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Zero-point energy, also called quantum vacuum zero-point energy, is the lowest possible energy that a quantum mechanical physical system may have; it is the energy of its ground state. All quantum mechanical systems undergo fluctuations even in their ground state and have an associated zero-point energy, a consequence of their wave-like nature. The uncertainty principle requires every physical system to have a zero-point energy greater than the minimum of its classical potential well. This results in motion even at absolute zero. For example, liquid helium does not freeze under atmospheric pressure at any temperature because of its zero-point energy.

The concept of zero-point energy was developed in Germany by Max Planck in 1911, as a corrective term added to a zero-grounded formula developed in his original quantum theory in 1900^[1]. The term zero-point energy originates from the German Nullpunktsenergie^[2]: 275ff. An alternative form of the German term is Nullpunktenergie (without the s).

Vacuum energy is the zero-point energy of all the fields in space, which in the Standard Model includes the electromagnetic field, other gauge fields, fermionic fields, and the Higgs field. It is the energy of the vacuum, which in quantum field theory is defined not as empty space but as the ground state of the fields. In cosmology, the vacuum energy is one possible explanation for the cosmological constant.^[3] A related term is zero-point field, which is the lowest energy state of a particular field.^[4]

History

In 1900, Max Planck derived the formula for the average energy of a single energy radiator, e.g., a vibrating atomic unit, as a function of absolute temperature :^[5]

${\displaystyle \epsilon ={\frac {h\nu }{e^{h\nu /kT}-1}}}$

where ${\displaystyle h}$ is Planck's constant, ${\displaystyle \nu }$ is the frequency, k is Boltzmann's constant, and T is the absolute temperature.

Starting from 1911 to 1913, in a series of works, he proposed his "second quantum theory", where he introduced the zero-point energy, and only the emitted radiation were in discrete energy quanta, the absorbed radiation could happen continuously. From these ideas, he found the average enery of an oscillator is^{[1]: sec 2 [6]: 235ff}

${\displaystyle \epsilon ={\frac {h\nu }{2}}+{\frac {h\nu }{e^{h\nu /kT}-1}}}$

Soon, the idea of zero-point energy attracted the attention of Albert Einstein and his assistant Otto Stern. They tried to prove the existence of zero-point energy by calculating the specific heat of hydrogen gas and compare with the experimental data. The results were positive. However, after the results were published, they soon retracted the support of the idea because they found Planck's second theory may not apply to their case.^[2]: 270ff>

In 1916 Walther Nernst proposed that empty space was filled with zero-point electromagnetic radiation^{[1]: sec 42}. Then in 1925, the existence of zero-point energy was shown to be “required by quantum mechanics, as a direct consequence of Heisenberg's uncertainty principle” in Werner Heisenberg's famous article "Quantum theoretical re-interpretation of kinematic and mechanical relations".^[7]: 162

Relation to the uncertainty principle

Zero-point energy is fundamentally related to the Heisenberg uncertainty principle.^[8] Roughly speaking, the uncertainty principle states that complementary variables (such as a particle's position and momentum, or a field's value and derivative at a point in space) cannot simultaneously be defined precisely by any given quantum state. In particular, there cannot be a state in which the system sits motionless at the bottom of its potential well, for then its position and momentum would both be completely determined to arbitrarily great precision. Therefore, the lowest-energy state (the ground state) of the system must have a distribution in position and momentum that satisfies the uncertainty principle, which implies its energy must be greater than the minimum of the potential well.

Near the bottom of a potential well, the Hamiltonian of a system (the quantum-mechanical operator giving its energy) can be approximated as

${\displaystyle {\hat {H}}=E_{0}+{\frac {1}{2}}k\left({\hat {x}}-x_{0}\right)^{2}+{\frac {1}{2m}}{\hat {p}}^{2}}$

where ${\displaystyle E_{0}}$ is the minimum of the classical potential well. The uncertainty principle tells us that

${\displaystyle {\sqrt {\left\langle \left({\hat {x}}-x_{0}\right)^{2}\right\rangle }}{\sqrt {\left\langle {\hat {p}}^{2}\right\rangle }}\geq {\frac {\hbar }{2}},}$

making the expectation values of the kinetic and potential terms above satisfy

${\displaystyle \left\langle {\frac {1}{2}}k\left({\hat {x}}-x_{0}\right)^{2}\right\rangle \left\langle {\frac {1}{2m}}{\hat {p}}^{2}\right\rangle \geq \left({\frac {\hbar }{4}}\right)^{2}{\frac {k}{m}}.}$

The expectation value of the energy must therefore be at least

${\displaystyle \left\langle {\hat {H}}\right\rangle \geq E_{0}+{\frac {\hbar }{2}}{\sqrt {\frac {k}{m}}}=E_{0}+{\frac {\hbar \omega }{2}}}$

where ${\displaystyle \omega ={\sqrt {k/m}}}$ is the angular frequency at which the system oscillates.

A more thorough treatment, showing that the energy of the ground state actually is ${\displaystyle E_{0}=\hbar \omega /2,}$ requires solving for the ground state of the system. See quantum harmonic oscillator for details.

Varieties

The concept of zero-point energy occurs in a number of situations.

In ordinary quantum mechanics, the zero-point energy is the energy associated with the ground state of the system. The professional physics literature tends to measure frequency, as denoted by ${\displaystyle \nu }$ above, using angular frequency, denoted with ${\displaystyle \omega }$ and defined by ${\displaystyle \omega }$ = ${\displaystyle 2\pi \nu }$. This leads to a convention of writing Planck's constant ${\displaystyle h}$ with a bar through its top (${\displaystyle \hbar }$) to denote the quantity ${\displaystyle h}$/${\displaystyle 2\pi }$. In those terms, the most famous such example of zero-point energy is ${\displaystyle E={\hbar \omega /2}}$ associated with the ground state of the quantum harmonic oscillator. In quantum mechanical terms, the zero-point energy is the expectation value of the Hamiltonian of the system in the ground state.

In quantum field theory, the fabric of space is visualized as consisting of fields, with the field at every point in space and time being a quantum harmonic oscillator, with neighboring oscillators interacting. In this case, one has a contribution of ${\displaystyle E={\hbar \omega /2}}$ from every point in space, resulting in a calculation of infinite zero-point energy in any finite volume; this is one reason renormalization is needed to make sense of quantum field theories. The zero-point energy is again the expectation value of the Hamiltonian; here, however, the phrase vacuum expectation value is more commonly used, and the energy is called the vacuum energy.

In quantum perturbation theory, it is sometimes said that the contribution of one-loop and multi-loop Feynman diagrams to elementary particle propagators are the contribution of vacuum fluctuations or the zero-point energy to the particle masses.

Experimental observations

A phenomenon that is commonly presented as evidence for the existence of zero-point energy in vacuum is the Casimir effect, proposed in 1948 by Dutch physicist Hendrik B. G. Casimir (Philips Research), who considered the quantized electromagnetic field between a pair of grounded, neutral metal plates. The vacuum energy contains contributions from all wavelengths, except those excluded by the spacing between plates. As the plates draw together, more wavelengths are excluded and the vacuum energy decreases. The decrease in energy means there must be a force doing work on the plates as they move. This force has been measured and found to be in good agreement with the theory. However, there is still some debate on whether vacuum energy is necessary to explain the Casimir effect. Robert Jaffe of MIT argues that the Casimir force should not be considered evidence for vacuum energy, since it can be derived in QED without reference to vacuum energy by considering charge-current interactions (the radiation-reaction picture).^[9]

The experimentally measured Lamb shift has been argued to be, in part, a zero-point energy effect.^[10]

Gravitation and cosmology

Unsolved problem in physics:

Why doesn't the zero-point energy density of the vacuum change with changes in the volume of the universe?^{[citation needed]} And related to that, why doesn't the large constant zero-point energy density of the vacuum cause a large cosmological constant? What cancels it out?

(more unsolved problems in physics)

In cosmology, the zero-point energy offers an intriguing possibility for explaining the speculative positive values of the proposed cosmological constant. ^[11] In brief, if the energy is "really there", then it should exert a gravitational force.^[12] In general relativity, mass and energy are equivalent; both produce a gravitational field. One obvious difficulty with this association is that the zero-point energy of the vacuum is absurdly large. Naively, it is infinite, because it includes the energy of waves with arbitrarily short wavelengths. But since only differences in energy are physically measurable, the infinity can be removed by renormalization. In all practical calculations, this is how the infinity is handled. It is also arguable^{[original research?]} that undiscovered physics relevant at the Planck scale reduces or eliminates the energy of waves shorter than the Planck length, making the total zero-point energy finite.^{[citation needed]}

Utilization controversy

As a scientific concept, the existence of zero-point energy is not controversial. However, the ability to harness zero point energy for useful work is considered pseudoscience by the scientific community at large.^[13][14]

Over the years, there have been numerous claims of devices capable of extracting usable zero-point energy. None of the claims have ever been confirmed by the scientific community, and most of these claims are dismissed by physicists and engineers after third-party inspection of such a device or based on disbelief in the viability of a technical design and theoretical corroboration.^[15]

Science skeptic and writer, Martin Gardner has called claims of such zero-point-energy-based systems, "as hopeless as past efforts to build perpetual motion machines"^[16] Perpetual motion machine refers to technical designs of machines that can operate indefinitely, optionally with additional output of excessive energy, without any cited input source of energy, which is in violation of the laws of thermodynamics. Formally, technical designs that claim to harness zero-point energy would not fall into this category because zero-point energy is claimed as the input source of energy. Despite the scientific stance to typically discount the claims, numerous articles and books have been published addressing and discussing the potential of tapping zero-point-energy from the quantum vacuum or elsewhere. Examples of such are the work of the following authors: Claus Wilhelm Turtur,^[17] Jeane Manning, Joel Garbon,^[18] John Bedini,^[19] Tom Bearden,^[20][21][22] Thomas Valone,^[23][24][25] Moray B King,^[26][27][28] Christopher Toussaint, Bill Jenkins,^[29] Nick Cook^[30] and William James.^[31]

In quantum theory, zero-point energy is a minimum energy below which a thermodynamic system can never go.^[13] Thus, none of this energy can be withdrawn without altering the system to a different form in which the system has a lower zero-point energy. One of the hypotheses that claims that zero-point energy is infinite is stochastic electrodynamics. In it, the zero-point field is viewed as simply a classical background isotropic noise wave field which excites all systems present in the vacuum and thus is responsible for their minimum-energy or "ground" states. The requirement of Lorentz invariance at a statistical level then implies that the energy density spectrum must increase with the third power of frequency, implying infinite energy density when integrated over all frequencies.^[32]

According to a NASA contractor report, "the concept of accessing a significant amount of useful energy from the ZPE gained much credibility when a major article on this topic was published in Aviation Week & Space Technology (1 March 2004), a leading aerospace industry magazine".^[33]

The calculation that underlies the Casimir experiment, a calculation based on the formula predicting infinite vacuum energy, shows the zero-point energy of a system consisting of a vacuum between two plates will decrease at a finite rate as the two plates are drawn together. The vacuum energies are predicted to be infinite, but the changes are predicted to be finite. Casimir combined the projected rate of change in zero-point energy with the principle of conservation of energy to predict a force on the plates. The predicted force, which is very small and was experimentally measured to be within 5% of its predicted value, is finite.^[34] Even though the zero-point energy is theoretically infinite, there is as yet no evidence to suggest that infinite amounts of zero-point energy are available for use, that zero-point energy can be withdrawn for free, or that zero-point energy can be used in violation of conservation of energy.^[35]

In the contrary of energy generation, a field of study where there is a somewhat realistic potential for the utilization of zero-point energy might be in the design of extremely small scale devices like MEMS and NEMS or in distant futuristic propulsion technology of extremely long-distance space-travel.^[13]

A document released by the NGIC shows there is ongoing worldwide research into zero-point energy, particular in China, Germany, Russia and Brazil. An analyst of the Defense Intelligence Agency has indicated that research into successfully harnessing zero-point energy for energy generation purposes is a serious concern inside the intelligence community.^[13]

In popular culture

"Zero point energy" has been invoked in science fiction movies and video games, often as an explanation for "impossible" technology that provides free energy or otherwise contradicts known laws of physics. In 1986, Arthur C. Clarke published a science fiction novel called The Songs of Distant Earth which depicts a starship called Magellan that is powered by the quantum vacuum zero point energy.

In Disney/Pixar's animated film The Incredibles, the main villain Syndrome refers to his weapons as using zero-point energy.^[36][37] The fan fiction community devoted to the character is named "Zero Point" because of this.^[38]

In the critically acclaimed game from Valve Corporation, Half-Life 2, a "zero-point energy field manipulator" (popularly known as a "gravity gun"), meant to handle sensitive, anomalous and hazardous materials, is used as both a weapon to throw objects at enemies in high speeds, as a primary attack, and a tool to solve physics puzzles consisting in moving objects of considerable weight.

In Nintendo's Star Fox series, there are mentions of a "G-Diffusion" system. The so-called G-diffusion is an experimental power system used in the game's starfighters that reduces gravity forces on the pilot and provides a respectable power source for shields and propulsion, using advanced zero-point energy technology.^{[citation needed]}

In the webcomic Schlock Mercenary, a major running plot-point centers around an enormous zero-point energy generator built from the super massive black hole comprising the core Milky Way Galaxy.

In the popular science-fiction programs generally labeled under Stargate SG-1, the intergalactic colonists visiting Atlantis often refer to and make use of "ZPMs" shortened from "Zero-Point Modules." Although fantastically powerful in terms of available energy density, these fictional energy sources still dissipate over time.

The 2006 James Rollins novel Black Order discusses suspected zero-point energy research by the German military during the Second World War.

Notes

1. Kragh, Helge (2012). "Preludes to dark energy: zero-point energy and vacuum speculations". Archive for History of Exact Sciences. 66 (3). Springer-Verlag: pp 199-240. doi:10.1007/s00407-011-0092-3. {{cite journal}}: |pages= has extra text (help)
2. Albert Einstein (1995). Martin J. Klein; et al. (eds.). The Collected Papers of Albert Einstein, Volume 4: The Swiss Years: Writings, 1912-1914. Princeton University Press. ISBN 9780691037059. {{cite book}}: Explicit use of et al. in: |editor2= (help)
3. Rugh, S. E.; Zinkernagel, H. (2002). "The Quantum Vacuum and the Cosmological Constant Problem". Studies in History and Philosophy of Modern Physics, vol. 33 (4): 663–705. arXiv:hep-th/0012253. doi:10.1016/S1355-2198(02)00033-3.
4. Gribbin, J. (1998). Q is for Quantum: An Encyclopedia of Particle Physics. Touchstone Books. ISBN 0-684-86315-4.
5. Planck, M (1900). "Zur Theorie des Gesetzes der Energieverteilung im Normalspektrum". Verhandlungen der Deutschen Physikalischen Gesellschaft. 2: 237–245.
6. Thomas S. Kuhn. Black-Body Theory and the Quantum Discontinuity, 1894-1912. University of Chicago Press. ISBN 978-0-226-45800-7.
7. Kragh, Helge (2002). Quantum Generations: A History of Physics in the Twentieth Century (Reprint ed.). Princeton University Press. ISBN 978-0691095523.
8. W. Heisenberg (1927). [Original work as HTML "Über den anschaulichen Inhalt der quantentheoretischen Kinematik und Mechanik"]. Zeitschrift für Physik. 43 (3): 172–198. Bibcode:1927ZPhy...43..172H. doi:10.1007/BF01397280. {{cite journal}}: Check |url= value (help)
9. Jaffe, R. L. (2005). "Casimir effect and the quantum vacuum". Physical Review D. 72 (2): 021301. arXiv:hep-th/0503158. Bibcode:2005PhRvD..72b1301J. doi:10.1103/PhysRevD.72.021301.
10. Hawton, M. (1993). "Self-consistent frequencies of the electron-photon system". Physical Review A. 48 (3): 1824. Bibcode:1993PhRvA..48.1824H. doi:10.1103/PhysRevA.48.1824.
11. Tarkowski, W. (2004). "A Toy Model of the Five-Dimensional Universe with the Cosmological Constant". International Journal of Modern Physics A. 19 (29): 5051. arXiv:gr-qc/0407024. Bibcode:2004IJMPA..19.5051T. doi:10.1142/S0217751X04019366.
12. Zee, A. (2008). "Gravity and Its Mysteries: Some Thoughts and Speculations" (PDF). AAPPS Bulletin. 18 (4): 32.
13. Amber M. Aiken, Ph.D. "Zero-Point Energy: Can We Get Something From Nothing?" (PDF). U.S. Army National Ground Intelligence Center. Forays into "free energy" inventions and perpetual-motion machines using ZPE are considered by the broader scientific community to be pseudoscience.
14. "老陳/sandbox1, on season 8 , episode 2". Scientific American Frontiers. Chedd-Angier Production Company. 1997–1998. PBS. Archived from the original on 2006-01-01.
15. Matt Visser (3 October 1996). "What is the 'zero-point energy' (or 'vacuum energy') in quantum physics? Is it really possible that we could harness this energy?". Phlogistin / Scientific American Magazine. Archived from the original on August 18, 1997. Retrieved 31 May 2013.
16. Martin Gardner, "'Dr' Bearden's Vacuum Energy", Skeptical Inquirer, January/February 2007
17. Claus Wilhelm Turtur. Conversion of the zero-point energy of the quantum vacuum into classical mechanical energy (PDF). Bremen Europ. Hochsch.-Verl. Archived from the original on 2010. {{cite book}}: Check date values in: |archivedate= (help)
18. Jeane Manning, Joel Garbon. Breakthrough power : how quantum-leap new energy inventions can transform our world. Amber Bridge Books.
19. John Bedini, Tom Bearden. Free energy generation : circuits & schematics. Cheniere Press.
20. Tom Bearden. Energy from the vacuum : concepts & principles. Cheniere Press.
21. Tom Bearden. Clash of the geniuses : inventing the impossible. New Science Ideas.
22. Tom Bearden. Virtual State Engineering and Its Implications. Ft. Belvoir Defense Technical Information Center.
23. Thomas Valone. Practical conversion of zero-point energy : feasibility study of the extraction of zero-point energy from the quantum vacuum for the performance of useful work. Integrity Research Institute.
24. Thomas Valone. Zero point energy : the fuel of the future. Integrity Research Institute.
25. Thomas Valone. Future energy : proceedings of the First International Conference on Future Energy. Integrity Research Institute.
26. Moray B King. Tapping the zero-point energy : how free energy and anti-gravity might be possible with today's physics. Adventures Unlimited.
27. Moray B King. Quest for zero point energy : engineering principles for 'free energy' inventions. Adventures Unlimited.
28. Moray B King. The energy machine of T. Henry Moray : zero-point energy & pulsed plasma physics. Adventures Unlimited.
29. Christopher Toussaint, Bill Jenkins. Free energy : the race to zero point. Lightworks Audio & Video.
30. Nick Cook. The hunt for zero point : inside the classified world of antigravity technology. Broadway Books.
31. William James. Zero point : power of the gods. Bloomington.
32. de la Peña, L.; Cetto, A. M. (1995). The Quantum Dice: An Introduction to Stochastic Electrodynamics. ISBN 978-0-7923-3818-5.
33. Advanced Energetics for Aeronautical Applications: Volume II (PDF). NASA.
34. "What is the Casimir Effect?".
35. "FOLLOW-UP: What is the 'zero-point energy' (or 'vacuum energy') in quantum physics? Is it really possible that we could harness this energy?". Scientific American. 18 August 1997.
36. "Buddy Pine character profile". Retrieved 5 September 2012.
37. "Zero Point Energy". Retrieved 5 September 2012.
38. "Zero Point at FanFiction.net". Retrieved 5 September 2012.

Bibliography

• Beiser, A. (1967). Concepts of Modern Physics. McGraw-Hill. ISBN 0-07-004473-2.
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• Einstein, A.; Hopf, L. (1910). "Statistical investigation of a resonator' s motion in a radiation field". Annalen der Physik. 33 (16): 1105–1115. Bibcode:1910AnP...338.1105E. doi:10.1002/andp.19103381604.
• Einstein, A.; Stern, O. (1913). "Einige Argumente für die Annahme einer molekularen Agitation beim absoluten Nullpunkt". Annalen der Physik. 40 (3): 551. Bibcode:1913AnP...345..551E. doi:10.1002/andp.19133450309.
• Haisch, B.; Rueda, A.; Dobyns, Y. (2001). "Inertial mass and the quantum vacuum fields" (PDF). Annalen der Physik. 10 (5): 393–414. arXiv:gr-qc/0009036. Bibcode:2001AnP...513..393H. doi:10.1002/1521-3889(200105)10:5<393::AID-ANDP393>3.0.CO;2-Z.
• Loudon, R. (2000). The Quantum Theory of Light (3rd ed.). Clarendon Press. ISBN 0-19-850176-5.
• Milonni, P. W. (1994). The Quantum Vacuum: An Introduction to Quantum Electrodynamics. Academic Press. ISBN 0-12-498080-5.
• Nernst, W. (1916). "Über einen Versuch, von quantentheoretischen Betrachtungen zur Annahme stetiger Energieänderungen zurückzukehren". Verhandlungen der Deutschen Physikalischen Gesellschaft. 18: 83.
• Sciama, D. W. (1991). Saunders, S.; Brown, H. R. (eds.). The Philosophy of Vacuum. Clarendon Press. ISBN 0-19-824449-5.
• Rafelski, J.; Muller, B. (1985). The Structured Vacuum: Thinking about nothing (PDF). Harri Deutsch. ISBN 3-87144-889-3.
• Boyer, T. H. (1968). "Quantum Electromagnetic Zero-Point Energy of a Conducting Spherical Shell and the Casimir Model for a Charged Particle" (PDF). Physical Review. 174 (5): 13. Bibcode:1968PhRv..174.1764B. doi:10.1103/PhysRev.174.1764.
• Yablonovitch, E. (1989). "Accelerating Reference Frame for Electromagnetic Waves in a Rapidly Growing Plasma: Unruh-Davies-Fulling-DeWitt Radiation and the Nonadiabatic Casimir Effect" (PDF). Physical Review Letters. 62 (15): 1742–1745. Bibcode:1989PhRvL..62.1742Y. doi:10.1103/PhysRevLett.62.1742. PMID 10039756.

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