30
; one time pad,
203
â
4
; quantum computers,
1
,
203
â
10
,
213
,
266
; Shor's algorithm,
206
â
9
,
210
,
212
,
213
; speech encipherment,
33
,
34
; Tunny,
35
â
40
,
44
; Turing's early work,
23
â
4
Cirac, Juan Ignacio,
216
â
17
,
220
Clark, Terry,
235
Clarke, Joan,
33
Clauser, John,
165
â
9
,
171
,
172
,
173
,
174
CNOT (Controlled NOT) gate,
215
â
17
,
220
,
225
â
6
,
228
,
240
,
262
â
4
coarse-grained universes,
201
â
2
codes,
see
ciphers and codes
Cohen, Morrel,
233
Colossus: achievements,
41
,
42
â
3
; destruction of machines,
43
â
4
; development,
40
â
1
,
82
,
93
,
203
; first electronic computer,
42
,
77
; Flowers' work,
40
â
2
,
49
; production,
41
â
2
; programming,
42
; replica,
44
; size,
253
; Turing's work,
33
,
40
â
3
; valves,
40
â
1
,
263
Communications Supplementary Services (Washington) (CSSW),
33
computation: act of,
125
â
7
; reversible,
126
,
127
â
9
computers: conventional (classical),
2
â
3
,
132
,
203
,
210
,
213
â
15
,
224
; fallibility of components,
82
â
4
; first complete and fully operational electronic digital stored-program computer,
77
; first electronic computer,
42
,
70
,
77
; first programmable electromechanical digital computer,
70
; first stored-program computer,
49
,
70
,
76
â
7
; languages,
50
; parallel architecture,
80
; quantum,
see
quantum computers; reversible,
128
; serial architecture,
79
â
80
; size,
253
; Turing machines,
20
â
1
,
43
,
81
â
2
,
91
,
131
,
196
â
7
; Turing's early work,
18
â
20
,
28
; universal,
20
,
46
,
86
Computron,
73
Copenhagen Interpretation,
105
â
7
; Bell's work,
158
â
9
,
184
; Bohm's work,
146
,
147
; comparison with hidden variables theory,
139
; Einstein's view,
142
,
144
; Everett's work,
184
,
186
; influence,
145
,
149
; Schrödinger's view,
120
â
2
,
138
CPT theorem,
153
cryptography: future of quantum computing,
265
; “one time pad,”
203
â
4
; public key,
204
â
5
; RSA algorithm,
204
â
6
; Shannon's work,
125
; Shor's algorithm,
206
â
9
,
210
,
212
,
213
; Turing's work,
23
â
4
,
33
,
38
â
9
Dalibard, Jean,
171
de Broglie, Louis: career,
135
â
6
; Clauser's work,
165
; hidden variables theory,
137
â
8
,
144
â
5
; 90th birthday symposium,
154
; on particles and waves,
136
; pilot wave idea,
137
,
138
,
142
,
148
,
149
