Draft page. For draft work and formula library.
The following five timelines show the geologic time scale to scale. The first shows the entire time from the formation of the Earth to the present, but this gives little space for the most recent eon. The second timeline shows an expanded view of the most recent eon. In a similar way, the most recent era is expanded in the third timeline, the most recent period is expanded in the fourth timeline, and the most recent epoch is expanded in the fifth timeline.
Horizontal scale is Millions of years (above timelines) / Thousands of years (below timeline)
Preceded by the Proterozoic Eon |
Phanerozoic Eon | |||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|
Paleozoic Era | Mesozoic Era | Cenozoic Era | ||||||||||
Cambrian | Ordovician | Silurian | Devonian | Carboniferous | Permian | Triassic | Jurassic | Cretaceous | Paleogene | Neogene | 4ry |
3rr: 4th edit Warned after 3 reverts 3rd edit 2nd edit 1st edit
Semi-protect. High level of disruptive IP POV tag teaming over many months. Last 24 hrs has seen 3 IPs at work. Repeated attempts at dialog with IP on talk page fail. -- Michael C. Price talk 10:20, 10 November 2009 (UTC)
at [12]
.
Peter J. Lewis (2007). “How Bohm’s Theory Solves the Measurement Problem”, Philosophy of Science 74 (5): 749–760 Lewis on Wallace & Brown's identification of Bohm's result assumption Also Lewis “Empty Waves in Bohmian Quantum Mechanics”, British Journal for the Philosophy of Science 58: 787–803 (2007).
Q: Hugh Everett says that Bohm's particles are not observable entities, but surely they are - what hits the detectors and causes flashes?
A:
Both Hugh Everett III and Bohm treated the wavefunction as a complex-valued but real field. Everett's many-worlds interpretation is an attempt to demonstrate that the wavefunction alone is sufficient to account for all our observations. When we see the particle detectors flash or hear the click of a Geiger counter or whatever then Everett's theory interprets this as our wavefunction responding to changes in the detector's wavefunction, which is responding in turn to the passage of another wavefunction (which we think of as a "particle", but is actually just another wave-packet). [1] But no particle, in the Bohm sense of having a defined position and velocity, is involved in measurement. [1] For this reason Everett sometimes referred to his approach as the "pure wave theory". Talking of Bohm's 1952 approach, Everett says:
“ | Our main criticism of this view is on the grounds of simplicity - if one desires to hold the view that is a real field then the associated particle is superfluous since, as we have endeavored to illustrate, the pure wave theory is itself satisfactory. [2] | ” |
In the Everettian view, then, the Bohm particles are unobservable entities, similar to, and equally as unnecessary as, for example, the luminiferous ether was found to be unnecessary in special relativity. In Everett's view, we can remove the particles from Bohm's theory and still account for all our observations. The unobservability of the "hidden particles" stems from an asymmetry in the causal structure of the theory; the particles are influenced by a "force" exerted by the wavefunction and by each other, but the particles do not influence the time development of the wavefunction (i.e. there is no analogue of Newton's third law -- the particles do not react back onto the wavefunction [1]) Thus, if we regard the wavefunction as real and the source of all experience, the particles do not make their presence known in any way; as the theory says, they are hidden, but in a far more profound way than de Broglie and Bohm had intended.
In the Everettian view the role of the Bohm particle is to tag, or select, just one branch of the universal wavefunction; the other branches are designated "empty" and implicitly assumed by Bohm, in what is called the "result assumption", to be devoid of conscious observers. [1] H. Dieter Zeh comments on these "empty" branches:
“ | It is usually overlooked that Bohm’s theory contains the same “many worlds” of dynamically separate branches as the Everett interpretation (now regarded as “empty” wave components), since it is based on precisely the same . . . global wave function . . . [3] | ” |
David Deutsch has expressed the same point more "acerbically" [1]:
“ | pilot-wave theories are parallel-universe theories in a state of chronic denial. [4] | ” |
This argument of Everett's is sometimes called the "redundancy argument", since the superfluous particles are redundant in the sense of Occam's razor. [5].
This conclusion has been challenged by pilot wave advocates, with a number of suggested resolutions; either make the "result assumption" explicit [1], deny that the wavefunction is as objectively real as the particles [5] or dispute whether the Everett prescription is complete (e.g. can probabilities be derived from the wavefunction?) [5]
(abstract, page 1)
(page 5)W&B's result assumption, from Bohm part II:
(page 6) W&B's question:
(page 6/7)
(page 7)
(page 8/9)
(page 12)
(page 13) Footnote 41:
(page 14/15) On Maudlin:
(page 15) Footnote 46:
(page 15) Footnote 47:
(page 17) Parting words:
I never accuse anyone of incivility
Hilarious protestations of innocence
I don't really care about {Civility}, and I never accuse anyone of incivility
Plants are not living organisms
The article says:
But don't all ghosts imply negative norm states? I notice, reading Cheng and Li, that Faddeev-Popov ghost propagators always have the opposite sign from the analogous non-ghost propagators, which implies the opposite sign for their norm.-- Michael C. Price talk 12:48, 2 July 2007 (UTC)
Wikipedia:Resolving disputes Wikipedia:Requests for arbitration Wikipedia:Ignore all rules Wikipedia:Policies and guidelines Wikipedia:How to create policy Wikipedia:Stable versions Wikipedia:Criteria for speedy deletion Wikipedia:Administrators' noticeboard/3RR
Please stop. If you continue to vandalize pages, you will be blocked from editing Wikipedia.
{{
cite journal}}
: External link in |title=
(
help)
{{
cite journal}}
: Cite journal requires |journal=
(
help); External link in |title=
(
help)
.
Orthomolecular megavitamin therapies, such as "megadose" usage of tocopherols [1] and ascorbates [2], date back to the 1930s.
The term "orthomolecular" was first used by Linus Pauling in 1968, to express the "idea of the right molecules in the right amounts" [3] and subsequently defined "orthomolecular medicine" as "the treatment of disease by the provision of the optimum molecular environment, especially the optimum concentrations of substances normally present in the human body." or as "the preservation of good health and the treatment of disease by varying the concentrations in the human body of substances that are normally present in the body and are required for health." [4]
Since 1968 the orthomolecular field has developed further through the works of mainstream and non-mainstream researchers. Despite thus it still is often closely associated by the public with Pauling's advocacy of multi-gram doses of vitamin C for optimal health.
An example of a recent mainstream researcher is nutrition researcher Bruce Ames although he does not use the term itself. However his research deals with nutrition and specific genetic disease conditions (as indeed did Pauling's original article which defined the term "orthomolecular" [3]). Ames' research includes investigating the effects of large doses of, for example, the nutrients alpha-lipoic acid (a coenzyme precursor) and the carnitine (an amino acid complex) on restoring metabolic health, and in particular mitochondrial function, in animal models [5] [6] [7] Ames has also investigated the role of high dose B-vitamin therapy in alleviating in approximately 50 defective co-enzyme binding affinities, of which one, at least, every human suffers from [8] (example of one genetic disease condition: Over 40% of the population is hetro- or homo-zygous with the thermolabile variant of 5,10- methylenetetrahydrofolate reductase [9] and as a result requires extra riboflavin [10] [8]).
Ames has, based on his research, developed a supplement for human use [11].
this list of tags [ failed verification] [ original research?] [ who?]
The Landau-Lifshitz pseudotensor of the gravitational field has the following construction
where:
is the Einstein tensor
is the metric tensor
is the determinant of a spacetime Lorentz metric
are partial derivatives, not covariant derivatives.
G is Newton's gravitational constant.
The Landau-Lifshitz pseudotensor is constructed so that when added to the stress-energy tensor of matter, , its total divergence vanishes:
This follows from the cancellation of the Einstein tensor, , with the stress-energy tensor, by the Einstein field equations; the remaining term vanishes algebraically due the commutativity of partial derivatives applied across antisymmetric indices.
Mainstream critics point out that Einstein's special theory of relativity is an extension of the principles of Galilean relativity or invariance from classical mechanics to include Maxwell's equations and thereby optics.
In the mainstream view, therefore, any attempt to formulate a new aether theory by recourse to Galilean relativity, is doomed since Galilean invariance is already incorporated into special relativity under the name Lorentz invariance; any putative aether is considered to be devoid of mechanical properties, unobservable and hence superfluous. [12] It is held that any non-superfluous aether theory would yield predictions that are incompatible with Lorentz invariance and thereby Maxwell's equations; however the latter is empirically very well attested.
Consequently the concept of a "Galilean" aether or space has not been used in the Theory of Relativity, Quantum mechanics, or other modern theories of physics.
This reference by Einstein in his 1905 paper is probably not about MMX, but to other attempts to detect the ether. Einstein is on record, early on, as saying that he hadn't heard of the MMX null result until after 1905, although later in his life, when we can presume his memory would not be so clear about distant events, he contradicted himself on this point. (Cf A P French's standard textbook (or see Michael Polanyi on this point) - French concludes that Einstein had not heard about the MMX -- and although you can find many texts that assume the reverse, they are wrong, IMO.)
A P French, Special Relativity,
or
developed from? ISBN 0-393-09793-5 (1966) 0-412-34320-7
The electroweak lagrangian can be written as [13] [14]:
The g term describes the gauge fields
The f term describes the interaction between the electrons, muons, and quarks (the Dirac particles) of the Standard Model. The subscripts Li and Ri in and refer to the Left and Right-handed spin of the i-th species of Dirac particles in the Standard Model. This is reflected in the asymmetric form of this term.
The H term describes the Higgs field .
where
This gives rise to an effective lagrangian with a mass term, where the is mass generated by the interaction of the Higgs with the other varieties of particles given in the Lagrangian:
Measurement and observation are easily handled in MWI. Measurements, or measurement-like interactions, are any interactions that correlate the observer's wavefunction with the observed system's wavefunction. A measurement, when the observed system is a definite state labelled by i, simply induces:
where O[i] represents the observer having detected the object system in the i-th state. In words this simply represents the observer measuring the observed system in the i-th state.
A measurement is complete when:
Before the measurement has started the observer states are identical; after the measurement is complete the observer states are orthonormal. [15] [16] Thus a measurement defines the branching process: the branching is as well- or ill- defined as the measurement is. Thus branching is complete when the measurement is complete. Since the role of the observer and measurement per se plays no special role in MWI (measurements are handled as all other interactions are) there is no need for a precise definition of what an observer or a measurement is – just as in Newtonian physics no precise definition of either an observer or a measurement was required or expected. In all circumstances the universal wavefunction is still available to give a complete description of reality.
MWI describes measurements as a formation of an entangled state which is a perfectly linear process (in terms of quantum superpositions) without any collapse of the wave function. For illustration, consider a Stern-Gerlach experiment and an electron or a silver atom passing this apparatus with a spin polarization in the left-right or x direction and thus a superposition of a spin up and a spin down state in up-down or z-direction. As a measuring apparatus, take a bubble or tracking chamber (a nonabsorbing particle detector). And finally let a cat observe the bubble tracks that form in the bubble chamber. The electron passes the apparatus and reach the same site in the end on either way so that, except for the up-down z-spin polarization, the state of the electron is finally the same regardless of the path taken (see The Feynman Lectures on Physics for a detailed discussion of such a setup). Before the measurement, the state of the electron and measuring apparatus is:
The state is factorizable into a tensor factor for the electron and another factor for the measurement apparatus. After the spin measurement (bubble formation), the state is:
The state is no longer factorizable -- regardless of the vector basis chosen the state has to be expressed as the sum of a number of terms (in this example, at least two). The state of the above experiment is decomposed into a sum of two correlated or so-called entangled states ("worlds") both of which will have their individivual history without any further interaction or quantum interference between the two due to the physical linearity of quantum mechanics (the superposition principle): All processes in nature are linear and correspond to linear operators acting on each superposition component individually without any notice of the other components being present.
This would also be true for two non-entangled superposed states, but the latter can be detected by interference which is not possible for different entangled states (without reversing the entanglement first): Different entangled states cannot interfere; interactions with other systems will only result in a further entanglement of them as well. In the example above, the state of a Schrödinger cat watching the scene will be factorizable in the beginning (before watching)
but not in the end (after watching)
This example also shows that it's not the whole world that is split up into "many worlds", but only the part of the world that is entangled with the considered quantum event. This splitting tends to extend by interactions and can be visualised by a zipper or a DNA molecule which are in a similar way not completely opened instantaneously but opens gradually, element by element.
Imaginative readers will even see the zipper structure and the extending splitting in the formula:
If a system state is entangled with many other degrees of freedom (such as those in amplifiers, photographs, heat, sound, computer memory circuits, neurons, paper documents) in an experiment, this amounts to a thermodynamically irreversible process which is constituted of many small individually reversible processes at the atomic or subatomic level as is generally the case for thermodynamic irreversibility in classical or quantum statistical mechanics. Thus there is -- for thermodynamic reasons -- no way for an observer to completely reverse the entanglement and thus observe the other worlds by doing interference experiments on them. On the other hand, for small systems with few degrees of freedom this is feasible, as long as the investigated aspect of the system remains unentangled with the rest of the world.
The MWI thus solves the measurement problem of quantum mechanics by reducing measurements to cascades of entanglements.
The formation of an entangled state is a linear operation in terms of quantum superpositions. Consider for example the vector basis
and the non-entangled initial state
The linear (and unitary and thus reversible) operation (in terms of quantum superpositions) corresponding to the matrix
(in the above vector basis) will result in the entangled state
[19] [20] [21] [22] [23] [24] [25] [26] [27]
everett57
was invoked but never defined (see the
help page).dewitt73
was invoked but never defined (see the
help page).{{
cite book}}
: |pages=
has extra text (
help)
.
Draft page. For draft work and formula library.
The following five timelines show the geologic time scale to scale. The first shows the entire time from the formation of the Earth to the present, but this gives little space for the most recent eon. The second timeline shows an expanded view of the most recent eon. In a similar way, the most recent era is expanded in the third timeline, the most recent period is expanded in the fourth timeline, and the most recent epoch is expanded in the fifth timeline.
Horizontal scale is Millions of years (above timelines) / Thousands of years (below timeline)
Preceded by the Proterozoic Eon |
Phanerozoic Eon | |||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|
Paleozoic Era | Mesozoic Era | Cenozoic Era | ||||||||||
Cambrian | Ordovician | Silurian | Devonian | Carboniferous | Permian | Triassic | Jurassic | Cretaceous | Paleogene | Neogene | 4ry |
3rr: 4th edit Warned after 3 reverts 3rd edit 2nd edit 1st edit
Semi-protect. High level of disruptive IP POV tag teaming over many months. Last 24 hrs has seen 3 IPs at work. Repeated attempts at dialog with IP on talk page fail. -- Michael C. Price talk 10:20, 10 November 2009 (UTC)
at [12]
.
Peter J. Lewis (2007). “How Bohm’s Theory Solves the Measurement Problem”, Philosophy of Science 74 (5): 749–760 Lewis on Wallace & Brown's identification of Bohm's result assumption Also Lewis “Empty Waves in Bohmian Quantum Mechanics”, British Journal for the Philosophy of Science 58: 787–803 (2007).
Q: Hugh Everett says that Bohm's particles are not observable entities, but surely they are - what hits the detectors and causes flashes?
A:
Both Hugh Everett III and Bohm treated the wavefunction as a complex-valued but real field. Everett's many-worlds interpretation is an attempt to demonstrate that the wavefunction alone is sufficient to account for all our observations. When we see the particle detectors flash or hear the click of a Geiger counter or whatever then Everett's theory interprets this as our wavefunction responding to changes in the detector's wavefunction, which is responding in turn to the passage of another wavefunction (which we think of as a "particle", but is actually just another wave-packet). [1] But no particle, in the Bohm sense of having a defined position and velocity, is involved in measurement. [1] For this reason Everett sometimes referred to his approach as the "pure wave theory". Talking of Bohm's 1952 approach, Everett says:
“ | Our main criticism of this view is on the grounds of simplicity - if one desires to hold the view that is a real field then the associated particle is superfluous since, as we have endeavored to illustrate, the pure wave theory is itself satisfactory. [2] | ” |
In the Everettian view, then, the Bohm particles are unobservable entities, similar to, and equally as unnecessary as, for example, the luminiferous ether was found to be unnecessary in special relativity. In Everett's view, we can remove the particles from Bohm's theory and still account for all our observations. The unobservability of the "hidden particles" stems from an asymmetry in the causal structure of the theory; the particles are influenced by a "force" exerted by the wavefunction and by each other, but the particles do not influence the time development of the wavefunction (i.e. there is no analogue of Newton's third law -- the particles do not react back onto the wavefunction [1]) Thus, if we regard the wavefunction as real and the source of all experience, the particles do not make their presence known in any way; as the theory says, they are hidden, but in a far more profound way than de Broglie and Bohm had intended.
In the Everettian view the role of the Bohm particle is to tag, or select, just one branch of the universal wavefunction; the other branches are designated "empty" and implicitly assumed by Bohm, in what is called the "result assumption", to be devoid of conscious observers. [1] H. Dieter Zeh comments on these "empty" branches:
“ | It is usually overlooked that Bohm’s theory contains the same “many worlds” of dynamically separate branches as the Everett interpretation (now regarded as “empty” wave components), since it is based on precisely the same . . . global wave function . . . [3] | ” |
David Deutsch has expressed the same point more "acerbically" [1]:
“ | pilot-wave theories are parallel-universe theories in a state of chronic denial. [4] | ” |
This argument of Everett's is sometimes called the "redundancy argument", since the superfluous particles are redundant in the sense of Occam's razor. [5].
This conclusion has been challenged by pilot wave advocates, with a number of suggested resolutions; either make the "result assumption" explicit [1], deny that the wavefunction is as objectively real as the particles [5] or dispute whether the Everett prescription is complete (e.g. can probabilities be derived from the wavefunction?) [5]
(abstract, page 1)
(page 5)W&B's result assumption, from Bohm part II:
(page 6) W&B's question:
(page 6/7)
(page 7)
(page 8/9)
(page 12)
(page 13) Footnote 41:
(page 14/15) On Maudlin:
(page 15) Footnote 46:
(page 15) Footnote 47:
(page 17) Parting words:
I never accuse anyone of incivility
Hilarious protestations of innocence
I don't really care about {Civility}, and I never accuse anyone of incivility
Plants are not living organisms
The article says:
But don't all ghosts imply negative norm states? I notice, reading Cheng and Li, that Faddeev-Popov ghost propagators always have the opposite sign from the analogous non-ghost propagators, which implies the opposite sign for their norm.-- Michael C. Price talk 12:48, 2 July 2007 (UTC)
Wikipedia:Resolving disputes Wikipedia:Requests for arbitration Wikipedia:Ignore all rules Wikipedia:Policies and guidelines Wikipedia:How to create policy Wikipedia:Stable versions Wikipedia:Criteria for speedy deletion Wikipedia:Administrators' noticeboard/3RR
Please stop. If you continue to vandalize pages, you will be blocked from editing Wikipedia.
{{
cite journal}}
: External link in |title=
(
help)
{{
cite journal}}
: Cite journal requires |journal=
(
help); External link in |title=
(
help)
.
Orthomolecular megavitamin therapies, such as "megadose" usage of tocopherols [1] and ascorbates [2], date back to the 1930s.
The term "orthomolecular" was first used by Linus Pauling in 1968, to express the "idea of the right molecules in the right amounts" [3] and subsequently defined "orthomolecular medicine" as "the treatment of disease by the provision of the optimum molecular environment, especially the optimum concentrations of substances normally present in the human body." or as "the preservation of good health and the treatment of disease by varying the concentrations in the human body of substances that are normally present in the body and are required for health." [4]
Since 1968 the orthomolecular field has developed further through the works of mainstream and non-mainstream researchers. Despite thus it still is often closely associated by the public with Pauling's advocacy of multi-gram doses of vitamin C for optimal health.
An example of a recent mainstream researcher is nutrition researcher Bruce Ames although he does not use the term itself. However his research deals with nutrition and specific genetic disease conditions (as indeed did Pauling's original article which defined the term "orthomolecular" [3]). Ames' research includes investigating the effects of large doses of, for example, the nutrients alpha-lipoic acid (a coenzyme precursor) and the carnitine (an amino acid complex) on restoring metabolic health, and in particular mitochondrial function, in animal models [5] [6] [7] Ames has also investigated the role of high dose B-vitamin therapy in alleviating in approximately 50 defective co-enzyme binding affinities, of which one, at least, every human suffers from [8] (example of one genetic disease condition: Over 40% of the population is hetro- or homo-zygous with the thermolabile variant of 5,10- methylenetetrahydrofolate reductase [9] and as a result requires extra riboflavin [10] [8]).
Ames has, based on his research, developed a supplement for human use [11].
this list of tags [ failed verification] [ original research?] [ who?]
The Landau-Lifshitz pseudotensor of the gravitational field has the following construction
where:
is the Einstein tensor
is the metric tensor
is the determinant of a spacetime Lorentz metric
are partial derivatives, not covariant derivatives.
G is Newton's gravitational constant.
The Landau-Lifshitz pseudotensor is constructed so that when added to the stress-energy tensor of matter, , its total divergence vanishes:
This follows from the cancellation of the Einstein tensor, , with the stress-energy tensor, by the Einstein field equations; the remaining term vanishes algebraically due the commutativity of partial derivatives applied across antisymmetric indices.
Mainstream critics point out that Einstein's special theory of relativity is an extension of the principles of Galilean relativity or invariance from classical mechanics to include Maxwell's equations and thereby optics.
In the mainstream view, therefore, any attempt to formulate a new aether theory by recourse to Galilean relativity, is doomed since Galilean invariance is already incorporated into special relativity under the name Lorentz invariance; any putative aether is considered to be devoid of mechanical properties, unobservable and hence superfluous. [12] It is held that any non-superfluous aether theory would yield predictions that are incompatible with Lorentz invariance and thereby Maxwell's equations; however the latter is empirically very well attested.
Consequently the concept of a "Galilean" aether or space has not been used in the Theory of Relativity, Quantum mechanics, or other modern theories of physics.
This reference by Einstein in his 1905 paper is probably not about MMX, but to other attempts to detect the ether. Einstein is on record, early on, as saying that he hadn't heard of the MMX null result until after 1905, although later in his life, when we can presume his memory would not be so clear about distant events, he contradicted himself on this point. (Cf A P French's standard textbook (or see Michael Polanyi on this point) - French concludes that Einstein had not heard about the MMX -- and although you can find many texts that assume the reverse, they are wrong, IMO.)
A P French, Special Relativity,
or
developed from? ISBN 0-393-09793-5 (1966) 0-412-34320-7
The electroweak lagrangian can be written as [13] [14]:
The g term describes the gauge fields
The f term describes the interaction between the electrons, muons, and quarks (the Dirac particles) of the Standard Model. The subscripts Li and Ri in and refer to the Left and Right-handed spin of the i-th species of Dirac particles in the Standard Model. This is reflected in the asymmetric form of this term.
The H term describes the Higgs field .
where
This gives rise to an effective lagrangian with a mass term, where the is mass generated by the interaction of the Higgs with the other varieties of particles given in the Lagrangian:
Measurement and observation are easily handled in MWI. Measurements, or measurement-like interactions, are any interactions that correlate the observer's wavefunction with the observed system's wavefunction. A measurement, when the observed system is a definite state labelled by i, simply induces:
where O[i] represents the observer having detected the object system in the i-th state. In words this simply represents the observer measuring the observed system in the i-th state.
A measurement is complete when:
Before the measurement has started the observer states are identical; after the measurement is complete the observer states are orthonormal. [15] [16] Thus a measurement defines the branching process: the branching is as well- or ill- defined as the measurement is. Thus branching is complete when the measurement is complete. Since the role of the observer and measurement per se plays no special role in MWI (measurements are handled as all other interactions are) there is no need for a precise definition of what an observer or a measurement is – just as in Newtonian physics no precise definition of either an observer or a measurement was required or expected. In all circumstances the universal wavefunction is still available to give a complete description of reality.
MWI describes measurements as a formation of an entangled state which is a perfectly linear process (in terms of quantum superpositions) without any collapse of the wave function. For illustration, consider a Stern-Gerlach experiment and an electron or a silver atom passing this apparatus with a spin polarization in the left-right or x direction and thus a superposition of a spin up and a spin down state in up-down or z-direction. As a measuring apparatus, take a bubble or tracking chamber (a nonabsorbing particle detector). And finally let a cat observe the bubble tracks that form in the bubble chamber. The electron passes the apparatus and reach the same site in the end on either way so that, except for the up-down z-spin polarization, the state of the electron is finally the same regardless of the path taken (see The Feynman Lectures on Physics for a detailed discussion of such a setup). Before the measurement, the state of the electron and measuring apparatus is:
The state is factorizable into a tensor factor for the electron and another factor for the measurement apparatus. After the spin measurement (bubble formation), the state is:
The state is no longer factorizable -- regardless of the vector basis chosen the state has to be expressed as the sum of a number of terms (in this example, at least two). The state of the above experiment is decomposed into a sum of two correlated or so-called entangled states ("worlds") both of which will have their individivual history without any further interaction or quantum interference between the two due to the physical linearity of quantum mechanics (the superposition principle): All processes in nature are linear and correspond to linear operators acting on each superposition component individually without any notice of the other components being present.
This would also be true for two non-entangled superposed states, but the latter can be detected by interference which is not possible for different entangled states (without reversing the entanglement first): Different entangled states cannot interfere; interactions with other systems will only result in a further entanglement of them as well. In the example above, the state of a Schrödinger cat watching the scene will be factorizable in the beginning (before watching)
but not in the end (after watching)
This example also shows that it's not the whole world that is split up into "many worlds", but only the part of the world that is entangled with the considered quantum event. This splitting tends to extend by interactions and can be visualised by a zipper or a DNA molecule which are in a similar way not completely opened instantaneously but opens gradually, element by element.
Imaginative readers will even see the zipper structure and the extending splitting in the formula:
If a system state is entangled with many other degrees of freedom (such as those in amplifiers, photographs, heat, sound, computer memory circuits, neurons, paper documents) in an experiment, this amounts to a thermodynamically irreversible process which is constituted of many small individually reversible processes at the atomic or subatomic level as is generally the case for thermodynamic irreversibility in classical or quantum statistical mechanics. Thus there is -- for thermodynamic reasons -- no way for an observer to completely reverse the entanglement and thus observe the other worlds by doing interference experiments on them. On the other hand, for small systems with few degrees of freedom this is feasible, as long as the investigated aspect of the system remains unentangled with the rest of the world.
The MWI thus solves the measurement problem of quantum mechanics by reducing measurements to cascades of entanglements.
The formation of an entangled state is a linear operation in terms of quantum superpositions. Consider for example the vector basis
and the non-entangled initial state
The linear (and unitary and thus reversible) operation (in terms of quantum superpositions) corresponding to the matrix
(in the above vector basis) will result in the entangled state
[19] [20] [21] [22] [23] [24] [25] [26] [27]
everett57
was invoked but never defined (see the
help page).dewitt73
was invoked but never defined (see the
help page).{{
cite book}}
: |pages=
has extra text (
help)
.