The End of Everything: (Astrophysically Speaking)

Page 22

by Katie Mack

Big Crunch impact on, 62–63

Big Rip and loss of, 112–13, 114 (fig.)

Copernican Principle on, 18

Cosmic Dawn and beginning of, 49

cosmic expansion and, 54, 61

cosmological constant and, 107

cosmological principle in, 17–18

dark energy and, 106, 107

distance and apparent size of, 86–87, 87 (fig.)

distance ladder measurements and, 119 (fig.)

Epoch of Reionization and, 49

gravitational lensing and, 68, 189

Hubble-Lemaître Law on speed-distance proportionality of, 58

light-year unit for observation of events and distance in, 16–17

possibilities of planets with other beings in, 50

rates of collisions between, 52–53

recession speed of, 83–84

redshift measurement process for, 55–56, 57 (fig.)

redshift measurements for distance of, 57, 58–59

seeing galaxies currently moving away from us faster than light, 87–88

shape of space and, 68

gamma rays, 55, 65

general relativity, 8, 78, 124, 155, 157, 162 cyclic universes and, 66

gravitational attraction and, 108

search for some kind of deviation in, 158–59

singularity at beginning of the Big Bang and, 33–34

General Theory of Relativity. See general relativity

gluons, 43–44

God Particle, 133–34. See also Higgs boson

Grand Unification, 37

Grand Unified Theory, 36, 160 beginning of the Big Bang and, 36–38

gravitational lensing, 68, 189

gravitational waves astronomical observation using, 157–58

effect on human body of, 158 (fig.)

first detection of, 157

inflation models for, 172

measurement of, 189–90

primordial, evidence for, 171–72

quantized gravity theory and, 160–61

gravitons, 160–61

gravity Big Crunch impact and, 63

cosmic expansion and, 61

cyclic universes and, 66

dark matter and, 67, 68

deceleration of universe and, 72, 74

effect of pressure and, 108

Einstein’s theory of, 8, 10, 32, 66, 68, 75, 77

Grand Unified Theory and, 36, 37

large extra dimensions scenario for, 163–64, 165

Newton’s studies of, 8, 9, 162

particle physics and, 160, 164

perceived weakness of, 163, 165

quantum mechanics predictions and, 160

search for some kind of deviation in, 158–60

shape of space and, 68

singularity at beginning of the Big Bang and, 32, 34

spacetime and, 164

Theory of Everything on, 36–37, 159

Gregory, Ruth, 150

GUT (Grand Unified Theory) era, 36–38

Hawking, Stephen, 11, 89, 92–93, 94, 95, 151, 152

Heat Death, 185, 207 black holes and, 95

dark energy and, 114

entropy and, 173

meaning of term, 90

state of universe after, 99–100

Heisenberg’s Uncertainty Principle, 41

helium Big Bang Nucleosynthesis and, 45, 46

Sun’s production of, 120

Higgs boson “God Particle” popular name for, 133–34

Higgs field differentiated from, 134

LHC discovery of, 130, 133

measurement of mass of, 141

Standard Model of particle physics and, 130, 134, 141, 181

Higgs field, 196–97 early universe and, 134, 136

electroweak symmetry and, 140, 142

false vacuum and, 143, 143 (fig.)

Higgs boson differentiated from, 134

inflation and, 171

potential of, 142, 143 (fig.), 147, 197

potential barrier and, 149

quantum tunneling and, 149

vacuum decay and, 144–45, 147–48

Higgs potential, 142, 143 (fig.), 147, 197

Higgs vacuum, 140, 141, 142

high-energy event, and vacuum decay, 147–48

Hložek, Renée, 188, 209, 210

Hot Big Bang black hole formation in, 151

cosmic microwave background and, 47

description and span of time of, 22

inflation field and, 167

LHC re-creation of conditions for, 130

Hubble, Edwin, 57–58, 79, 118n

Hubble Constant, 189 cosmic expansion and, 58, 125

debates about calculation methods for, 126–28, 189

Hubble-Lemaître Law and, 58

Hubble-Lemaître Law, 58, 59, 62, 69

Hubble radius, 83–86, 85 (fig.), 88

hydrogen Big Bang Nucleosynthesis and, 45, 46

decay of, 89–90

red giant phase of the Sun and burning off of, 121

Sun’s fusion of, 120

hydrostatic equilibrium, 120

Ijjas, Anna, 173

infernoverse, 23

inflaton field, 167, 171

James Webb Space Telescope (JWST), 187

Johnson, Matthew, 99

Johnson, Clifford V., 184, 190, 199–200, 202

Kibble, Tom, 26n

Lao-Tzu, 4

large extra dimensions scenario, and gravity, 163–64, 165

Large Hadron Collider (LHC), 129–31, 141, 147, 161, 182, 183 description of, 129–30

Higgs boson discovery by, 130, 133

public concerns about, 129, 130–31, 132

quark-gluon plasma re-creation in, 44

safety of, 129

vacuum decay and, 152

large-scale curvature of universe, 75

Large Synoptic Survey Telescope (LSST), 186

Laser Interferometry Gravitational-Wave Observatory (LIGO), 157, 190

Law of Universal Gravitation, 8

Leavitt, Henrietta Swan, 117–18

Lemaître, Georges, 58

LHC. See Large Hadron Collider

light dominant energy condition and, 111

measuring shifts in. See blueshift measurements; redshift measurements

movement through spacetime by, 20 (fig.)

particle horizon and speed of, 82

recession speed of galaxies and speed of, 83–84

shape of space and response of, 68

spectrum pattern characteristics of, 27, 55–57

thermal radiation and, 27–28

travel times for, 17 (fig.)

light speed delay description of, 16–17

“now” concept when viewing events and, 18–19

spacetime property and, 18–19

light-year unit, 16–17

LIGO. See Laser Interferometry Gravitational-Wave Observatory

Local Group of galaxies 52–53, 88

lookback time, 26

loop quantum gravity, 160

LSST. See Large Synoptic Survey Telescope

Many Worlds interpretation of quantum mechanics, 169n

matter bending of space by, 68, 108

Big Bang Nucleosynthesis and, 45

dark energy and, 107–8

density over time of, 97 (fig.)

imbalance between antimatter and, 162

quark era and distinction between antimatter and, 44

maximum entropy universe, 97

McNees, Robert, 153n

Mendeleev, Dmitri, 137

Mercury gravity theory and observations of, 8, 162

red giant phase of the Sun and destruction of, 1, 121

Milky Way, 8, 24 Andromeda Galaxy’s future collision with, 51–52, 62–63, 88

distance ladder measurements and, 119 (fig.)

smaller nearby galaxies consumed by, 52

“Mixed Signals” (White and Wharton), 166

Moon B
ig Rip and, 113

cosmic ray collisions on, 132–33

distance and apparent size of, 86

Moss, Ian, 150

neutron, decay of, 89

neutron stars, 125n, 158, 159, 166, 171

Newton, Sir Isaac, 8, 9

Nietzsche, Friedrich, 3, 100–101

observable universe description of, 21, 26

cartoon map of, 26 (fig.)

cosmic expansion and, 54

particle horizon in, 82–84

seeing “edge” of, 83

uniformity problem of, 39–40

open universe, 75, 76 (fig.)

overview effect, 7

parallax, in distance measurement, 117, 118, 119 (fig.)

Parkes radio telescope, 24

particle colliders, 48. See also specific colliders early universe research using, 134–35

gravity theory experiments and, 161

particle physics research using, 135–36

public concerns about, 129, 130–31, 132, 133

quark-gluon plasma re-creation in, 44

safety of, 129

vacuum decay and, 152

particle horizon, 82–84

particle physics, 11 Grand Unification in, 37

gravity and, 160, 164

particle collider experiments for insights into, 135–36

symmetry in, 138

Pauli exclusion principle, 122

Peebles, Jim, 23, 24–25, 27n

Peiris, Hiranya, 179, 180, 187, 202, 206

Penrose, Roger, 175, 208

Penzias, Arno, 23–24, 25–27

periodic table of the elements, symmetry in, 137

phantom dark energy, 128 Big Rip and, 115

Caldwell’s calculation of, 110–12, 111 (fig.), 115

phenomenology, 11–12

physics areas studied by cosmologists in, 10

Grand Unified Theory in, 36–37

gravity theory and, 161

Higgs field and, 134

models in, 22n

new perspectives on the universe’s end and findings in, 7–8

particle collider experiments for insights into, 135, 141

singularity at beginning of the Big Bang and, 33–34

symmetry in, 136–39

Planck, Max, 35

Planck satellite, 115

Planck Time, 35, 36, 37

planets Big Crunch and birth of, 63

Big Rip and orbits of, 113

red giant phase of the Sun and destruction of, 121

Poincaré recurrences, 99, 103, 201

Pontzen, Andrew, 180–81, 206–7

potential Higgs field and, 142, 143 (fig.)

vacuum decay and, 141–42

primordial gravitational waves, 171–72

Pritchard, Jonathan, 208–9

protons, decay of, 89

quantum field theory, 11

quantum gravity theories, 34, 160, 199

quantum mechanics, 148, 149, 155 cyclic universes and, 66

density fluctuations in cosmic inflation and, 43

gravity and, 160

Many Worlds interpretation of, 169n

singularity at beginning of the Big Bang and, 33–34

quantum tunneling, 148–50

quark-gluon plasma, 43, 44

quarks early universe and, 43–44

particle colliders and, 130–31

quantum gravity theory on, 160

Standard Model of particle physics on, 181

types of, 131n

quintessence hypothesis, for dark energy, 80–81

radiation, density over time of, 97 (fig.)

radio telescopes, 20, 24, 25, 132–33

recollapse of universe, 76, 81, 177 critical density between eternal expansion and, 68–70

final stages of the Big Bang and, 64–65

theoretical possibility of, 70n

red giant phase of the Sun, 1, 52, 73, 121

redshift measurements Big Crunch and, 62

cosmic expansion and, 55–57, 57 (fig.), 73, 74

distant galaxy movement and, 57, 58–59

earlier epochs of the universe and, 59

Hubble radius and, 83

importance of distance and age relationship with, 59–60

Rees, Martin, 177, 205–6

reheating process, in cosmic inflation, 42

Relativistic Heavy Ion Collider (RHIC) public concerns about, 131, 132, 133

quark-gluon plasma re-creation in, 44

vacuum decay possibility and, 133

religion cyclic view of the universe and, 3

discomfort with mixing of science and, 134

vision of End Times in, 2–3, 4

RHIC. See Relativistic Heavy Ion Collider

rotational symmetry, 138–39

Rubin, Vera, 67–68

Sagan, Carl, 46

scalar field, in ekpyrotic models, 171, 174

Schwarzschild radius, 94n

Second Law of Thermodynamics, 91, 93, 97, 98, 104

shape of space geometry of universe types and, 75, 76 (fig.)

gravitational waves and, 158

matter and bending of, 68, 108

response of light related to, 68

singularity Big Bang beginning with, 32–35, 40n

black hole and, 93, 94n

bounce model and, 170

Conformal Cyclic Cosmology and, 176

cyclic universes and, 66, 175

ekpyrotic mode and, 174

Solar System Andromeda Galaxy–Milky Way collision in, 51–52, 62

definitions and measurements of distance in, 116–17

distance ladder in, 117, 119 (fig.)

vacuum decay in, 150

sound, and Doppler effect, 54, 55 (fig.)

spacetime dark energy as property of, 81

description of, 18–19

gravity in, 164

light moving through, 20 (fig.)

spectrum pattern characteristics, in star identification, 27, 55–57

spontaneous symmetry breaking, 134

standard candle method of distance measurement, 73–74, 117–18, 119

Standard Model of particle physics, 181–83, 190, 191 Higgs boson and, 130, 134, 141, 181

physical phenomena not explained in, 161–62

vacuum decay and, 155

stars and star systems. See also white dwarf stars Andromeda Galaxy–Milky Way collision and formation of, 51–52

astronomical all-sky surveys of, 113

Big Crunch impact on, 62–63, 65

Big Rip and, 113

Cepheid variable stars, 118–19, 119 (fig.), 127

Chandrasekhar Limit and, 124–25

Cosmic Dawn and beginning of, 49

cosmic expansion and, 61

distance ladder measurements and, 119 (fig.)

electron degeneracy pressure and collapse of, 122–23, 124

Epoch of Reionization and, 49

gravitational wave astronomy on, 158

hydrostatic equilibrium in, 120

light spectrum pattern characteristics of, 27, 55–57

possibilities of planets with other beings in, 50

redshift measurements of, 55–56

shape of space and, 68

supernovae explosions and distance measurements in, 73–74, 75, 79, 81, 84, 118–19

Star Trek: The Next Generation (TV series), 18n, 163

statistical mechanics, 98–99

Steinhardt, Paul, 166, 173

string theory, 160 research conducted in, 10n

as ultimate Theory of Everything, 36–37

Sun Big Rip and, 113

distance and apparent size of, 86

electron degeneracy pressure and collapse of, 122–23

gravitational pull of, 159

hydrogen-helium balance in, 120–21

red giant phase of, 1, 52, 73, 121

supernovae explosions distance measurements in universe using, 73–74, 75, 79, 81, 84, 1
18–19

electron degeneracy pressure and, 122–23

Supernova 1006, 123n

supersymmetry model (SUSY), 182

surface of last scattering, 47

symmetry breaking event in, 138, 139. See also electroweak symmetry breaking equations describing interactions in, 139

examples of, 138–39

mathematical expression of, 138

patterns in, 137, 138

physics and, 136–38

Theory of Everything (TOE), 37, 59n, 159, 160, 161, 162

thermal radiation, 27–28

thermodynamic equilibrium, 39

3-dimensional branes, in ekpyrotic models, 163, 164, 166, 167–69

time travel, 15

topological defect, 139n

translational symmetry, 139

Turner, Ken, 25

Turok, Neil, 166, 175, 201, 209

Type Ia supernovae explosions characteristic brightness and spectrum of light in, 73

dark energy and, 125

description of, 119–20

distance measurement using, 73–74, 75, 79, 81, 84, 118–19, 125

measuring speed of receding by, 74

standard candle method of distance measurement for, 73–74, 117–18, 119

universe. See also observable universe beginning of, 2

belief in steady state of, 4–5

Big Bang afterglow in, 63–64

bounce model of, 169–70, 173–74

bubble of true vacuum in, 144–46, 146 (fig.)

closed, 75, 76 (fig.)

Copernican Principle on, 18

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