pdgLive

2020

LHC

ATLAS+CMS combined

$-0.045$ $\pm0.044$ $\pm0.058$

2013

CDF

${{\mathit F}_{{+}}}$ = B( ${{\mathit t}}$ $\rightarrow$ ${{\mathit W}_{{+}}}{{\mathit b}}$ )

$0.008$ $\pm0.012$ $\pm0.014$

CHATRCHYAN

2013

CMS

${{\mathit F}_{{+}}}$ = B( ${{\mathit t}}$ $\rightarrow$ ${{\mathit W}_{{+}}}{{\mathit b}}$ )

$0.01$ $\pm0.05$

⁴

2012

ATLS

${{\mathit F}_{{+}}}$ = B( ${{\mathit t}}$ $\rightarrow$ ${{\mathit W}_{{+}}}{{\mathit b}}$ )

$0.023$ $\pm0.041$ $\pm0.034$

⁵

2011

${{\mathit F}_{{+}}}$ = B( ${{\mathit t}}$ $\rightarrow$ ${{\mathit W}_{{+}}}{{\mathit b}}$ )

$0.11$ $\pm0.15$

⁶

AFFOLDER

2000

CDF

${{\mathit F}_{{+}}}$ = B( ${{\mathit t}}$ $\rightarrow$ ${{\mathit W}}_{+}$ ${{\mathit b}}$ )

• • We do not use the following data for averages, fits, limits, etc. • •

$< 0.036 \pm0.006$

⁷

AABOUD

2017

ATLS

${{\mathit F}_{{+}}}$ = ${{\mathit f}_{{1}}}{{\mathit f}_{{1}}^{+}}$, Repl. by AAD 2020Y

$-0.004$ $\pm0.005$ $\pm0.014$

⁸

KHACHATRYAN

2016

CMS

${{\mathit F}_{{+}}}$ = B( ${{\mathit t}}$ $\rightarrow$ ${{\mathit W}_{{+}}}{{\mathit b}}$ ), Repl. by AAD 2020Y

$-0.033$ $\pm0.034$ $\pm0.031$

⁹

2012

TEVA

${{\mathit F}_{{+}}}$ = B( ${{\mathit t}}$ $\rightarrow$ ${{\mathit W}_{{+}}}{{\mathit b}}$ )

$-0.01$ $\pm0.02$ $\pm0.05$

¹⁰

2010

CDF

Repl. by AALTONEN 2013D

$-0.04$ $\pm0.04$ $\pm0.03$

¹¹

2009

CDF

Repl. by AALTONEN 2010Q

$0.119$ $\pm0.090$ $\pm0.053$

¹²

2008

Repl. by ABAZOV 2011C

$0.056$ $\pm0.080$ $\pm0.057$

¹³

2007

${{\mathit F}_{{+}}}$ = B( ${{\mathit t}}$ $\rightarrow$ ${{\mathit W}_{{+}}}{{\mathit b}}$ )

$0.05$ ${}^{+0.11}_{-0.05}$ $\pm0.03$

¹⁴

2007

CDF

${{\mathit F}_{{+}}}$ = B( ${{\mathit t}}$ $\rightarrow$ ${{\mathit W}_{{+}}}{{\mathit b}}$ )

$<0.26$

¹⁴

2007

CDF

${{\mathit F}_{{+}}}$ = B( ${{\mathit t}}$ $\rightarrow$ ${{\mathit W}_{{+}}}{{\mathit b}}$ )

$<0.27$

¹⁵

2006

CDF

${{\mathit F}_{{+}}}$ = B( ${{\mathit t}}$ $\rightarrow$ ${{\mathit W}_{{+}}}{{\mathit b}}$ )

$0.00$ $\pm0.13$ $\pm0.07$

¹⁶

2005

${{\mathit F}_{{+}}}$ = B( ${{\mathit t}}$ $\rightarrow$ ${{\mathit W}_{{+}}}{{\mathit b}}$ )

$<0.25$

¹⁶

2005

${{\mathit F}_{{+}}}$ = B( ${{\mathit t}}$ $\rightarrow$ ${{\mathit W}_{{+}}}{{\mathit b}}$ )

$<0.24$

¹⁷

ACOSTA

2005

CDF

${{\mathit F}_{{+}}}$ = B( ${{\mathit t}}$ $\rightarrow$ ${{\mathit W}_{{+}}}{{\mathit b}}$ )

AAD 2020Y based on about 20 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ data at $\sqrt {s }$ = 8 TeV for each experiment. The first error stands for the sum of the statistical and background uncertainties, and the second error for the remaining systematic uncertainties. The measurements used events with one lepton and different jet multiplicities in the final state. The result is estimated from the measurements of $\mathit F_{0}$ and $\mathit F_{-}$ assuming unitarity. The value is consistent with the NNLO SM prediction of $0.0017$ $\pm0.0001$ for ${\mathit m}_{{{\mathit t}}}$ = $172.8$ $\pm1.3$ GeV.

Based on 8.7 fb${}^{-1}$ of data in ${{\mathit p}}{{\overline{\mathit p}}}$ collisions at $\sqrt {s }$ = 1.96 TeV using ${{\mathit t}}{{\overline{\mathit t}}}$ events with ${{\mathit \ell}}$ + $\not E_T$ + ${}\geq{}$4 jets(${}\geq{}$1 ${{\mathit b}}$), and under the constraint F$_{0}$ + F$_{+}$ + F$_{-}$ = 1. The statstical errors of F$_{0}$ and F$_{+}$ are correlated with correlation coefficient $\rho (F_{0},F_{+}$) = $-0.69$.

³	Based on 5.0 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ data at $\sqrt {s }$ = 7 TeV. CHATRCHYAN 2013BH studied events with large $\not E_T$ and ${{\mathit \ell}}$ +${}\geq{}$4 jets using a constrained kinematic fit.

⁴	Based on 1.04 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ data at $\sqrt {s }$ = 7 TeV. AAD 2012BG studied events with large $\not E_T$ and either ${{\mathit \ell}}$ +${}\geq{}$4j or ${{\mathit \ell}}{{\mathit \ell}}$ +${}\geq{}$2j.

⁵

Results are based on 5.4 fb${}^{-1}$ of data in ${{\mathit p}}{{\overline{\mathit p}}}$ collisions at 1.96 TeV, including those of ABAZOV 2008B. Under the SM constraint of ${{\mathit f}_{{0}}}$ = 0.698 (for ${\mathit m}_{{{\mathit t}}}$ = 173.3 GeV, ${\mathit m}_{{{\mathit W}}}$ = 80.399 GeV), ${{\mathit f}_{{+}}}$ = $0.010$ $\pm0.022$ $\pm0.030$ is obtained.

⁶

AFFOLDER 2000B studied the angular distribution of leptonic decays of ${{\mathit W}}$ bosons in ${{\mathit t}}$ $\rightarrow$ ${{\mathit W}}{{\mathit b}}$ events. The ratio $\mathit F_{0}$ is the fraction of the helicity zero (longitudinal) ${{\mathit W}}~$bosons in the decaying top quark rest frame. B( ${{\mathit t}}$ $\rightarrow$ ${{\mathit W}}_{+}$ ${{\mathit b}}$ ) is the fraction of positive helicity (right-handed) positive charge ${{\mathit W}}~$bosons in the top quark decays. It is obtained by assuming the Standard Model value of $\mathit F_{0}$.

⁷

AABOUD 2017BB based on 20.2 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ data at $\sqrt {s }$ = 8 TeV. Triple-differential decay rate of top quark in the ${{\mathit t}}$-channel single-top production is used to simultaneously determine five generalized ${{\mathit W}}{{\mathit t}}{{\mathit b}}$ couplings as well as the top polarization. No assumption is made for the other couplings. The authors reported ${{\mathit f}_{{1}}}$ = $0.30$ $\pm0.05$ and ${{\mathit f}_{{1}}^{+}}$ $<$ $0.120$ which we converted to ${{\mathit F}_{{+}}}$ = ${{\mathit f}_{{1}}}{{\mathit f}_{{1}}^{+}}$. See this paper for constraints on other couplings not included here.

⁸

KHACHATRYAN 2016BU based on 19.8 fb${}^{-1}$ of ${{\mathit p}}{{\mathit p}}$ data at $\sqrt {s }$ = 8 TeV using ${{\mathit t}}{{\overline{\mathit t}}}$ events with ${{\mathit \ell}}$ + $\not E_T$ + ${}\geq{}$4 jets(${}\geq{}$2 ${{\mathit b}}$). The result is consistent with the NNLO SM prediction of $0.0017$ $\pm0.0001$ for ${\mathit m}_{{{\mathit t}}}$ = $172.8$ $\pm1.3$ GeV.

⁹

Based on 2.7 and 5.1 fb${}^{-1}$ of CDF data in ${{\mathit \ell}}$ + jets and dilepton channels, and 5.4 fb${}^{-1}$ of D0 data in ${{\mathit \ell}}$ + jets and dilepton channels. ${{\mathit F}_{{0}}}$ = $0.682$ $\pm0.035$ $\pm0.046$ if ${{\mathit F}_{{+}}}$ = 0.0017(1), while ${{\mathit F}_{{+}}}$ = $-0.015$ $\pm0.018$ $\pm0.030$ if ${{\mathit F}_{{0}}}$ = 0.688(4), where the assumed fixed values are the SM prediction for ${\mathit m}_{{{\mathit t}}}$ = $173.3$ $\pm1.1$ GeV and ${\mathit m}_{{{\mathit W}}}$ = $80.399$ $\pm0.023$ GeV.

¹⁰

Results are based on 2.7 fb${}^{-1}$ of data in ${{\mathit p}}{{\overline{\mathit p}}}$ collisions at $\sqrt {s }$ = 1.96 TeV. ${{\mathit F}_{{0}}}$ result is obtained by assuming ${{\mathit F}_{{+}}}$ = 0, while ${{\mathit F}_{{+}}}$ result is obtained for ${{\mathit F}_{{0}}}$ = 0.70, the SM value. Model independent fits for the two fractions give ${{\mathit F}_{{0}}}$ = $0.88$ $\pm0.11$ $\pm0.06$ and ${{\mathit F}_{{+}}}$ = $-0.15$ $\pm0.07$ $\pm0.06$ with correlation coefficient of $-0.59$. The results are for ${\mathit m}_{{{\mathit t}}}$ = 175 GeV.

¹¹

Results are based on 1.9 fb${}^{-1}$ of data in ${{\mathit p}}{{\overline{\mathit p}}}$ collisions at $\sqrt {s }$ = 1.96 TeV. ${{\mathit F}_{{0}}}$ result is obtained assuming ${{\mathit F}_{{+}}}$ = 0, while ${{\mathit F}_{{+}}}$ result is obtained for ${{\mathit F}_{{0}}}$ = 0.70, the SM values. Model independent fits for the two fractions give ${{\mathit F}_{{0}}}$ = $0.66$ $\pm0.16$ $\pm0.05$ and ${{\mathit F}_{{+}}}$ = $-0.03$ $\pm0.06$ $\pm0.03$.

¹²	Based on 1 fb${}^{-1}$ at $\sqrt {s }$ = 1.96 TeV.

¹³	Based on 370 pb${}^{-1}$ of data at $\sqrt {s }$ = 1.96 TeV, using the ${{\mathit \ell}}$ + jets and dilepton decay channels. The result assumes ${{\mathit F}_{{0}}}$ = 0.70, and it gives ${{\mathit F}_{{+}}}$ $<$ 0.23 at 95$\%$ CL.

¹⁴	Based on 318 pb${}^{-1}$ of data at $\sqrt {s }$ = 1.96 TeV.

¹⁵	Based on 200 pb${}^{-1}$ of data at $\sqrt {s }$ = 1.96 TeV. ${{\mathit t}}$ $\rightarrow$ ${{\mathit W}}{{\mathit b}}$ $\rightarrow$ ${{\mathit \ell}}{{\mathit \nu}}{{\mathit b}}$ (${{\mathit \ell}}$ = ${{\mathit e}}$ or ${{\mathit \mu}}$). The errors are stat + syst.

¹⁶

ABAZOV 2005L studied the angular distribution of leptonic decays of ${{\mathit W}}$ bosons in ${{\mathit t}}{{\overline{\mathit t}}}$ events, where one of the ${{\mathit W}}$'s from ${{\mathit t}}$ or ${{\overline{\mathit t}}}$ decays into ${{\mathit e}}$ or ${{\mathit \mu}}$ and the other decays hadronically. The fraction of the ``+'' helicity ${{\mathit W}}$ boson is obtained by assuming ${{\mathit F}_{{0}}}$ = 0.7, which is the generic prediction for any linear combination of V and A currents. Based on $230$ $\pm15$ pb${}^{-1}$ of data at $\sqrt {s }$ = 1.96 TeV.

¹⁷

ACOSTA 2005D measures the ${{\mathit m}^{2}}_{ {{\mathit \ell}} {+} {{\mathit b}} }$ distribution in ${{\mathit t}}{{\overline{\mathit t}}}$ production events where one or both ${{\mathit W}}$'s decay leptonically to ${{\mathit \ell}}$ = ${{\mathit e}}$ or ${{\mathit \mu}}$, and finds a bound on the V+A coupling of the ${{\mathit t}}{{\mathit b}}{{\mathit W}}$ vertex. By assuming the SM value of the longitudinal ${{\mathit W}}$ fraction ${{\mathit F}_{{0}}}$ = B( ${{\mathit t}}$ $\rightarrow$ ${{\mathit W}_{{0}}}{{\mathit b}}$ ) = 0.70, the bound on ${{\mathit F}}_{+}$ is obtained. If the results are combined with those of AFFOLDER 2000B, the bounds become ${{\mathit F}}_{V+A}$ $<$ 0.61 (95$\%$ CL) and ${{\mathit F}_{{+}}}$ $<$ 0.18 (95 $\%$CL), respectively. Based on $109$ $\pm7$ pb${}^{-1}$ of data at $\sqrt {s }$ = 1.8 TeV (run I).

References:

2020Y

JHEP 2008 051

Combination of the W boson polarization measurements in top quark decays using ATLAS and CMS data at $\sqrt{s} =$ 8 TeV

AABOUD

2017BB

JHEP 1712 017

Analysis of the $\mathit W_{tb}$ Vertex from the Measurement of Triple-Differential Angular Decay Rates of Single Top Quarks Produced in the t-Channel at $\sqrt {s }$ = 8 TeV with the ATLAS Detector

KHACHATRYAN

2016BU

PL B762 512

Measurement of the ${{\mathit W}}$ Boson Helicity Fractions in the Decays of Top Quark Pairs to Lepton + Jets Final States Produced in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 8 TeV

2013D

PR D87 031104

Measurement of $\mathit W$-Boson Polarization in Top-Quark Decay using the Full CDF Run II Data Set

CHATRCHYAN

2013BH

JHEP 1310 167

Measurement of the ${{\mathit W}}$-Boson Helicity in Top-Quark Decays from ${\mathit {\mathit t}}{\mathit {\overline{\mathit t}}}$ Production in Lepton+Jets Events in ${{\mathit p}}{{\mathit p}}$ Collisions at $\sqrt {s }$ = 7 TeV

2012BG

JHEP 1206 088

Measurement of the ${{\mathit W}}$ Boson Polarization in Top Quark Decays with the ATLAS Detector

2012Z

PR D85 071106

Combination of CDF and ${D0}$ Measurements of the ${{\mathit W}}$ Boson Helicity in Top Quark Decays

2011C

PR D83 032009

Measurement of the $\mathit W$ Boson Helicity in Top Quark Decays using 5.4 fb${}^{-1}$ of ${{\mathit p}}{{\overline{\mathit p}}}$ Collision Data

2010Q

PRL 105 042002

Measurement of ${{\mathit W}}$-Boson Polarization in Top-Quark Decay in Collisions at $\sqrt {s }$ = 1.96$~$TeV

2009Q

PL B674 160

Measurement of ${{\mathit W}}$-Boson Helicity Fractions in Top-Quark Decays using cos $\theta {}^{*}$

2008B

PRL 100 062004

Model-Independent Measurement of the ${{\mathit W}}$ Boson Helicity in Top Quark Decays at ${D0}$

2007D

PR D75 031102

Measurement of the ${{\mathit W}}$ Boson Helicity in Top Quark Decays at ${D0}$

2007I

PR D75 052001

Measurement of the Helicity Fractions of ${{\mathit W}}$ Bosons from top Quark Decays using Fully Reconstructed ${\mathit {\mathit t}}$ ${\mathit {\overline{\mathit t}}}$ Events with CDF II

2006U

PR D73 111103

Measurement of the Helicity of $\mathit W$ Bosons in top-Quark Decays