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Collape and ampilification Theories of Quantum Locality

 

GRW THEORY OF QUANTUM MEASURE.

---------------------------------------------------------------

Ghirardi–Rimini–Weber theory


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அளபடையம் என்பதே இங்கு குவாண்டம் ஆகும்.கிரார்டி _ ரிமினி _வெபர் ஆகிய மூவர் கோட்பாடு ஜி ஆர் டபிள்யூ கோட்பாடு என்று இங்கே குறிப்பிடப்படுகிறது.என்ன அந்த மூவர் கோட்பாடு? 1986 ல் இது இவர்களால் நிறுவப்பட்டது.விஞ்ஞானிகளின் பிடிக்குள் வராமல் அடம் செய்யும் குவாண்டம் எனும் அளபடையம் பற்றி நாம் நுண்மையான கணித சமன்பாடுகள் மூலம் அடையாளப்படுத்தும் ஒரு நிலைப்பாட்டில் நின்று கொண்டிருக்கிறோம். இந்த "பொன் மானை" வேட்டையாடுவது என்பது  குவாண்டத்தை அளவிடுவதே.  அதை அளவிடும்போதே அது காணாமல் போய்விடும் தன்மை தான் இங்கு சிக்கல் தருகிறது.மெஷர்மென்டே ஒரு ஸ்பொன்டேனியஸ் கொலேப்ஸ் ஆகி விடும் இதை எப்படி அணுகுவது என்பதே குவாண்டம் விஞ்ஞானிகளின் நோக்கம் ஆகும். இந்த குவாண்ட அல்லது அளபடைய இயங்கியம் (டைனாமிக்ஸ்) திடீரென்று அப்படி வீழ்ச்சி(கொலேப்ஸ்) அடைவது அல்லது காணாமல் போய்விடுவது என்பது நடைபெறுவது காலம் மற்றும் வெளி ஆகிய இரு பரிமாணங்களிலும் தான்.காலப்பகுதியில்(டைம்) ஒரு சராசரி அளவீட்டிலும் (ஆவ்ரேஜ் ரேட்) "வெளிப்"(ஸ்பேஸ்) பகுதியில் போர்ன் விதிப்படியும் இது நிகழ்கிறது.அது என்ன "போர்ன்"விதி?




The Ghirardi–Rimini–Weber theory (GRW) is a spontaneous collapse theory in quantum mechanics, proposed in 1986 by Giancarlo Ghirardi, Alberto Rimini, and Tullio Weber.[1]


Measurement problem and spontaneous collapses

Quantum mechanics has two fundamentally different dynamical principles: the linear and deterministic Schrödinger equation, and the nonlinear and stochastic wave packet reduction postulate. The orthodox interpretation, or Copenhagen interpretation of quantum mechanics, posits a wave function collapse every time an observer performs a measurement. One thus faces the problem of defining what an “observer” and a “measurement” are. Another issue of quantum mechanics is that it forecasts superpositions of macroscopic objects, which are not observed in nature (see Schrödinger’s cat paradox). The theory does not tell where the threshold between the microscopic and macroscopic worlds is, that is when quantum mechanics should leave space to classical mechanics. The aforementioned issues constitute the measurement problem in quantum mechanics.


Collapse theories avoid the measurement problem by merging the two dynamical principles of quantum mechanics in a unique dynamical description. The physical idea that underlies collapse theories is that particles undergo spontaneous wave-function collapses, which occur randomly both in time (at a given average rate), and in space (according to the Born rule). The imprecise talk of “observer” and a “measurement” that plagues the orthodox interpretation is thus avoided because the wave function collapses spontaneously. Furthermore, thanks to a so called “amplification mechanism” (later discussed), collapse theories recover both quantum mechanics for microscopic objects, and classical mechanics for macroscopic ones.


The GRW is the first spontaneous collapse theory that was devised. In the following years the field developed and several different models were proposed. Among these are the CSL model,[2] which is formulated in terms of identical particles; the Diósi–Penrose model,[3][4] which relates the spontaneous collapse to gravity; the QMUPL model,[3][5] which proves important mathematical results on collapse theories; and the coloured QMUPL model,[6][7][8][9] which is the only collapse model involving coloured stochastic processes for which the exact solution is known.


The theory

The first assumption of the GRW theory is that the wave function (or state vector) represents the most accurate possible specification of the state of a physical system. This is a feature that the GRW theory shares with the standard Interpretations of quantum mechanics, and distinguishes it from hidden variable theories, like the de Broglie–Bohm theory, according to which the wave function does not give a complete description of a physical system. The GRW theory differs from standard quantum mechanics for the dynamical principles according to which the wave function evolves.[10][11] For more philosophical issues related to the GRW theory and to collapse theories in general one should refer to.[12]


Working principles

Each particle of a system described by the multi-particle wave function 

|

𝜓

⟩{\displaystyle |\psi \rangle } independently undergoes a spontaneous localization process (or jump):

|

𝜓

|

𝜓

𝑥

𝑖

𝜓

𝑥

𝑖

|

𝜓

𝑥

𝑖

⟩{\displaystyle |\psi \rangle \rightarrow {\frac {|\psi _{x}^{i}\rangle }{\sqrt {\langle \psi _{x}^{i}|\psi _{x}^{i}\rangle }}}} ,


where 

|

𝜓

𝑥

𝑖

=

𝐿

^

𝑥

𝑖

|

𝜓

⟩{\displaystyle |\psi _{x}^{i}\rangle ={\hat {L}}_{x}^{i}|\psi \rangle } is the state after the operator 

𝐿

^

𝑥

𝑖

{\displaystyle {\hat {L}}_{x}^{i}} has localized the 

𝑖

{\displaystyle i}-th particle around the position 

𝑥

{\displaystyle x}.


The localization process is random both in space and time. The jumps are Poisson distributed in time, with mean rate 

𝜆{\displaystyle \lambda }; the probability density for a jump to occur at position 

𝑥

{\displaystyle x} is 

𝑃

𝑖

(

𝑥

)

=

𝜓

𝑥

𝑖

|

𝜓

𝑥

𝑖

⟩{\displaystyle P_{i}(x)=\langle \psi _{x}^{i}|\psi _{x}^{i}\rangle }.

The localization operator has a Gaussian form:

𝐿

^

𝑥

𝑖

=

(

1

𝜋

𝑟

𝐶

2

)

3

4

𝑒

(

𝑞

^

𝑖

𝑥

)

2

2

𝑟

𝐶

2

{\displaystyle {\hat {L}}_{x}^{i}=\left({\frac {1}{\pi r_{C}^{2}}}\right)^{\frac {3}{4}}e^{-{\frac {({\hat {q}}_{i}-x)^{2}}{2r_{C}^{2}}}}} ,


where 

𝑞

^

𝑖

{\displaystyle {\hat {q}}_{i}} is the position operator of the 

𝑖

{\displaystyle i}-th particle, and 

𝑟

𝐶

{\displaystyle r_{C}} is the localization distance.


In between two localization processes, the wave function evolves according to the Schrödinger equation.

These principles can be expressed in a more compact way with the statistical operator formalism. Since the localization process is Poissonian, in a time interval 

𝑑

𝑡

{\displaystyle dt} there is a probability 

𝜆

𝑑

𝑡

{\displaystyle \lambda dt} that a collapse occurs, i.e. that the pure state 

𝜌

=

|

𝜓

𝜓

|

{\displaystyle \rho =|\psi \rangle \langle \psi |} is transformed into the following statistical mixture:


𝑇

^

𝑖

[

𝜌

]

𝑑

𝑥

𝐿

^

𝑥

𝑖

|

𝜓

𝜓

|

𝐿

^

𝑥

𝑖

{\displaystyle {\hat {T}}_{i}[\rho ]\equiv \int dx\,{\hat {L}}_{x}^{i}|\psi \rangle \langle \psi |{\hat {L}}_{x}^{i}} .


In the same time interval, there is a probability 

1

𝜆

𝑑

𝑡

{\displaystyle 1-\lambda dt} that the system keeps evolving according to the Schrödinger equation. Accordingly, the GRW master equation for 

𝑁

{\displaystyle N} particles reads


𝑑

𝑑

𝑡

𝜌

(

𝑡

)

=

𝑖

[

𝐻

^

,

𝜌

(

𝑡

)

]

𝑖

=

1

𝑁

𝜆

𝑖

(

𝜌

(

𝑡

)

𝑇

^

𝑖

[

𝜌

]

)

{\displaystyle {\frac {d}{dt}}\rho (t)=-{\frac {i}{\hbar }}[{\hat {H}},\rho (t)]-\sum _{i=1}^{N}\lambda _{i}\left(\rho (t)-{\hat {T}}_{i}[\rho ]\right)} ,


where 

𝐻

^{\displaystyle {\hat {H}}} is the Hamiltonian of the system, and the square brackets denote a commutator.


Two new parameters are introduced by the GRW theory, namely the collapse rate 

𝜆{\displaystyle \lambda } and the localization distance 

𝑟

𝐶

{\displaystyle r_{C}}. These are phenomenological parameters, whose values are not fixed by any principle and should be understood as new constants of Nature. Comparison of the model's predictions with experimental data permits bounding of the values of the parameters (see CSL model). The collapse rate should be such that microscopic object are almost never localized, thus effectively recovering standard quantum mechanics. The value originally proposed was 

𝜆

=

10

16

s

1

{\displaystyle \lambda =10^{-16}\mathrm {s} ^{-1}},[1] while more recently Stephen L. Adler proposed that the value 

𝜆

=

10

8

s

1

{\displaystyle \lambda =10^{-8}\mathrm {s} ^{-1}} (with an uncertainty of two orders of magnitude) is more adequate.[13] There is a general consensus on the value 

𝑟

𝐶

=

10

7

m

{\displaystyle r_{C}=10^{-7}\mathrm {m} } for the localization distance. This is a mesoscopic distance, such that microscopic superpositions are left unaltered, while macroscopic ones are collapsed.


Examples

When the wave function is hit by a sudden jump, the action of the localization operator essentially results in the multiplication of the wave function by the collapse Gaussian.


Let us consider a Gaussian wave function with spread 

𝜎{\displaystyle \sigma }, centered at 

𝑥

=

𝑎

{\displaystyle x=a}, and let us assume that this undergoes a localization process at the position 

𝑥

=

𝑎

{\displaystyle x=a}. One thus has (in one dimension)


𝜓

(

𝑥

)

=

1

(

𝜋

𝜎

)

1

4

𝑒

(

𝑥

𝑎

)

2

2

𝜎

2

𝜓

𝑎

(

𝑥

)

=

𝐿

^

𝑥

=

𝑎

𝜓

(

𝑥

)

=

𝑁

𝑒

(

𝑥

𝑎

)

2

2

𝑟

𝐶

2

𝑒

(

𝑥

𝑎

)

2

2

𝜎

2

{\displaystyle \psi (x)={\frac {1}{(\pi \sigma )^{\frac {1}{4}}}}\,e^{-{\frac {(x-a)^{2}}{2\sigma ^{2}}}}\quad \longrightarrow \quad \psi _{a}(x)={\hat {L}}_{x=a}\,\psi (x)={\cal {N}}e^{-{\frac {(x-a)^{2}}{2r_{C}^{2}}}}\,e^{-{\frac {(x-a)^{2}}{2\sigma ^{2}}}}} ,


where 

𝑁

{\displaystyle {\cal {N}}} is a normalization factor. Let us further assume that the initial state is delocalised, i.e. that 

𝜎

𝑟

𝐶

{\displaystyle \sigma \gg r_{C}}. In this case one has


𝜓

𝑎

(

𝑥

)

𝑁

𝑒

(

𝑥

𝑎

)

2

2

𝑟

𝐶

2

{\displaystyle \psi _{a}(x)\simeq {\cal {N}}'e^{-{\frac {(x-a)^{2}}{2r_{C}^{2}}}}},


where 

𝑁

{\displaystyle {\cal {N}}'} is another normalization factor. One thus finds that after the sudden jump has occurred, the initially delocalised wave function has become localized.


Another interesting case is when the initial state is the superposition of two Gaussian states, centered at 

𝑥

=

𝑎

{\displaystyle x=-a} and 

𝑥

=

𝑎

{\displaystyle x=a} respectively: 

𝜓

(

𝑥

)

=

1

2

(

𝜋

𝜎

)

1

4

[

𝑒

(

𝑥

+

𝑎

)

2

2

𝜎

2

+

𝑒

(

𝑥

𝑎

)

2

2

𝜎

2

]

{\displaystyle \psi (x)={\frac {1}{2(\pi \sigma )^{\frac {1}{4}}}}\,\left[e^{-{\frac {(x+a)^{2}}{2\sigma ^{2}}}}+e^{-{\frac {(x-a)^{2}}{2\sigma ^{2}}}}\right]}. If the localization occurs e.g. around 

𝑥

=

𝑎

{\displaystyle x=a} one has


𝜓

𝑎

(

𝑥

)

=

𝑁

𝑒

(

𝑥

𝑎

)

2

2

𝑟

𝐶

2

[

𝑒

(

𝑥

+

𝑎

)

2

2

𝜎

2

+

𝑒

(

𝑥

𝑎

)

2

2

𝜎

2

]

=

𝑁

[

𝑒

𝜎

2

+

𝑟

𝐶

2

2

𝜎

2

𝑟

𝐶

2

(

𝑥

+

𝜎

2

𝑟

𝐶

2

𝜎

2

+

𝑟

𝐶

2

𝑎

)

2

2

𝑎

2

𝜎

2

+

𝑟

𝐶

2

+

𝑒

𝜎

2

+

𝑟

𝐶

2

2

𝜎

2

𝑟

𝐶

2

(

𝑥

𝑎

)

2

]

{\displaystyle \psi _{a}(x)={\cal {N}}e^{-{\frac {(x-a)^{2}}{2r_{C}^{2}}}}\left[e^{-{\frac {(x+a)^{2}}{2\sigma ^{2}}}}+e^{-{\frac {(x-a)^{2}}{2\sigma ^{2}}}}\right]={\cal {N}}\left[e^{-{\frac {\sigma ^{2}+r_{C}^{2}}{2\sigma ^{2}r_{C}^{2}}}\,\left(x+{\frac {\sigma ^{2}-r_{C}^{2}}{\sigma ^{2}+r_{C}^{2}}}a\right)^{2}-{\frac {2a^{2}}{\sigma ^{2}+r_{C}^{2}}}}+e^{-{\frac {\sigma ^{2}+r_{C}^{2}}{2\sigma ^{2}r_{C}^{2}}}\,(x-a)^{2}}\right]}.


If one assumes that  each Gaussian is localized (

𝜎

𝑟

𝐶

{\displaystyle \sigma \ll r_{C}}) and that the overall superposition is delocalised (

2

𝑎

𝑟

𝐶

{\displaystyle 2a\gg r_{C}}), one finds


𝜓

𝑎

(

𝑥

)

𝑁

[

𝑒

(

𝑥

+

𝑎

)

2

2

𝜎

2

2

𝑎

2

𝑟

𝐶

2

+

𝑒

(

𝑥

𝑎

)

2

2

𝜎

2

]

{\displaystyle \psi _{a}(x)\simeq {\cal {N}}'\left[e^{-{\frac {\left(x+a\right)^{2}}{2\sigma ^{2}}}-{\frac {2a^{2}}{r_{C}^{2}}}}+e^{-{\frac {(x-a)^{2}}{2\sigma ^{2}}}}\right]}.


We thus see that the Gaussian that is hit by the localization is left unchanged, while the other is exponentially suppressed.


Amplification mechanism

This is one of the most important features of the GRW theory, because it allows us to recover classical mechanics for macroscopic objects. Let us consider a rigid body of 

𝑁

{\displaystyle N} particles whose statistical operator evolves according to the master equation described above. We introduce the center of mass (

𝑄

^{\displaystyle {\hat {Q}}}) and relative (

𝑟

^

𝑖

{\displaystyle {\hat {r}}_{i}}) position operators, which allow us to rewrite each particle's position operator as follows: 

𝑞

^

𝑖

=

𝑄

^

+

𝑟

^

𝑖

{\displaystyle {\hat {q}}_{i}={\hat {Q}}+{\hat {r}}_{i}}. One can show that, when the system Hamiltonian can be split into a center of mass Hamiltonian 

𝐻

C

M

{\displaystyle H_{\mathrm {CM} }} and a relative Hamiltonian 

𝐻

𝑟

{\displaystyle H_{r}}, the center of mass statistical operator 

𝜌

C

M

{\displaystyle \rho _{\mathrm {CM} }} evolves according to the following master equation:


𝑑

𝑑

𝑡

𝜌

C

M

(

𝑡

)

=

𝑖

[

𝐻

^

C

M

,

𝜌

C

M

(

𝑡

)

]

𝑖

=

1

𝑁

𝜆

𝑖

(

𝜌

C

M

(

𝑡

)

𝑇

^

C

M

[

𝜌

C

M

(

𝑡

)

]

)

{\displaystyle {\frac {d}{dt}}\rho _{\mathrm {CM} }(t)=-{\frac {i}{\hbar }}[{\hat {H}}_{\mathrm {CM} },\rho _{\mathrm {CM} }(t)]-\sum _{i=1}^{N}\lambda _{i}\left(\rho _{\mathrm {CM} }(t)-{\hat {T}}_{\mathrm {CM} }[\rho _{\mathrm {CM} }(t)]\right)},


where


𝑇

^

C

M

[

𝜌

C

M

(

𝑡

)

]

=

(

1

𝜋

𝑟

𝐶

2

)

3

2

𝑑

3

𝑥

𝑒

(

𝑄

^

𝑥

)

2

2

𝑟

𝐶

2

𝜌

C

M

(

𝑡

)

𝑒

(

𝑄

^

𝑥

)

2

2

𝑟

𝐶

2

{\displaystyle {\hat {T}}_{\mathrm {CM} }[\rho _{\mathrm {CM} }(t)]=\left({\frac {1}{\pi r_{C}^{2}}}\right)^{\frac {3}{2}}\int _{\infty }^{\infty }d^{3}x\,e^{-{\frac {({\hat {Q}}-x)^{2}}{2r_{C}^{2}}}}\,\rho _{\mathrm {CM} }(t)\,e^{-{\frac {({\hat {Q}}-x)^{2}}{2r_{C}^{2}}}}}.


One thus sees that the center of mass collapses with a rate 

Λ{\displaystyle \Lambda } that is the sum of the rates of its constituents: this is the amplification mechanism. If for simplicity one assumes that all particles collapse with the same rate 

𝜆{\displaystyle \lambda }, one simply gets 

Λ

=

𝑁

𝜆{\displaystyle \Lambda =N\,\lambda }.


An object that consists of in the order of the Avogadro number of nucleons (

𝑁

10

23

{\displaystyle N\simeq 10^{23}}) collapses almost instantly: GRW's and Adler's values of 

𝜆{\displaystyle \lambda } give respectively 

Λ

=

10

7

s

1

{\displaystyle \Lambda =10^{7}\,\mathrm {s} ^{-1}} and 

Λ

=

10

15

s

1

{\displaystyle \Lambda =10^{15}\,\mathrm {s} ^{-1}}. Fast reduction of macroscopic object superpositions is thus guaranteed, and the GRW theory effectively recovers classical mechanics for macroscopic objects.


Other features

The GRW theory makes different predictions than standard quantum mechanics,[14] and as such can be tested against it (see CSL model).[15]

The collapse noise repeatedly kicks the particles, thus inducing a diffusion process (Brownian motion). This introduces a steady amount of energy in the system, thus leading to a violation of the energy conservation principle. For the GRW model, one can show that energy grows linearly in time with rate 

𝜆

2

/

4

𝑚

𝑟

𝐶

2

{\displaystyle \lambda \hbar ^{2}/4mr_{C}^{2}} , which for a macroscopic object amounts to 

10

14

e

r

g

s

1

{\displaystyle \simeq 10^{-14}\mathrm {erg\,\,s} ^{-1}}. Although such an energy increase is negligible, this feature of the model is not appealing. For this reason, a dissipative extension of the GRW theory has been investigated.[16]

The GRW theory does not allow for identical particles. An extension of the theory with identical particles has been proposed by Tumulka.[17]

GRW is a non relativistic theory, its relativistic extension for non-interacting particles has been investigated by Tumulka,[18] while interacting models are still under investigation.

The master equation of the GRW theory describes a decoherence process according to which the off-diagonal elements of the statistical operator are suppressed exponentially. This is a feature that the GRW theory shares with other collapse theories: those involving white noises are associated to Lindblad master equations,[19] while the coloured QMUPL model follows a non-Markovian Gaussian master equation.[20][21]

See also

Quantum decoherence

Penrose interpretation

Interpretations of quantum mechanics

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