Higgs boson

Higgs boson

Composition	Elementary particle
Family	Boson
Status	Hypothetical
Theorized	F. Englert, R. Brout, P. Higgs, G. S. Guralnik, C. R. Hagen, and T. W. B. Kibble 1964
Spin	0

In particle physics, the Higgs boson is a massive scalar elementary particle predicted to exist by the Standard Model.

The Higgs boson is the only Standard Model particle yet to be observed. Experimental detection of the Higgs boson would help to explain how massless elementary particles can cause matter to have mass. More specifically, the Higgs boson would explain the difference between the massless photon, which mediates electromagnetism, and the relatively massive W and Z bosons, which mediate the weak force. If the Higgs boson exists, it would be an integral and pervasive component of the material world.

The Large Hadron Collider (LHC) at CERN, which came online on September 10, 2008 and will become fully operational in 2009, is expected to provide experimental evidence confirming or refuting the Higgs boson's existence.

Origin

The Higgs mechanism, which gives mass to vector bosons, was theorized in 1964 by François Englert and Robert Brout ("boson scalaire");^[1] in October of the same year by Peter Higgs,^[2] working from the ideas of Philip Anderson; and independently by Gerald Guralnik, C. R. Hagen, and Tom Kibble,^[3] who worked out the results by the spring of 1963.^[4] The three papers written on this discovery by Guralnik, Hagen, Kibble, Higgs, Brout, and Englert were each recognized as milestone papers during Physical Review Letters 50th anniversary celebration.^[5] Steven Weinberg and Abdus Salam were the first to apply the Higgs mechanism to the electroweak symmetry breaking. The electroweak theory predicts a neutral particle whose mass is not far from that of the W and Z bosons.

Theoretical overview

A one-loop Feynman diagram of the first-order correction to the Higgs mass. The Higgs boson couples strongly to the top quark so it may decay into top anti-top quark pairs.

The Higgs boson particle is one quantum component of the theoretical Higgs field. In empty space, the Higgs field has an amplitude different from zero, i.e., a non-zero vacuum expectation value. The existence of this non-zero vacuum expectation plays a fundamental role: it gives mass to every elementary particle which should have mass, including the Higgs boson itself. In particular, the acquisition of a non-zero vacuum expectation value spontaneously breaks electroweak gauge symmetry, which scientists often refer to as the Higgs mechanism. This is the simplest mechanism capable of giving mass to the gauge bosons while remaining compatible with gauge theories. In essence, this field is analogous to a pool of molasses that "sticks" to the otherwise massless fundamental particles which travel through the field, converting them into particles with mass which form, for example, the components of atoms.

In the Standard Model, the Higgs field consists of two neutral and two charged component fields. Both of the charged components and one of the neutral fields are Goldstone bosons, which act as the longitudinal third-polarization components of the massive W⁺, W^–, and Z bosons. The quantum of the remaining neutral component corresponds to the massive Higgs boson. Since the Higgs field is a scalar field, the Higgs boson has no spin, hence no intrinsic angular momentum. The Higgs boson is also its own antiparticle and is CP-even.

The Standard Model does not predict the mass of the Higgs boson. If that mass is between 115 and 180 GeV/c², then the Standard Model can be valid at energy scales all the way up to the Planck scale (10¹⁶ TeV). Many theorists expect new physics beyond the Standard Model to emerge at the TeV-scale, based on unsatisfactory properties of the Standard Model. The highest possible mass scale allowed for the Higgs boson (or some other electroweak symmetry breaking mechanism) is around one TeV; beyond this point, the Standard Model becomes inconsistent without such a mechanism because unitarity is violated in certain scattering processes. Many models of Supersymmetry predict that the lightest Higgs boson (of several) will have a mass only slightly above the current experimental limits, at around 120 GeV or less.

Experimental search

A Feynman diagram of one way the Higgs boson may be produced at the LHC. Here, two gluons decay into a top/anti-top pair which then combine to make a neutral Higgs.

As of early 2009, the Higgs boson has yet to be observed experimentally, despite large efforts invested in accelerator experiments at CERN and Fermilab. This nonobservation suggests an experimental lower bound for the mass of the Standard Model Higgs boson of 114 GeV/c² at 95% confidence level. Experiments at the LEP collider at CERN have recorded a small number of events that could be interpreted as resulting from Higgs bosons, but the evidence is inconclusive.^[6] The Large Hadron Collider (LHC), due to begin proper experimentation in 2009 after initial calibration, is expected to be able to confirm or reject the existence of the Higgs boson. Full operational mode has been delayed by about 2 months, because of problems discovered with a number of magnets during the calibration and startup phase.

At the Fermilab Tevatron, there are ongoing experiments searching for the Higgs boson. As of August 2008, combined data from CDF and D0 experiments at the Tevatron were finally sufficient to exclude the Higgs boson at 170 GeV/c² at the 95% confidence level.^[7] Continued data collection is aimed at raising this lower bound.

It may be possible to estimate the mass of the Higgs Boson indirectly. In the Standard Model, the Higgs has a number of indirect effects; most notably, Higgs loops result in tiny corrections to W and Z masses. Precision measurements of electroweak parameters, such as Fermi constant and masses of W/Z bosons, can be used to constrain the mass of the Higgs. Current estimates exclude a Standard Model Higgs boson having a mass greater than 285 GeV/c² at 95% CL, and estimate its mass to be 129+74
−49 GeV/c².^[8] (138 proton masses)

Some have argued that there exists potential evidence of the Higgs Boson,^[9][10] but to date no such evidence has convinced the physics community.

Alternatives to the Higgs mechanism for electroweak symmetry breaking

Main article: Higgsless model

In the years since the Higgs boson was proposed, several alternatives to the Higgs mechanism have been proposed. All of the alternative mechanisms use strongly interacting dynamics to produce a vacuum expectation value that breaks electroweak symmetry. A partial list of these alternative mechanisms are

• Technicolor^[11] is a class of models that attempts to mimic the dynamics of the strong force as a way of breaking electroweak symmetry.
• Abbott-Farhi models of composite W and Z vector bosons.^[12]
• Top quark condensate

Popular culture

Main article: Higgs boson in fiction

The Higgs boson is frequently referred to as "the God particle," after the title of Leon Lederman's book for lay readers.^[13]

See also

• Higgs mechanism
• List of particles
• Standard Model
• Yukawa interaction
• ZZ diboson

Notes

1. François Englert and Robert Brout, 1964, "Broken Symmetry and the Mass of Gauge Vector Mesons," Phys. Rev. Lett. 13: 321-23.
2. Peter Higgs, 1964, " Broken Symmetries and the Masses of Gauge Bosons,"Phys. Rev. Lett. 13: 508-09.
3. Gerald Guralnik, C. R. Hagen, and T. W. B. Kibble, 1964, "Global Conservation Laws and Massless Particles," Phys. Rev. Let. 13: 585-87.
4. Gerald Guralnik, 2001, "A Physics History of My Part in the Theory of Spontaneous Symmetry Breaking and Gauge particles," Text of talk presented at a Colloquium at St. Louis University.
5. Physical Review Letters - 50th Anniversary Milestone Papers
6. "Searches for Higgs Bosons (pdf)]" from W.-M. Yao; et al. (2006). "Review of Particle Physics". J Phys. G. 33: 1. doi:10.1088/0954-3899/33/1/001. {{cite journal}}: Explicit use of et al. in: |author= (help)
7. "Tevatron experiments double-team Higgs boson".
8. "H⁰ Indirect Mass Limits from Electroweak Analysis."
9. Potential Higgs Boson discovery: "Higgs Boson: Glimpses of the God particle."
10. "'God particle' may have been seen," BBC news.
11. S. Dimopoulos and Leonard Susskind (1979). "Mass Without Scalars". Nucl.Phys.B. 155: 237–252. doi:10.1016/0550-3213(79)90364-X.
12. L. F. Abbott and E. Farhi (1981). "Are the Weak Interactions Strong?". Phys.Lett.B. 101: 69. doi:10.1016/0370-2693(81)90492-5.
13. Leon Lederman, 1993. The God Particle: If the Universe Is the Answer, What Is the Question? New York: Dell.

References

• "The LEP Electroweak Working Group."
• "Particle Data Group: Review of searches for Higgs bosons."
• Leon Lederman and Dick Teresi, 1993. The God Particle: If the Universe Is the Answer, What Is the Question? Houghton Mifflin Co.. ISBN 0-395-55849-2, paperback ISBN 0-385-31211-3.
• "Fermilab Results Change Estimated Mass Of Postulated Higgs boson."
• "Higgs boson on the horizon."
• "Signs of mass-giving particle get stronger."
• "Higgs boson: One page explanation." In 1993, the UK Science Minister, William Waldegrave, challenged physicists to produce a one page answer to the question "What is the Higgs boson, and why do we want to find it?"
• "Higgs mechanism/boson simple explanation via cartoon."
• "Higgs physics at the LHC."
• "Quark experiment predicts heavier Higgs."
• Martin, Richard, "The God Particle and the Grid."
• "The Higgs boson" by the CERN exploratorium.
• "Higgs Boson - the search for the God particle." BBC Radio 4: "In Our Time"

Further reading

• G S Guralnik, C R Hagen and T W B Kibble (1964). "Global Conservation Laws and Massless Particles". Physical Review Letters. 13: 585. doi:10.1103/PhysRevLett.13.585.
• F Englert and R Brout (1964). "Broken Symmetry and the Mass of Gauge Vector Mesons". Physical Review Letters. 13: 321. doi:10.1103/PhysRevLett.13.321.
• Peter Higgs (1964). "Broken Symmetries, Massless Particles and Gauge Fields". Physics Letters. 12: 132. doi:10.1016/0031-9163(64)91136-9.
• Peter Higgs (1964). "Broken Symmetries and the Masses of Gauge Bosons". Physical Review Letters. 13: 508. doi:10.1103/PhysRevLett.13.508.
• Peter Higgs (1966). "Spontaneous Symmetry Breakdown without Massless Bosons". Physical Review. 145: 1156. doi:10.1103/PhysRev.145.1156.
• Y Nambu; G Jona-Lasinio (1961). "Dynamical Model of Elementary Particles Based on an Analogy with Superconductivity". I Phys. Rev. 122: 345–358. doi:10.1103/PhysRev.122.345.
• J Goldstone, A Salam and S Weinberg (1962). "Broken Symmetries". Physical Review. 127: 965. doi:10.1103/PhysRev.127.965.
• P W Anderson (1963). "Plasmons, Gauge Invariance, and Mass". Physical Review. 130: 439. doi:10.1103/PhysRev.130.439.
• A Klein and B W Lee (1964). "Does Spontaneous Breakdown of Symmetry Imply Zero-Mass Particles?". Physical Review Letters. 12: 266. doi:10.1103/PhysRevLett.12.266.
• W Gilbert (1964). "Broken Symmetries and Massless Particles". Physical Review Letters. 12: 713. doi:10.1103/PhysRevLett.12.713.

External links

• At Fermilab, the Race Is on for the 'God Particle'
• Physics World, Introducing the little Higgs
• A quasi-political Explanation of the Higgs Boson
• The Atom Smashers, a blog about the making of a documentary about the search for the Higgs boson
• In CERN Courier, Steven Weinberg reflects on spontaneous symmetry breaking
• Steven Weinberg Praises Teams for Higgs Boson Theory
• Physical Review Letters - 50th Anniversary Milestone Papers
• Imperial College London on PRL 50th Anniversary Milestone Papers
• The God Particle, from National Geographic Magazine
• "Tevatron experiments double-team Higgs boson", sets lower bound at 170GeV