Back action (quantum)

Last updated March 24, 2024

Introduction (error in measurement)

Back Action in quantum mechanics is the phenomenon in which the act of measuring a property of a particle directly influences the state of the particle. In all scientific measurement, there exists a degree of error due to a variety of factors. This could include unaccounted-for variables, imperfect procedure execution, or imperfect measurement devices. In classical mechanics, it is assumed that the error of any experiment could theoretically be zero if all relevant aspects of the configuration are known and the measurement devices are perfect. However, quantum mechanical theory supports that the act of measuring a quantity, regardless of the degree of precision, carries inherent uncertainty as the measurement influences the quantity itself.^[1]^[2] This behavior is known as back action. This is due to the fact that quantum uncertainty carries minimum fluctuations as a probability. For example, even objects at absolute zero still carry ‘motion’ due to such fluctuations.^[3]

Simultaneous measurement & uncertainty

Simultaneous measurement is not possible in quantum mechanics for observables that do not commute (the commutator of the observables is not equal to zero). Since observable quantities are treated as operators, their values do not necessarily follow classical algebraic properties. For this reason, there always remains a minimum uncertainty in regard to the uncertainty principle. This relationship sets a minimum uncertainty when measuring position and momentum. However, it can be extended to any incompatible observables.^[4]

$\sigma _{x}\sigma _{p}\geq \hbar /2$

$\sigma _{A}^{2}\sigma _{B}^{2}\geq |\left({\frac {1}{2i}}\right)\langle [{\hat {A}},{\hat {B}}]\rangle |^{2}$

Effect of measurement on system

Each observable operator has a set of eigenstates, each with an eigenvalue. The full initial state of a system is a linear combination of the full set of its eigenstates. Upon measurement, the state then collapses to an eigenstate with a given probability and will proceed to evolve over time after measurement.^[4] Thus, measuring a system affects its future behavior and will thus affect further measurements of non-commuting observables.

Using bra-ket notation, consider a given system that begins in a state $|\psi \rangle$ , and an observable operator ${\hat {O}}$ with the set of eigenstates $\{|\omega _{i}\rangle \}$ each with a corresponding eigenvalue $\lambda _{i}$ . A measurement of ${\hat {O}}$ is made, and the probability of getting $\lambda _{i}$ is as follows:

$P(\lambda _{i})=|\langle \omega _{i}|\psi \rangle |^{2}$

The particle's state has now collapsed to the state $|\omega _{i}\rangle$ . Now, consider another observable ${\hat {B}}$ with the set of eigenstates $\{|\varphi _{i}\rangle \}$ each with a corresponding eigenvalue $b_{i}$ . If a subsequent measurement of ${\hat {B}}$ on the system is made, the possible outcomes are now $\{b_{i}\}$ , each with the following probability:

$P(b_{i})=|\langle \varphi _{i}|\omega _{i}\rangle |^{2}$

Had ${\hat {O}}$ not been measured first, the probability of each outcome would have remained as:

$P(b_{i})=|\langle \varphi _{i}|\psi \rangle |^{2}$

Thus, unless ${\hat {B}}$ and ${\hat {O}}$ share and identical set of eigenstates (that is to say, $\{|\varphi _{i}\rangle \}=\{|\omega _{i}\rangle \}$ ), the initial measurement fundamentally influences the system to affect future measurements. This statement is identical to stating that if the commutator of the two observables is non-zero, repeated observations of the observables will present altered results. Observables will share the set of eigenstates if^[4]

$[{\hat {O}},{\hat {B}}]=0$

Back action is an area of active research. Recent experiments with nanomechanical systems have attempted to evade back action while making measurements.^[5]^[6]

Related Research Articles

The mathematical formulations of quantum mechanics are those mathematical formalisms that permit a rigorous description of quantum mechanics. This mathematical formalism uses mainly a part of functional analysis, especially Hilbert spaces, which are a kind of linear space. Such are distinguished from mathematical formalisms for physics theories developed prior to the early 1900s by the use of abstract mathematical structures, such as infinite-dimensional Hilbert spaces, and operators on these spaces. In brief, values of physical observables such as energy and momentum were no longer considered as values of functions on phase space, but as eigenvalues; more precisely as spectral values of linear operators in Hilbert space.

The uncertainty principle, also known as Heisenberg's indeterminacy principle, is a fundamental concept in quantum mechanics. It states that there is a limit to the precision with which certain pairs of physical properties, such as position and momentum, can be simultaneously known. In other words, the more accurately one property is measured, the less accurately the other property can be known.

<span class="mw-page-title-main">Quantum harmonic oscillator</span> Important, well-understood quantum mechanical model

The quantum harmonic oscillator is the quantum-mechanical analog of the classical harmonic oscillator. Because an arbitrary smooth potential can usually be approximated as a harmonic potential at the vicinity of a stable equilibrium point, it is one of the most important model systems in quantum mechanics. Furthermore, it is one of the few quantum-mechanical systems for which an exact, analytical solution is known.

The Schrödinger equation is a linear partial differential equation that governs the wave function of a quantum-mechanical system. Its discovery was a significant landmark in the development of quantum mechanics. It is named after Erwin Schrödinger, who postulated the equation in 1925 and published it in 1926, forming the basis for the work that resulted in his Nobel Prize in Physics in 1933.

In quantum mechanics, a density matrix is a matrix that describes the quantum state of a physical system. It allows for the calculation of the probabilities of the outcomes of any measurement performed upon this system, using the Born rule. It is a generalization of the more usual state vectors or wavefunctions: while those can only represent pure states, density matrices can also represent mixed states. Mixed states arise in quantum mechanics in two different situations:

when the preparation of the system is not fully known, and thus one must deal with a statistical ensemble of possible preparations, and
when one wants to describe a physical system that is entangled with another, without describing their combined state; this case is typical for a system interacting with some environment.

In quantum mechanics, wave function collapse occurs when a wave function—initially in a superposition of several eigenstates—reduces to a single eigenstate due to interaction with the external world. This interaction is called an observation, and is the essence of a measurement in quantum mechanics, which connects the wave function with classical observables such as position and momentum. Collapse is one of the two processes by which quantum systems evolve in time; the other is the continuous evolution governed by the Schrödinger equation.

<span class="mw-page-title-main">Wave function</span> Mathematical description of the quantum state of a system

In quantum physics, a wave function is a mathematical description of the quantum state of an isolated quantum system. The most common symbols for a wave function are the Greek letters $ψ$ and $Ψ$ . Wave functions are complex-valued. For example, a wave function might assign a complex number to each point in a region of space. The Born rule provides the means to turn these complex probability amplitudes into actual probabilities. In one common form, it says that the squared modulus of a wave function that depends upon position is the probability density of measuring a particle as being at a given place. The integral of a wavefunction's squared modulus over all the system's degrees of freedom must be equal to 1, a condition called normalization. Since the wave function is complex-valued, only its relative phase and relative magnitude can be measured; its value does not, in isolation, tell anything about the magnitudes or directions of measurable observables. One has to apply quantum operators, whose eigenvalues correspond to sets of possible results of measurements, to the wave function $ψ$ and calculate the statistical distributions for measurable quantities.

In physics, specifically in quantum mechanics, a coherent state is the specific quantum state of the quantum harmonic oscillator, often described as a state that has dynamics most closely resembling the oscillatory behavior of a classical harmonic oscillator. It was the first example of quantum dynamics when Erwin Schrödinger derived it in 1926, while searching for solutions of the Schrödinger equation that satisfy the correspondence principle. The quantum harmonic oscillator arise in the quantum theory of a wide range of physical systems. For instance, a coherent state describes the oscillating motion of a particle confined in a quadratic potential well. The coherent state describes a state in a system for which the ground-state wavepacket is displaced from the origin of the system. This state can be related to classical solutions by a particle oscillating with an amplitude equivalent to the displacement.

In physics, an operator is a function over a space of physical states onto another space of physical states. The simplest example of the utility of operators is the study of symmetry. Because of this, they are useful tools in classical mechanics. Operators are even more important in quantum mechanics, where they form an intrinsic part of the formulation of the theory.

In quantum mechanics, a probability amplitude is a complex number used for describing the behaviour of systems. The square of the modulus of this quantity represents a probability density.

In physics, the Rabi cycle is the cyclic behaviour of a two-level quantum system in the presence of an oscillatory driving field. A great variety of physical processes belonging to the areas of quantum computing, condensed matter, atomic and molecular physics, and nuclear and particle physics can be conveniently studied in terms of two-level quantum mechanical systems, and exhibit Rabi flopping when coupled to an optical driving field. The effect is important in quantum optics, magnetic resonance and quantum computing, and is named after Isidor Isaac Rabi.

In quantum mechanics, a complete set of commuting observables (CSCO) is a set of commuting operators whose common eigenvectors can be used as a basis to express any quantum state. In the case of operators with discrete spectra, a CSCO is a set of commuting observables whose simultaneous eigenspaces span the Hilbert space, so that the eigenvectors are uniquely specified by the corresponding sets of eigenvalues.

In quantum mechanics, an energy level is degenerate if it corresponds to two or more different measurable states of a quantum system. Conversely, two or more different states of a quantum mechanical system are said to be degenerate if they give the same value of energy upon measurement. The number of different states corresponding to a particular energy level is known as the degree of degeneracy of the level. It is represented mathematically by the Hamiltonian for the system having more than one linearly independent eigenstate with the same energy eigenvalue. When this is the case, energy alone is not enough to characterize what state the system is in, and other quantum numbers are needed to characterize the exact state when distinction is desired. In classical mechanics, this can be understood in terms of different possible trajectories corresponding to the same energy.

The Born rule is a postulate of quantum mechanics that gives the probability that a measurement of a quantum system will yield a given result. In its simplest form, it states that the probability density of finding a system in a given state, when measured, is proportional to the square of the amplitude of the system's wavefunction at that state. It was formulated and published by German physicist Max Born in July, 1926.

Photon polarization is the quantum mechanical description of the classical polarized sinusoidal plane electromagnetic wave. An individual photon can be described as having right or left circular polarization, or a superposition of the two. Equivalently, a photon can be described as having horizontal or vertical linear polarization, or a superposition of the two.

In quantum physics, unitarity is the condition that the time evolution of a quantum state according to the Schrödinger equation is mathematically represented by a unitary operator. This is typically taken as an axiom or basic postulate of quantum mechanics, while generalizations of or departures from unitarity are part of speculations about theories that may go beyond quantum mechanics. A unitarity bound is any inequality that follows from the unitarity of the evolution operator, i.e. from the statement that time evolution preserves inner products in Hilbert space.

In quantum mechanics, the expectation value is the probabilistic expected value of the result (measurement) of an experiment. It can be thought of as an average of all the possible outcomes of a measurement as weighted by their likelihood, and as such it is not the most probable value of a measurement; indeed the expectation value may have zero probability of occurring. It is a fundamental concept in all areas of quantum physics.

In quantum mechanics, the eigenvalue $of an observable is said to be a good quantum number if the observable is a constant of motion. In other words, the quantum number is good if the corresponding observable commutes with the Hamiltonian. If the system starts from the eigenstate with an eigenvalue, it remains on that state as the system evolves in time, and the measurement of always yields the same eigenvalue .$

In quantum physics, a quantum state is a mathematical entity that embodies the knowledge of a quantum system. Quantum mechanics specifies the construction, evolution, and measurement of a quantum state. The result is a quantum-mechanical prediction for the system represented by the state. Knowledge of the quantum state, and the quantum mechanical rules for the system's evolution in time, exhausts all that can be known about a quantum system.

This is a glossary for the terminology often encountered in undergraduate quantum mechanics courses.

References

↑ Braginskij, Vladimir B.; Khalili, Farid Y. (2010). Thorne, Kip S. (ed.). Quantum measurement (Transferred to digit. print., [Nachdr.] ed.). Cambridge: Cambridge Univ. Pr. ISBN 978-0-521-48413-8.
↑ Hatridge, M.; Shankar, S.; Mirrahimi, M.; Schackert, F.; Geerlings, K.; Brecht, T.; Sliwa, K. M.; Abdo, B.; Frunzio, L.; Girvin, S. M.; Schoelkopf, R. J.; Devoret, M. H. (2013-01-11). "Quantum Back-Action of an Individual Variable-Strength Measurement". Science. 339 (6116): 178–181. arXiv: 1903.11732 . doi:10.1126/science.1226897. ISSN 0036-8075.
↑ "Quantum Backaction - Open Quantum Sensing and Measurement Notes". qsm.quantumtinkerer.tudelft.nl. Retrieved 2023-11-01.
1 2 3 Griffiths, David (2005). Introduction to Quantum Mechanics (2nd ed.). United States of America: Pearson Education Inc. ISBN 0131911759.
↑ Hertzberg, J. B.; Rocheleau, T.; Ndukum, T.; Savva, M.; Clerk, A. A.; Schwab, K. C. (March 2010). "Back-action-evading measurements of nanomechanical motion". Nature Physics. 6 (3): 213–217. arXiv: 0906.0967 . doi:10.1038/nphys1479. ISSN 1745-2473.
↑ Møller, Christoffer B.; Thomas, Rodrigo A.; Vasilakis, Georgios; Zeuthen, Emil; Tsaturyan, Yeghishe; Balabas, Mikhail; Jensen, Kasper; Schliesser, Albert; Hammerer, Klemens; Polzik, Eugene S. (July 2017). "Quantum back-action-evading measurement of motion in a negative mass reference frame". Nature. 547 (7662): 191–195. arXiv: 1608.03613 . doi:10.1038/nature22980. ISSN 0028-0836.

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[1] Braginskij, Vladimir B.; Khalili, Farid Y. (2010). Thorne, Kip S. (ed.). Quantum measurement (Transferred to digit. print., [Nachdr.] ed.). Cambridge: Cambridge Univ. Pr. ISBN 978-0-521-48413-8.

[2] Hatridge, M.; Shankar, S.; Mirrahimi, M.; Schackert, F.; Geerlings, K.; Brecht, T.; Sliwa, K. M.; Abdo, B.; Frunzio, L.; Girvin, S. M.; Schoelkopf, R. J.; Devoret, M. H. (2013-01-11). "Quantum Back-Action of an Individual Variable-Strength Measurement". Science. 339 (6116): 178–181. arXiv: 1903.11732 . doi:10.1126/science.1226897. ISSN 0036-8075.

[3] "Quantum Backaction - Open Quantum Sensing and Measurement Notes". qsm.quantumtinkerer.tudelft.nl. Retrieved 2023-11-01.

[:0-4] 1 2 3 Griffiths, David (2005). Introduction to Quantum Mechanics (2nd ed.). United States of America: Pearson Education Inc. ISBN 0131911759.

[5] Hertzberg, J. B.; Rocheleau, T.; Ndukum, T.; Savva, M.; Clerk, A. A.; Schwab, K. C. (March 2010). "Back-action-evading measurements of nanomechanical motion". Nature Physics. 6 (3): 213–217. arXiv: 0906.0967 . doi:10.1038/nphys1479. ISSN 1745-2473.

[6] Møller, Christoffer B.; Thomas, Rodrigo A.; Vasilakis, Georgios; Zeuthen, Emil; Tsaturyan, Yeghishe; Balabas, Mikhail; Jensen, Kasper; Schliesser, Albert; Hammerer, Klemens; Polzik, Eugene S. (July 2017). "Quantum back-action-evading measurement of motion in a negative mass reference frame". Nature. 547 (7662): 191–195. arXiv: 1608.03613 . doi:10.1038/nature22980. ISSN 0028-0836.

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