Orders of magnitude (time)

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An order of magnitude of time is usually a decimal prefix or decimal order-of-magnitude quantity together with a base unit of time, like a microsecond or a million years. In some cases, the order of magnitude may be implied (usually 1), like a "second" or "year". In other cases, the quantity name implies the base unit, like "century". In most cases, the base unit is seconds or years.

Contents

Prefixes are not usually used with a base unit of years. Therefore, it is said "a million years" instead of "a megayear". Clock time and calendar time have duodecimal or sexagesimal orders of magnitude rather than decimal, e.g., a year is 12 months, and a minute is 60 seconds.

The smallest meaningful increment of time is the Planck time―the time light takes to traverse the Planck distance, many decimal orders of magnitude smaller than a second. [1]

The largest realized amount of time, based on known scientific data, is the age of the universe, about 13.8 billion years—the time since the Big Bang as measured in the cosmic microwave background rest frame. [2] Those amounts of time together span 60 decimal orders of magnitude. Metric prefixes are defined spanning 10−30 to 1030, 60 decimal orders of magnitude which may be used in conjunction with the metric base unit of second.

Metric units of time larger than the second are most commonly seen only in a few scientific contexts such as observational astronomy and materials science, although this depends on the author. For everyday use and most other scientific contexts, the common units of minutes, hours (3,600 s or 3.6 ks), days (86,400 s), weeks, months, and years (of which there are a number of variations) are commonly used. Weeks, months, and years are significantly variable units whose lengths depend on the choice of calendar and are often not regular even with a calendar, e.g., leap years versus regular years in the Gregorian calendar. This makes them problematic for use against a linear and regular time scale such as that defined by the SI, since it is not clear which version is being used.

Because of this, the table below does not include weeks, months, and years. Instead, the table uses the annum or astronomical Julian year (365.25 days of 86,400 seconds), denoted with the symbol a. Its definition is based on the average length of a year according to the Julian calendar, which has one leap year every four years. According to the geological science convention, this is used to form larger units of time by the application of SI prefixes to it; at least up to giga-annum or Ga, equal to 1,000,000,000 a (short scale: one billion years, long scale: one milliard years).

Less than one second

Units of measure less than a second
Multiple
of a
second
UnitSymbolDefinitionComparative examples & common units
10−44 Planck time tPPresumed to be the shortest theoretically measurable time interval
(but not necessarily the shortest increment of time—see quantum gravity)
10−14 qs: The length of one Planck time (tP = 5.39×10−44 s) [3] is the briefest physically meaningful span of time. It is the unit of time in the natural units system known as Planck units.
10−30quectosecondqsQuectosecond, ( quecto- + second), is one nonillionth of a second
10−27rontosecondrsRontosecond, ( ronto- + second), is one octillionth of a second300 rs: The mean lifetime of W and Z bosons
10−24yoctosecondys [4] Yoctosecond, ( yocto- + second), is one septillionth of a second23 ys: The lower estimated bound on the half-life of isotope 7 of hydrogen (Hydrogen-7)
143 ys: The half-life of the Nitrogen-10 isotope of Nitrogen
156 ys: The mean lifetime of a Higgs Boson
10−21zeptosecondzsZeptosecond, ( zepto- + second), is one sextillionth of one second1.3 zs: Smallest experimentally controlled time delay in a photon field. [5]
2 zs: The representative cycle time of gamma ray radiation released in the decay of a radioactive atomic nucleus (here as 2 MeV per emitted photon)
4 zs: The cycle time of the zitterbewegung of an electron ()
247 zs: The experimentally-measured travel time of a photon across a hydrogen molecule, "for the average bond length of molecular hydrogen" [6]
10−18 attosecond asOne quintillionth of one second12 as: The best timing control of laser pulses. [7]
43 as: The shortest X-ray laser pulse [8]
53 as: The shortest electron laser pulse [9] [10]
10−15 femtosecond fsOne quadrillionth of one second1 fs: The cycle time for ultraviolet light with a wavelength of 300 nanometres; The time it takes light to travel a distance of 0.3 micrometres (μm).
7.58fs: The period of vibration of a hydrogen molecule.
140 fs: The time needed for electrons to have localized onto individual bromine atoms 6 Ångstrom apart after laser dissociation of Br2. [11]
290 fs: The lifetime of a tauon
10−12 picosecond psOne trillionth of one second1 ps: The mean lifetime of a bottom quark; the time needed for light to travel 0.3 millimetres (mm)
1 ps: The typical lifetime of a transition state one machine cycle by an IBM silicon-germanium transistor
109 ps: The period of the photon corresponding to the hyperfine transition of the ground state of cesium-133, and one 9,192,631,770th of one second by definition
114.6 ps: The time for the fastest overclocked processor as of 2014 to execute one machine cycle. [12]
696 ps: How much more a second lasts far away from Earth's gravity due to the effects of General Relativity
10−9 nanosecond nsOne billionth of one second1 ns: The time needed to execute one machine cycle by a 1 GHz microprocessor
1 ns: The time light takes to travel 30 cm (11.811 in)
10−6 microsecond μsOne millionth of one second1 μs: The time needed to execute one machine cycle by an Intel 80186 microprocessor
2.2 μs: The lifetime of a muon
4–16 μs: The time needed to execute one machine cycle by a 1960s minicomputer
10−3 millisecond msOne thousandth of one second1 ms: The time for a neuron in the human brain to fire one impulse and return to rest [13]
4–8 ms: The typical seek time for a computer hard disk
10−2centisecondcsOne hundredth of one second1.6667 cs: The period of a frame at a frame rate of 60 Hz.
2 cs: The cycle time for European 50 Hz AC electricity

10–20 cs (=0.1–0.2 s): The human reflex response to visual stimuli

10−1deciseconddsOne tenth of a second1–4 ds (=0.1–0.4 s): The length of a single blink of an eye [14]

More than one second

In this table, large intervals of time surpassing one second are catalogued in order of the SI multiples of the second as well as their equivalent in common time units of minutes, hours, days, and Julian years.

Units of measure greater than one second
Multiple of a secondUnitSymbolCommon unitsComparative examples and common units
101decaseconddassingle seconds

(1 das = 10 s)

6 das: One minute (min), the time it takes a second hand to cycle around a clock face
102hectosecondhsminutes
(1 hs = 1 min 40 s = 100 s)
2 hs (3 min 20 s): The average length of the most popular YouTube videos as of January 2017 [15]
5.55 hs (9 min 12 s): The longest videos in the above study

7.1 hs (11 m 50 s): The time for a human walking at average speed of 1.4 m/s to walk 1 kilometre

103kilosecondksminutes, hours, days

(1 ks = 16 min 40 s = 1,000 s)

1 ks: The record confinement time for antimatter, specifically antihydrogen, in electrically neutral state as of 2011; [16] 1.477 ks: The longest period in which a person has not taken a breath.

1.8 ks: The time slot for the typical situation comedy on television with advertisements included
2.28 ks: The duration of the Anglo-Zanzibar War, the shortest war in recorded history.
3.6 ks: The length of one hour (h), the time for the minute hand of a clock to cycle once around the face, approximately 1/24 of one mean solar day
7.2 ks (2 h): The typical length of feature films

35.73 ks: the rotational period of planet Jupiter, fastest planet to rotate

38.0196 ks: rotational period of Saturn, second shortest rotational period

57.996 ks: one day on planet Neptune.

62.064 ks: one day on Uranus.
86.399 ks (23 h 59 min 59 s): The length of one day with a removed leap second on UTC time scale. Such has not yet occurred.
86.4 ks (24 h): The length of one day of Earth by standard. More exactly, the mean solar day is 86.400 002 ks due to tidal braking, and increasing at the rate of approximately 2 ms/century; to correct for this time standards like UTC use leap seconds with the interval described as "a day" on them being most often 86.4 ks exactly by definition but occasionally one second more or less so that every day contains a whole number of seconds while preserving alignment with astronomical time. The hour hand of an analogue clock will typically cycle twice around the dial in this period as most analogue clocks are 12-hour, less common are analogue 24-hour clocks in which it cycles around once.
86.401 ks (24 h 0 min 1 s): One day with an added leap second on UTC time scale. While this is strictly 24 hours and 1 second in conventional units, a digital clock of suitable capability level will most often display the leap second as 23:59:60 and not 24:00:00 before rolling over to 00:00:00 the next day, as though the last "minute" of the day were crammed with 61 seconds and not 60, and similarly the last "hour" 3601 s instead of 3600.
88.775 ks (24 h 39 min 35 s): One sol of Mars
604.8 ks (7 d): One week of the Gregorian calendar

106megasecondMsweeks to years

(1 Ms = 11 d 13 h 46 min 40 s = 1,000,000 s)

1.6416 Ms (19 d): The length of a month of the Baha'i calendar

2.36 Ms (27.32 d): The length of the true month, the orbital period of the Moon
2.4192 Ms (28 d): The length of February, the shortest month of the Gregorian calendar, in common years
2.5056 Ms (29 d): The length of February in leap years
2.592 Ms (30 d): The length of April, June, September, and November in the Gregorian calendar; common interval used in legal agreements and contracts as a proxy for a month
2.6784 Ms (31 d): The length of the longest months of the Gregorian calendar
23 Ms (270 d): The approximate length of typical human gestational period
31.5576 Ms (365.25 d): The length of the Julian year, also called the annum , symbol a.

5.06703168 Ms: The rotational period of Mercury.

7.600544064 Ms: One year on Mercury.

19.41414912 Ms: One year on Venus.

20.9967552 Ms: The rotational period of Venus.
31.55815 Ms (365 d 6 h 9 min 10 s): The length of the true year, the orbital period of the Earth
126.2326 Ms (1461 d 0 h 34 min 40 s): The elected term of the President of the United States or one Olympiad

109gigasecondGsdecades, centuries, millennia

(1 Gs = over 31 years and 287 days = 1,000,000,000 s)

1.5 Gs: Unix time as of Jul 14 02:40:00 UTC 2017. Unix time being the number of seconds since 1970-01-01T00:00:00Z ignoring leap seconds.

2.5 Gs: (79 a): The typical human life expectancy in the developed world
3.16 Gs: (100 a): One century
31.6 Gs: (1000 a, 1 ka): One millennium, also called a kilo-annum (ka)
63.8 Gs: The approximate time since the beginning of the Anno Domini era as of 2019 – 2,019 years, and traditionally the time since the birth of Jesus Christ
194.67 Gs: The approximate lifespan of time capsule Crypt of Civilization, 28 May 1940 – 28 May 8113
363 Gs: (11.5 ka): The time since the beginning of the Holocene epoch
814 Gs: (25.8 ka): The approximate time for the cycle of precession of the Earth's axis

1012terasecondTsmillennia to geological epochs

(1 Ts = over 31,600 years = 1,000,000,000,000 s)

3.1 Ts (100 ka): approximate length of a glacial period of the current Quaternary glaciation epoch

31.6 Ts (1000 ka, 1 Ma): One mega-annum (Ma), or one million years
79 Ts (2.5 Ma): The approximate time since earliest hominids of genus Australopithecus
130 Ts (4 Ma): The typical lifetime of a biological species on Earth
137 Ts (4.32 Ma): The length of the mythic unit of mahayuga , the Great Age, in Hindu mythology.

1015petasecondPsgeological eras, history of Earth and the Universe 2 Ps: The approximate time since the Cretaceous-Paleogene extinction event, believed to be caused by the impact of a large asteroid into Chicxulub in modern-day Mexico. This extinction was one of the largest in Earth's history and marked the demise of most dinosaurs, with the only known exception being the ancestors of today's birds.

7.9 Ps (250 Ma): The approximate time since the Permian-Triassic extinction event, the actually largest known mass extinction in Earth history which wiped out 95% of all extant species and believed to have been caused by the consequences of massive long-term volcanic eruptions in the area of the Siberian Traps. Also, the approximate time to the supercontinent of Pangaea. Also, the length of one galactic year or cosmic year, the time required for the Sun to complete one orbit around the Milky Way Galaxy.
16 Ps (510 Ma): The approximate time since the Cambrian explosion, a massive evolutionary diversification of life which led to the appearance of most existing multicellular organisms and the replacement of the previous Ediacaran biota.
22 Ps (704 Ma): The approximate half-life of the uranium isotope 235U.
31.6 Ps (1000 Ma, 1 Ga): One giga-annum (Ga), one billion years, the largest fixed time unit used in the standard geological time scale, approximately the order of magnitude of an eon, the largest division of geological time.
+1 Ga: The estimated remaining habitable lifetime of Earth, according to some models. At this point in time the stellar evolution of the Sun will have increased its luminosity to the point that enough energy will be reaching the Earth to cause the evaporation of the oceans and their loss into space (due to the UV flux from the Sun at the top of the atmosphere dissociating the molecules), making it impossible for any life to continue.
136 Ps (4.32 Ga): The length of the legendary unit Kalpa in Hindu mythology, or one day (but not including the following night) of the life of Brahma.
143 Ps (4.5 Ga): The age of the Earth by our best estimates. Also the approximate half-life of the uranium isotope 238U.
315 Ps (10 Ga): The approximate lifetime of a main-sequence star similar to the Sun.
434.8 Ps (13.787 Ga): The approximate age of the Universe

1018 exasecond Esfuture cosmological timeAll times of this length and beyond are currently theoretical as they surpass the elapsed lifetime of the known universe.

1.08 Es (+34 Ga): Time to the Big Rip according to some models, but this is not favored by existing data. This is one possible scenario for the ultimate fate of the Universe. Under this scenario, dark energy increases in strength and power in a feedback loop that eventually results in the tearing apart of all matter down to subatomic scale due to the rapidly increasing negative pressure thereupon
300 – 600 Es (10 – 20 Ta): The estimated lifetime of low-mass stars (red dwarfs)

1021 zettasecond Zs3 Zs (+100 Ta): The remaining time until the end of Stelliferous Era of the universe, under the heat death scenario for the ultimate fate of the Universe, which is the most commonly-accepted model in the current scientific community. This is marked by the cooling-off of the last low-mass dwarf star to a black dwarf. After this time has elapsed, the Degenerate Era begins.

9.85 Zs (311 Ta): The entire lifetime of Brahma in Hindu mythology.

1024 yottasecond Ys600 Ys (2×1019 a): The radioactive half-life of bismuth-209 by alpha decay, one of the slowest-observed radioactive decay processes.
1027 ronnasecond Rs3.16 Rs (1×1020 a): The estimated time until all stars are ejected from their galaxies or consumed by black holes.

32 Rs (1×1021 a): Highest estimate of the time until all stars are ejected from galaxies or consumed by black holes.

1030and onwardquettasecond and beyondQs and on69 Qs (2.2×1024 a): The radioactive half-life of tellurium-128, the longest known half-life of any elemental isotope.

1,340,009 Qs (4.134105×1028 years): The time period equivalent to the value of 13.13.13.13.13.13.13.13.13.13.13.13.13.13.13.13.13.13.13.13.0.0.0.0 in the Mesoamerican Long Count, a date discovered on a stele at the Coba Maya site, believed by archaeologist Linda Schele to be the absolute value for the length of one cycle of the universe [17] [18]
2.6×1011 Qs (8.2×1033 years): The smallest possible value for proton half-life consistent with experiment [19]

1023 Qs (3.2×1045 years): The largest possible value for the proton half-life, assuming that the Big Bang was inflationary and that the same process that made baryons predominate over antibaryons in the early Universe also makes protons decay [20]
6×1043 Qs (2×1066 years): The approximate lifespan of a black hole with the mass of the Sun [21]
4×1063 Qs (1.3×1086 years): The approximate lifespan of Sagittarius A*, if uncharged and non-rotating [21]
5.4×1083 Qs (1.7×10106 years): The approximate lifespan of a supermassive black hole with a mass of 20 trillion solar masses [21]
Qs: The scale of an estimated Poincaré recurrence time for the quantum state of a hypothetical box containing an isolated black hole of stellar mass [22] This time assumes a statistical model subject to Poincaré recurrence. A much simplified way of thinking about this time is that in a model in which history repeats itself arbitrarily many times due to properties of statistical mechanics, this is the time scale when it will first be somewhat similar (for a reasonable choice of "similar") to its current state again.
Qs: The scale of an estimated Poincaré recurrence time for the quantum state of a hypothetical box containing a black hole with the mass of the observable Universe. [22]
Qs ( years): The scale of an estimated Poincaré recurrence time for the quantum state of a hypothetical box containing a black hole with the estimated mass of the entire Universe, observable or not, assuming Linde's Chaotic Inflationary model with an inflaton whose mass is 10−6 Planck masses. [22]

Other
MultiplesUnitSymbol
6×101 seconds1 minutemin
6×101 minutes1 hourh (hr)
2.4×101 hours1 dayd

See also

Related Research Articles

<span class="mw-page-title-main">Physical cosmology</span> Branch of cosmology which studies mathematical models of the universe

Physical cosmology is a branch of cosmology concerned with the study of cosmological models. A cosmological model, or simply cosmology, provides a description of the largest-scale structures and dynamics of the universe and allows study of fundamental questions about its origin, structure, evolution, and ultimate fate. Cosmology as a science originated with the Copernican principle, which implies that celestial bodies obey identical physical laws to those on Earth, and Newtonian mechanics, which first allowed those physical laws to be understood.

<span class="mw-page-title-main">Cosmic inflation</span> Theory of rapid universe expansion

In physical cosmology, cosmic inflation, cosmological inflation, or just inflation, is a theory of exponential expansion of space in the very early universe. Following the inflationary period, the universe continued to expand, but at a slower rate. The re-acceleration of this slowing expansion due to dark energy began after the universe was already over 7.7 billion years old.

<span class="mw-page-title-main">Cosmic microwave background</span> Trace radiation from the early universe

The cosmic microwave background, or relic radiation, is microwave radiation that fills all space in the observable universe. With a standard optical telescope, the background space between stars and galaxies is almost completely dark. However, a sufficiently sensitive radio telescope detects a faint background glow that is almost uniform and is not associated with any star, galaxy, or other object. This glow is strongest in the microwave region of the radio spectrum. The accidental discovery of the CMB in 1965 by American radio astronomers Arno Penzias and Robert Wilson was the culmination of work initiated in the 1940s.

<span class="mw-page-title-main">Hubble's law</span> Observation in physical cosmology

Hubble's law, also known as the Hubble–Lemaître law, is the observation in physical cosmology that galaxies are moving away from Earth at speeds proportional to their distance. In other words, the farther they are, the faster they are moving away. For this purpose, the recessional velocity of a galaxy is typically determined by measuring redshift, a shift in the light it emits toward the red end of the visible light spectrum. The discovery of Hubble's law is attributed to work published by Edwin Hubble in 1929.

The ekpyrotic universe is a cosmological model of the early universe that explains the origin of the large-scale structure of the cosmos. The model has also been incorporated in the cyclic universe theory, which proposes a complete cosmological history, both the past and future.

Hawking radiation is the theoretical emission released outside a black hole's event horizon. This is counterintuitive because once ordinary electromagnetic radiation is inside the event horizon, it cannot escape. It is named after the physicist Stephen Hawking, who developed a theoretical argument for its existence in 1974. Hawking radiation is predicted to be extremely faint and is many orders of magnitude below the current best telescopes' detecting ability.

Doubly special relativity (DSR) – also called deformed special relativity or, by some, extra-special relativity – is a modified theory of special relativity in which there is not only an observer-independent maximum velocity, but also an observer-independent maximum energy scale and/or a minimum length scale. This contrasts with other Lorentz-violating theories, such as the Standard-Model Extension, where Lorentz invariance is instead broken by the presence of a preferred frame. The main motivation for this theory is that the Planck energy should be the scale where as yet unknown quantum gravity effects become important and, due to invariance of physical laws, this scale should remain fixed in all inertial frames.

<span class="mw-page-title-main">Wilkinson Microwave Anisotropy Probe</span> NASA satellite of the Explorer program

The Wilkinson Microwave Anisotropy Probe (WMAP), originally known as the Microwave Anisotropy Probe, was a NASA spacecraft operating from 2001 to 2010 which measured temperature differences across the sky in the cosmic microwave background (CMB) – the radiant heat remaining from the Big Bang. Headed by Professor Charles L. Bennett of Johns Hopkins University, the mission was developed in a joint partnership between the NASA Goddard Space Flight Center and Princeton University. The WMAP spacecraft was launched on 30 June 2001 from Florida. The WMAP mission succeeded the COBE space mission and was the second medium-class (MIDEX) spacecraft in the NASA Explorer program. In 2003, MAP was renamed WMAP in honor of cosmologist David Todd Wilkinson (1935–2002), who had been a member of the mission's science team. After nine years of operations, WMAP was switched off in 2010, following the launch of the more advanced Planck spacecraft by European Space Agency (ESA) in 2009.

<span class="mw-page-title-main">Observable universe</span> All of space observable from the Earth at the present

The observable universe is a spherical region of the universe consisting of all matter that can be observed from Earth or its space-based telescopes and exploratory probes at the present time; the electromagnetic radiation from these objects has had time to reach the Solar System and Earth since the beginning of the cosmological expansion. Initially, it was estimated that there may be 2 trillion galaxies in the observable universe. That number was reduced in 2021 to several hundred billion based on data from New Horizons. Assuming the universe is isotropic, the distance to the edge of the observable universe is roughly the same in every direction. That is, the observable universe is a spherical region centered on the observer. Every location in the universe has its own observable universe, which may or may not overlap with the one centered on Earth.

An order of magnitude is usually a factor of ten. Thus, four orders of magnitude is a factor of 10,000 or 104.

<span class="mw-page-title-main">Age of the universe</span> Time elapsed since the Big Bang

In physical cosmology, the age of the universe is the time elapsed since the Big Bang. Astronomers have derived two different measurements of the age of the universe: a measurement based on direct observations of an early state of the universe, which indicate an age of 13.787±0.020 billion years as interpreted with the Lambda-CDM concordance model as of 2021; and a measurement based on the observations of the local, modern universe, which suggest a younger age. The uncertainty of the first kind of measurement has been narrowed down to 20 million years, based on a number of studies that all show similar figures for the age. These studies include researches of the microwave background radiation by the Planck spacecraft, the Wilkinson Microwave Anisotropy Probe and other space probes. Measurements of the cosmic background radiation give the cooling time of the universe since the Big Bang, and measurements of the expansion rate of the universe can be used to calculate its approximate age by extrapolating backwards in time. The range of the estimate is also within the range of the estimate for the oldest observed star in the universe.

<span class="mw-page-title-main">Lambda-CDM model</span> An anomaly in astronomical observations of the Cosmic Microwave Background

The Lambda-CDM, Lambda cold dark matter, or ΛCDM model is a mathematical model of the Big Bang theory with three major components:

  1. a cosmological constant, denoted by lambda (Λ), associated with dark energy
  2. the postulated cold dark matter, denoted by CDM
  3. ordinary matter
<span class="mw-page-title-main">Dirac large numbers hypothesis</span> Hypothesis relating age of the universe to physical constants

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<span class="mw-page-title-main">Dark energy</span> Energy driving the accelerated expansion of the universe

In physical cosmology and astronomy, dark energy is a proposed form of energy that affects the universe on the largest scales. Its primary effect is to drive the accelerating expansion of the universe. Assuming that the lambda-CDM model of cosmology is correct, dark energy dominates the universe, contributing 68% of the total energy in the present-day observable universe while dark matter and ordinary (baryonic) matter contribute 26% and 5%, respectively, and other components such as neutrinos and photons are nearly negligible. Dark energy's density is very low: 7×10−30 g/cm3, much less than the density of ordinary matter or dark matter within galaxies. However, it dominates the universe's mass–energy content because it is uniform across space.

Lorentz invariance follows from two independent postulates: the principle of relativity and the principle of constancy of the speed of light. Dropping the latter while keeping the former leads to a new invariance, known as Fock–Lorentz symmetry or the projective Lorentz transformation. The general study of such theories began with Fock, who was motivated by the search for the general symmetry group preserving relativity without assuming the constancy of c.

<span class="mw-page-title-main">Cosmological constant problem</span> Concept in cosmology

In cosmology, the cosmological constant problem or vacuum catastrophe is the substantial disagreement between the observed values of vacuum energy density and the much larger theoretical value of zero-point energy suggested by quantum field theory.

In particle physics and physical cosmology, Planck units are a system of units of measurement defined exclusively in terms of four universal physical constants: c, G, ħ, and kB. Expressing one of these physical constants in terms of Planck units yields a numerical value of 1. They are a system of natural units, defined using fundamental properties of nature rather than properties of a chosen prototype object. Originally proposed in 1899 by German physicist Max Planck, they are relevant in research on unified theories such as quantum gravity.

The "axis of evil" is a name given to an unsubstantiated correlation between the plane of the Solar System and aspects of the cosmic microwave background (CMB). It gives the plane of the Solar System and hence the location of Earth a greater significance than might be expected by chance – a result which has been claimed to be evidence of a departure from the Copernican principle. Later analysis found no such evidence.

The term physical constant expresses the notion of a physical quantity subject to experimental measurement which is independent of the time or location of the experiment. The constancy (immutability) of any "physical constant" is thus subject to experimental verification.

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