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CHARMED MESONS
($\mathit C$ = $\pm1$)
${{\mathit D}^{+}}$ = ${\mathit {\mathit c}}$ ${\mathit {\overline{\mathit d}}}$, ${{\mathit D}^{0}}$ = ${\mathit {\mathit c}}$ ${\mathit {\overline{\mathit u}}}$, ${{\overline{\mathit D}}^{0}}$ = ${\mathit {\overline{\mathit c}}}$ ${\mathit {\mathit u}}$, ${{\mathit D}^{-}}$ = ${\mathit {\overline{\mathit c}}}$ ${\mathit {\mathit d}}$, similarly for ${{\mathit D}^{*}}$'s

INSPIRE JSON (beta) PDGID:

${{\mathit D}^{0}}$

$I(J^P)$ = $1/2(0^{-})$

See related review:

${{\mathit D}^{0}}$ $-$ ${{\overline{\mathit D}}^{0}}$ Mixing

${{\mathit D}^{0}}$ MASS

$1864.84 \pm0.05$ MeV

${\mathit m}_{{{\mathit D}^{\pm}}}–{\mathit m}_{{{\mathit D}^{0}}}$

$4.822 \pm0.015$ MeV

${{\mathit D}^{0}}$ MEAN LIFE

$(4.103 \pm0.010) \times 10^{-13}$ s

$\vert{}{\mathit m}_{{{\mathit D}_{{1}}^{0}}}–{\mathit m}_{{{\mathit D}_{{2}}^{0}}}\vert{}$ = $x$ $\Gamma $

$(99.7 \pm11.6) \times 10^{8}$ $\hbar{}$ s${}^{-1}$

($\Gamma _{{{\mathit D}_{{1}}^{0}}}$ $-$ $\Gamma _{{{\mathit D}_{{2}}^{0}}})/\Gamma $ = 2$\mathit y$

$0.01394 \pm0.00056$

$\vert $q/p$\vert $

$0.995 \pm0.016$

$0.000089 \pm0.000113$

$\phi {}^{ {{\mathit K}_S^0} {{\mathit \pi}} {{\mathit \pi}} }$

$0.02 {}^{+0.04}_{-0.05}$

$0.990 \pm0.025$

${{\mathit D}^{0}}$ $\rightarrow$ ${{\mathit K}^{-}}{{\mathit \pi}^{+}}{{\mathit \pi}^{0}}$ COHERENCE FACTOR $\mathit R_{ {{\mathit K}} {{\mathit \pi}} {{\mathit \pi}^{0}} }$

$0.792 \pm0.033$

${{\mathit D}^{0}}$ $\rightarrow$ ${{\mathit K}^{-}}{{\mathit \pi}^{+}}{{\mathit \pi}^{0}}$ AVERAGE RELATIVE STRONG PHASE $\delta {}^{ {{\mathit K}} {{\mathit \pi}} {{\mathit \pi}^{0}} }$

$198 \pm10$ $^\circ{}$

${{\mathit D}^{0}}$ $\rightarrow$ ${{\mathit K}^{-}}{{\mathit \pi}^{-}}$2 ${{\mathit \pi}^{+}}$ COHERENCE FACTOR $\mathit R_{ {{\mathit K}}3 {{\mathit \pi}} }$

$0.52 {}^{+0.10}_{-0.09}$

${{\mathit D}^{0}}$ $\rightarrow$ ${{\mathit K}^{-}}{{\mathit \pi}^{-}}$2 ${{\mathit \pi}^{+}}$ AVERAGE RELATIVE STRONG PHASE $\delta {}^{ {{\mathit K}}3 {{\mathit \pi}} }$

$149 {}^{+26}_{-16}$ $^\circ{}$ (S = 1.4)

${{\mathit D}^{0}}$ $\rightarrow$ ${{\mathit K}^{-}}{{\mathit \pi}^{-}}$2 ${{\mathit \pi}^{+}}$ , $\mathit R_{ {{\mathit K}}3 {{\mathit \pi}} }$ (y cos $\delta {}^{ {{\mathit K}}3 {{\mathit \pi}} }$ $−$ x sin$\delta {}^{ {{\mathit K}}3 {{\mathit \pi}} }$)

$-0.0030 \pm0.0007$ TeV${}^{-1}$

${{\mathit D}^{0}}$ $\rightarrow$ ${{\mathit K}_S^0}$ ${{\mathit K}^{+}}{{\mathit \pi}^{-}}$ COHERENCE FACTOR R$_{ {{\mathit K}_S^0} {{\mathit K}} {{\mathit \pi}} }$

${{\mathit D}^{0}}$ $\rightarrow$ ${{\mathit K}_S^0}$ ${{\mathit K}^{+}}{{\mathit \pi}^{-}}$ AVERAGE RELATIVE STRONG PHASE $\delta {}^{ {{\mathit K}_S^0} {{\mathit K}} {{\mathit \pi}} }$

$0 \pm16$ $^\circ{}$

${{\mathit D}^{0}}$ $\rightarrow$ ${{\mathit K}^{*}}{{\mathit K}}$ COHERENCE FACTOR R$_{ {{\mathit K}^{*}} {{\mathit K}} }$

${{\mathit D}^{0}}$ $\rightarrow$ ${{\mathit K}^{*}}{{\mathit K}}$ AVERAGE RELATIVE STRONG PHASE $\delta {}^{ {{\mathit K}^{*}} {{\mathit K}} }$

$-17 \pm18$ $^\circ{}$

▸	${{\mathit D}^{0}}$ $\mathit CP$-EVEN FRACTIONS

▸	${{\mathit D}^{0}}$ $\mathit CP$-VIOLATING DECAY-RATE ASYMMETRIES

${{\mathit D}^{0}}$ $\mathit CP$-VIOLATING ASYMMETRY DIFFERENCES

$\Delta \mathit A_{CP}$ = $\mathit A_{CP}$( ${{\mathit K}^{+}}{{\mathit K}^{-}}$ ) $−$ $\mathit A_{CP}$( ${{\mathit \pi}^{+}}{{\mathit \pi}^{-}}$ )

$-0.00154 \pm0.00029$

▸	${{\mathit D}^{0}}$ TESTS OF LOCAL $\mathit CP$-VIOLATION ($\mathit CPV$)

▸	$\mathit CP$ VIOLATING ASYMMETRIES OF $\mathit P$-ODD ($\mathit T$-ODD) MOMENTS

${{\mathit D}^{0}}$ $\mathit CPT$-VIOLATING DECAY-RATE ASYMMETRIES

$\mathit A_{\mathit CPT}({{\mathit K}^{\mp}}{{\mathit \pi}^{\pm}}$) in ${{\mathit D}^{0}}$ $\rightarrow$ ${{\mathit K}^{-}}{{\mathit \pi}^{+}}$ , ${{\overline{\mathit D}}^{0}}$ $\rightarrow$ ${{\mathit K}^{+}}{{\mathit \pi}^{-}}$

$0.008 \pm0.008$

▸	*${{\mathit D}^{0}}$ $\rightarrow$ ${{\mathit K}^{}{(892)}^{-}}{{\mathit \ell}^{+}}{{\mathit \nu}_{{{{\mathit \ell}}}}}$ FORM FACTORS**

▸	${{\mathit D}^{0}}$ $\rightarrow$ ${{\mathit K}^{-}}$ / ${{\mathit \pi}^{-}}{{\mathit \ell}^{+}}{{\mathit \nu}_{{{{\mathit \ell}}}}}$ FORM FACTORS

Amplitude analyses

${{\mathit D}}$ $\rightarrow$ ${{\mathit K}}{{\mathit \pi}}{{\mathit \pi}}{{\mathit \pi}}$ , ${{\mathit D}}$ $\rightarrow$ ${{\mathit K}}{{\mathit K}}{{\mathit \pi}}{{\mathit \pi}}$ partial wave analyses

${{\mathit D}^{0}}$ DECAY MODES ▸ Expand all decays

Most decay modes (other than the semileptonic modes) that involve a neutral ${{\mathit K}}$ meson are now given as ${{\mathit K}_S^0}$ modes, not as ${{\overline{\mathit K}}^{0}}$ modes. Nearly always it is a ${{\mathit K}_S^0}$ that is measured, and interference between Cabibbo-allowed and doubly Cabibbo-suppressed modes can invalidate the assumption that 2$~\Gamma ({{\mathit K}_S^0}$ ) = $\Gamma ({{\overline{\mathit K}}^{0}}$).

▸	Topological modes

▸	Inclusive modes

▸	Semileptonic modes

▸	Hadronic modes with one ${{\overline{\mathit K}}}$

▸	Fractions of some of the following modes with resonances have already appeared above as submodes of particular charged-particle modes.These nine modes below are all corrected for unseen decays of the resonances.

▸	Hadronic modes with three ${{\mathit K}}$'s

▸	Pionic modes

▸	Hadronic modes with a ${{\mathit K}}{{\overline{\mathit K}}}$ pair

▸	Other ${{\mathit K}}{{\overline{\mathit K}}}{{\mathit X}}$ modes. They include all decay modes of the ${{\mathit \phi}}$, ${{\mathit \eta}}$, and ${{\mathit \omega}}$.

▸	Radiative modes

▸	Doubly Cabibbo suppressed ($\mathit DC$) modes or $\Delta \mathit C$ = 2 forbidden via mixing ($\mathit C2M$) modes

▸	$\Delta \mathit C$ = 1 weak neutral current ($\mathit C1$) modes, Lepton Family number ($\mathit LF$) violating modes, Lepton ($\mathit L$) or Baryon ($\mathit B$) number violating modes

Unaccounted decay modes

$(35.0\pm{1.3})\%$

FOOTNOTES

Constrained Fit information

Except where otherwise noted, content of the 2023 Review of Particle Physics is licensed under a Creative Commons Attribution-NonCommercial 4.0 International (CC BY-NC 4.0) license. The publication of the Review of Particle Physics is supported by US DOE, MEXT (Japan), INFN (Italy), JPS and CERN. Individual collaborators receive support for their PDG activities from their respective institutes or funding agencies. © 2023. See LBNL disclaimers.