Next-to-Minimal Supersymmetric Standard Model

In particle physics, NMSSM is an acronym for Next-to-Minimal Supersymmetric Standard Model. It is a supersymmetric extension to the Standard Model that adds an additional singlet chiral superfield to the MSSM and can be used to dynamically generate the μ {displaystyle mu } term, solving the μ {displaystyle mu } -problem. Articles about the NMSSM are available for review. In particle physics, NMSSM is an acronym for Next-to-Minimal Supersymmetric Standard Model. It is a supersymmetric extension to the Standard Model that adds an additional singlet chiral superfield to the MSSM and can be used to dynamically generate the μ {displaystyle mu } term, solving the μ {displaystyle mu } -problem. Articles about the NMSSM are available for review. The Minimal Supersymmetric Standard Model does not explain why the μ {displaystyle mu } parameter in the superpotential term μ H u H d {displaystyle mu H_{u}H_{d}} is at the electroweak scale. The idea behind the Next-to-Minimal Supersymmetric Standard Model is to promote the μ {displaystyle mu } term to a gauge singlet, chiral superfield S {displaystyle S} . Note that the scalar superpartner of the singlino S {displaystyle S} is denoted by S ^ {displaystyle {hat {S}}} and the spin-1/2 singlino superpartner by S ~ {displaystyle { ilde {S}}} in the following. The superpotential for the NMSSM is given by where W Yuk {displaystyle W_{ ext{Yuk}}} gives the Yukawa couplings for the Standard Model fermions. Since the superpotential has a mass dimension of 3, the couplings λ {displaystyle lambda } and κ {displaystyle kappa } are dimensionless; hence the μ {displaystyle mu } -problem of the MSSM is solved in the NMSSM, the superpotential of the NMSSM being scale-invariant. The role of the λ {displaystyle lambda } term is to generate an effective μ {displaystyle mu } term. This is done with the scalar component of the singlet S ^ {displaystyle {hat {S}}} getting a vacuum-expectation value of ⟨ S ^ ⟩ {displaystyle langle {hat {S}} angle } ; that is, we have Without the κ {displaystyle kappa } term the superpotential would have a U(1)' symmetry, so-called Peccei–Quinn symmetry; see Peccei–Quinn theory. This additional symmetry would alter the phenomenology completely. The role of the κ {displaystyle kappa } term is to break this U(1)' symmetry. The κ {displaystyle kappa } term is introduced trilinearly such that κ {displaystyle kappa } is dimensionless. However, there remains a discrete Z 3 {displaystyle mathbb {Z} _{3}} symmetry, which is moreover broken spontaneously. In principle this leads to the domain wall problem. Introducing additional but suppressed terms, the Z 3 {displaystyle mathbb {Z} _{3}} symmetry can be broken without changing phenomenology at the electroweak scale.It is assumed that the domain wall problem is circumvented in this way without any modifications except far beyond the electroweak scale. Other models have been proposed which solve the μ {displaystyle mu } -problem of the MSSM. One idea is to keep the κ {displaystyle kappa } term in the superpotential and take the U(1)' symmetry into account. Assuming this symmetry to be local, an additional, Z ′ {displaystyle Z'} gauge boson is predicted inthis model, called the UMSSM. Due to the additional singlet S {displaystyle S} , the NMSSM alters in general the phenomenology of both the Higgs sector and the neutralino sector compared with the MSSM. In the Standard Model we have one physical Higgs boson. In the MSSM we encounter five physical Higgs bosons. Due to the additional singlet S ^ {displaystyle {hat {S}}} in the NMSSM we have two more Higgs bosons; that is, in total seven physical Higgs bosons. Its Higgs sector is therefore much richer than that of the MSSM. In particular, the Higgs potential is in general no longer invariant under CP transformations; see CP violation. Typically, the Higgs bosons in the NMSSM are denoted in an order with increasing masses; that is, by H 1 , H 2 , . . . , H 7 {displaystyle H_{1},H_{2},...,H_{7}} , with H 1 {displaystyle H_{1}} the lightest Higgs boson. In the special case of a CP-conserving Higgs potential we have three CP even Higgs bosons, H 1 , H 2 , H 3 {displaystyle H_{1},H_{2},H_{3}} , two CP odd ones, A 1 , A 2 {displaystyle A_{1},A_{2}} , and a pair of charged Higgs bosons, H + , H − {displaystyle H^{+},H^{-}} . In the MSSM, the lightest Higgs boson is always Standard Model-like, and therefore its production and decays are roughly known. In the NMSSM, the lightest Higgs can be very light (even of the order of 1 GeV), and thus may have escaped detection so far. In addition, in the CP-conserving case, the lightest CP even Higgs boson turns out to have an enhanced lower bound compared with the MSSM. This is one of the reasons why the NMSSM has been the focus of much attention in recent years. The spin-1/2 singlino S ~ {displaystyle { ilde {S}}} gives a fifth neutralino, compared with the four neutralinos of the MSSM. The singlino does not couple with any gauge bosons, gauginos (the superpartners of the gauge bosons), leptons, sleptons (the superpartners of the leptons), quarks or squarks (the superpartners of the quarks). Suppose that a supersymmetric partner particle is produced at a collider, for instance at the LHC, the singlino is omitted in cascade decays and therefore escapes detection. However, if the singlino is the lightest supersymmetric particle (LSP), all supersymmetric partner particles eventually decay into the singlino. Due to R parity conservation this LSP is stable. In this way the singlino could be detected via missing transverse energy in a detector.