Nothing Special   »   [go: up one dir, main page]

CERN Accelerating science

 
: Five sets of measurements by the LHCb experiment combined in this paper and their sensitivity to fragmentation fractions and branching fractions. : Observables and related parameters of the default fit. See text for a detailed explanation.
Measurements of \fsfd sensitive observables as a function of the \B-meson transverse momentum, \pt, overlaid with the fit function. The scaling factors $r_{AF}$ and $r_{E}$ are defined in the text; the variable \R is defined in Eq.~\ref{eq:R}. The vertical axes are zero-suppressed. The uncertainties on the data points are fully independent of each other; overall uncertainties for measurements in multiple \pt intervals are propagated via scaling parameters, as described in the text. The band associated with the fit function shows the uncertainty on the post-fit function for each sample.
Measurements of \fsfd sensitive observables as a function of the \B-meson transverse momentum, \pt, overlaid with the fit function. The scaling factors $r_{AF}$ and $r_{E}$ are defined in the text; the variable \R is defined in Eq.~\ref{eq:R}. The vertical axes are zero-suppressed. The uncertainties on the data points are fully independent of each other; overall uncertainties for measurements in multiple \pt intervals are propagated via scaling parameters, as described in the text. The band associated with the fit function shows the uncertainty on the post-fit function for each sample.
Measurements of \fsfd sensitive observables as a function of the \B-meson transverse momentum, \pt, overlaid with the fit function. The scaling factors $r_{AF}$ and $r_{E}$ are defined in the text; the variable \R is defined in Eq.~\ref{eq:R}. The vertical axes are zero-suppressed. The uncertainties on the data points are fully independent of each other; overall uncertainties for measurements in multiple \pt intervals are propagated via scaling parameters, as described in the text. The band associated with the fit function shows the uncertainty on the post-fit function for each sample.
Measurements of \fsfd sensitive observables as a function of the \B-meson transverse momentum, \pt, overlaid with the fit function. The scaling factors $r_{AF}$ and $r_{E}$ are defined in the text; the variable \R is defined in Eq.~\ref{eq:R}. The vertical axes are zero-suppressed. The uncertainties on the data points are fully independent of each other; overall uncertainties for measurements in multiple \pt intervals are propagated via scaling parameters, as described in the text. The band associated with the fit function shows the uncertainty on the post-fit function for each sample.
Measurements of \fsfd sensitive observables as a function of the \B-meson transverse momentum, \pt, overlaid with the fit function. The scaling factors $r_{AF}$ and $r_{E}$ are defined in the text; the variable \R is defined in Eq.~\ref{eq:R}. The vertical axes are zero-suppressed. The uncertainties on the data points are fully independent of each other; overall uncertainties for measurements in multiple \pt intervals are propagated via scaling parameters, as described in the text. The band associated with the fit function shows the uncertainty on the post-fit function for each sample.
Measurements of \fsfd sensitive observables as a function of the \B-meson transverse momentum, \pt, overlaid with the fit function. The scaling factors $r_{AF}$ and $r_{E}$ are defined in the text; the variable \R is defined in Eq.~\ref{eq:R}. The vertical axes are zero-suppressed. The uncertainties on the data points are fully independent of each other; overall uncertainties for measurements in multiple \pt intervals are propagated via scaling parameters, as described in the text. The band associated with the fit function shows the uncertainty on the post-fit function for each sample.
Measurements of \fsfd sensitive observables as a function of the \B-meson transverse momentum, \pt, overlaid with the fit function. The scaling factors $r_{AF}$ and $r_{E}$ are defined in the text; the variable \R is defined in Eq.~\ref{eq:R}. The vertical axes are zero-suppressed. The uncertainties on the data points are fully independent of each other; overall uncertainties for measurements in multiple \pt intervals are propagated via scaling parameters, as described in the text. The band associated with the fit function shows the uncertainty on the post-fit function for each sample.
Measurements of \fsfd sensitive observables as a function of the \B-meson transverse momentum, \pt, overlaid with the fit function. The scaling factors $r_{AF}$ and $r_{E}$ are defined in the text; the variable \R is defined in Eq.~\ref{eq:R}. The vertical axes are zero-suppressed. The uncertainties on the data points are fully independent of each other; overall uncertainties for measurements in multiple \pt intervals are propagated via scaling parameters, as described in the text. The band associated with the fit function shows the uncertainty on the post-fit function for each sample.
Measurements of \fsfd sensitive observables as a function of the \B-meson transverse momentum, \pt, overlaid with the fit function. The scaling factors $r_{AF}$ and $r_{E}$ are defined in the text; the variable \R is defined in Eq.~\ref{eq:R}. The vertical axes are zero-suppressed. The uncertainties on the data points are fully independent of each other; overall uncertainties for measurements in multiple \pt intervals are propagated via scaling parameters, as described in the text. The band associated with the fit function shows the uncertainty on the post-fit function for each sample.
Efficiency correction versus effective lifetime hypothesis for the \bsjpsiphi branching fraction. The band shows the uncertainty on the correction due to the simulated sample size for a given effective lifetime.
Fragmentation fraction ratio \fsfd as a function of proton-proton centre-of-mass energy.
Measurements of \fsfd sensitive observables as a function of the \B-meson transverse momentum, \pt, overlaid with the fit function. A Tsallis-statistics inspired function is used in this plot as described in the text. The scaling factors $r_{AF}$ and $r_{E}$ are defined in the text; the variable \R is defined in Eq.~\ref{eq:R}. The vertical axes are zero-suppressed. The uncertainties on the data points are fully independent of each other; overall uncertainties for measurements in multiple \pt intervals are propagated through scaling parameters, as described in the text. The band associated with the fit function shows the uncertainty on the post-fit function for each sample.
Measurements of \fsfd sensitive observables as a function of the \B-meson transverse momentum, \pt, overlaid with the fit function. A Tsallis-statistics inspired function is used in this plot as described in the text. The scaling factors $r_{AF}$ and $r_{E}$ are defined in the text; the variable \R is defined in Eq.~\ref{eq:R}. The vertical axes are zero-suppressed. The uncertainties on the data points are fully independent of each other; overall uncertainties for measurements in multiple \pt intervals are propagated through scaling parameters, as described in the text. The band associated with the fit function shows the uncertainty on the post-fit function for each sample.
Measurements of \fsfd sensitive observables as a function of the \B-meson transverse momentum, \pt, overlaid with the fit function. A Tsallis-statistics inspired function is used in this plot as described in the text. The scaling factors $r_{AF}$ and $r_{E}$ are defined in the text; the variable \R is defined in Eq.~\ref{eq:R}. The vertical axes are zero-suppressed. The uncertainties on the data points are fully independent of each other; overall uncertainties for measurements in multiple \pt intervals are propagated through scaling parameters, as described in the text. The band associated with the fit function shows the uncertainty on the post-fit function for each sample.
Measurements of \fsfd sensitive observables as a function of the \B-meson transverse momentum, \pt, overlaid with the fit function. A Tsallis-statistics inspired function is used in this plot as described in the text. The scaling factors $r_{AF}$ and $r_{E}$ are defined in the text; the variable \R is defined in Eq.~\ref{eq:R}. The vertical axes are zero-suppressed. The uncertainties on the data points are fully independent of each other; overall uncertainties for measurements in multiple \pt intervals are propagated through scaling parameters, as described in the text. The band associated with the fit function shows the uncertainty on the post-fit function for each sample.
Measurements of \fsfd sensitive observables as a function of the \B-meson transverse momentum, \pt, overlaid with the fit function. A Tsallis-statistics inspired function is used in this plot as described in the text. The scaling factors $r_{AF}$ and $r_{E}$ are defined in the text; the variable \R is defined in Eq.~\ref{eq:R}. The vertical axes are zero-suppressed. The uncertainties on the data points are fully independent of each other; overall uncertainties for measurements in multiple \pt intervals are propagated through scaling parameters, as described in the text. The band associated with the fit function shows the uncertainty on the post-fit function for each sample.
Measurements of \fsfd sensitive observables as a function of the \B-meson transverse momentum, \pt, overlaid with the fit function. A Tsallis-statistics inspired function is used in this plot as described in the text. The scaling factors $r_{AF}$ and $r_{E}$ are defined in the text; the variable \R is defined in Eq.~\ref{eq:R}. The vertical axes are zero-suppressed. The uncertainties on the data points are fully independent of each other; overall uncertainties for measurements in multiple \pt intervals are propagated through scaling parameters, as described in the text. The band associated with the fit function shows the uncertainty on the post-fit function for each sample.
Measurements of \fsfd sensitive observables as a function of the \B-meson transverse momentum, \pt, overlaid with the fit function. A Tsallis-statistics inspired function is used in this plot as described in the text. The scaling factors $r_{AF}$ and $r_{E}$ are defined in the text; the variable \R is defined in Eq.~\ref{eq:R}. The vertical axes are zero-suppressed. The uncertainties on the data points are fully independent of each other; overall uncertainties for measurements in multiple \pt intervals are propagated through scaling parameters, as described in the text. The band associated with the fit function shows the uncertainty on the post-fit function for each sample.
Measurements of \fsfd sensitive observables as a function of the \B-meson transverse momentum, \pt, overlaid with the fit function. A Tsallis-statistics inspired function is used in this plot as described in the text. The scaling factors $r_{AF}$ and $r_{E}$ are defined in the text; the variable \R is defined in Eq.~\ref{eq:R}. The vertical axes are zero-suppressed. The uncertainties on the data points are fully independent of each other; overall uncertainties for measurements in multiple \pt intervals are propagated through scaling parameters, as described in the text. The band associated with the fit function shows the uncertainty on the post-fit function for each sample.
Measurements of \fsfd sensitive observables as a function of the \B-meson transverse momentum, \pt, overlaid with the fit function. A Tsallis-statistics inspired function is used in this plot as described in the text. The scaling factors $r_{AF}$ and $r_{E}$ are defined in the text; the variable \R is defined in Eq.~\ref{eq:R}. The vertical axes are zero-suppressed. The uncertainties on the data points are fully independent of each other; overall uncertainties for measurements in multiple \pt intervals are propagated through scaling parameters, as described in the text. The band associated with the fit function shows the uncertainty on the post-fit function for each sample.