| $> 592$ |
90 |
1 |
|
TWST |
| $\bf{>715}$ |
90 |
2 |
|
RVUE |
| • • • We do not use the following data for averages, fits, limits, etc. • • • |
| $>4000$ |
95 |
3 |
|
RVUE |
| $>235$ |
90 |
4 |
|
PIE3 |
| $> 245$ |
90 |
5 |
|
CNTR |
| $> 2500$ |
|
6 |
|
THEO |
| $> 180$ |
90 |
7 |
|
CNTR |
| $> 290.7$ |
90 |
8 |
|
CNTR |
| $\text{[> 3300]}$ |
95 |
9 |
|
COSM |
| $>310$ |
90 |
10 |
|
CNTR |
| $>137$ |
95 |
11 |
|
OPAL |
| $>1400$ |
68 |
12 |
|
RVUE |
| $>549$ |
68 |
13 |
|
RVUE |
| $>220$ |
95 |
14 |
|
RVUE |
| $>220$ |
90 |
15 |
|
CNTR |
| $>281$ |
90 |
16 |
|
CNTR |
| $>282$ |
90 |
17 |
|
CNTR |
| $>439$ |
90 |
18 |
|
RVUE |
| $>250$ |
90 |
19 |
|
CNTR |
|
|
20 |
|
CNTR |
| $>475$ |
90 |
21 |
|
RVUE |
| $>240$ |
90 |
22 |
|
RVUE |
| $>496$ |
90 |
22 |
|
RVUE |
| $>700$ |
|
23 |
|
THEO |
| $>477$ |
90 |
24 |
|
RVUE |
| $\text{[none 540 - 23000]}$ |
|
25 |
|
ASTR |
| $>300$ |
90 |
26 |
|
RVUE |
| $>160$ |
90 |
27 |
|
CNTR |
| $>406$ |
90 |
28 |
|
ELEC |
| $>482$ |
90 |
28 |
|
ELEC |
| $>800$ |
|
|
|
RVUE |
| $>400$ |
95 |
29 |
|
ELEC |
| $>475$ |
95 |
29 |
|
ELEC |
|
|
30 |
|
CHRM |
| $>380$ |
90 |
31 |
|
ELEC |
| $>1600$ |
|
32 |
|
THEO |
|
1
BUENO 2011 limit is for manifest left-right symmetric model.
|
|
2
CZAKON 1999 perform a simultaneous fit to charged and neutral sectors.
|
|
3
ALVES 2024 limit quoted above is from B( ${{\mathit \pi}}$ $\rightarrow$ ${{\mathit e}}{{\mathit \nu}}$)/B( ${{\mathit \pi}}$ $\rightarrow$ ${{\mathit \mu}}{{\mathit \nu}}$) assuming ${\mathit m}_{{{\mathit \nu}_{{{R}}}}}$ = 50 MeV in vanishing ${{\mathit W}_{{{L}}}}−{{\mathit W}_{{{R}}}}$ mixing limit. ${{\mathit g}_{{{L}}}}$ = ${{\mathit g}_{{{R}}}}$ is assumed. See their Fig. 2 for limits in ${\mathit m}_{{{\mathit \nu}_{{{R}}}}}−{\mathit m}_{{{\mathit W}_{{{R}}}}}$ plane.
|
|
4
PRIEELS 2014 limit is from ${{\mathit \mu}^{+}}$ $\rightarrow$ ${{\mathit e}^{+}}{{\mathit \nu}}{{\overline{\mathit \nu}}}$ decay parameter ${{\mathit \xi}^{''}}$, which is determined by the positron polarization measurement.
|
|
5
WAUTERS 2010 limit is from a measurement of the asymmetry parameter of polarized ${}^{60}\mathrm {Co}$ ${{\mathit \beta}}$ decays. The listed limit assumes no mixing.
|
|
6
ZHANG 2008 limit uses a lattice QCD calculation of the relevant hadronic matrix elements, while BEALL 1982 limit used the vacuum saturation approximation.
|
|
7
MELCONIAN 2007 measure the neutrino angular asymmetry in ${{\mathit \beta}^{+}}$-decays of polarized ${}^{37}\mathrm {K}$, stored in a magneto-optical trap. Result is consistent with SM prediction and does not constrain the ${{\mathit W}_{{{L}}}}$ ${{\mathit W}_{{{R}}}}$ mixing angle appreciably.
|
|
8
SCHUMANN 2007 limit is from measurements of the asymmetry $\langle \overrightarrow{{\mathit p}}_{{{\mathit \nu}}}\cdot{}{{\mathit \sigma}_{{{n}}}}\rangle $ in the $\beta $ decay of polarized neutrons. Zero mixing is assumed.
|
|
9
CYBURT 2005 limit follows by requiring that three light ${{\mathit \nu}_{{{R}}}}$'s decouple when ${{\mathit T}_{{{{dec}}}}}$ $>$ 140 MeV. For different ${{\mathit T}_{{{{dec}}}}}$, the bound becomes ${{\mathit M}}_{{{\mathit W}_{{{R}}}}}$ $>$ 3.3 TeV (${{\mathit T}_{{{{dec}}}}}$ $/$ 140 MeV)${}^{3/4}$.
|
|
10
THOMAS 2001 limit is from measurement of ${{\mathit \beta}^{+}}$ polarization in decay of polarized ${}^{12}\mathrm {N}$. The listed limit assumes no mixing.
|
|
11
ACKERSTAFF 1999D limit is from ${{\mathit \tau}}$ decay parameters. Limit increase to 145 GeV for zero mixing.
|
|
12
BARENBOIM 1998 assumes minimal left-right model with Higgs of SU(2)$_{\mathit R}$ in SU(2)$_{\mathit L}$ doublet. For Higgs in SU(2)$_{\mathit L}$ triplet, ${\mathit m}_{{{\mathit W}_{{{R}}}}}>$1100 GeV. Bound calculated from effect of corresponding ${{\mathit Z}_{{{LR}}}}$ on electroweak data through ${{\mathit Z}}-{{\mathit Z}_{{{LR}}}}$ mixing.
|
|
13
The quoted limit is from ${{\mathit \mu}}$ decay parameters. BARENBOIM 1997 also evaluate limit from ${{\mathit K}_{{{L}}}}-{{\mathit K}_{{{S}}}}$ mass difference.
|
|
14
STAHL 1997 limit is from fit to ${{\mathit \tau}}$-decay parameters.
|
|
15
ALLET 1996 measured polarization-asymmetry correlation in ${}^{12}\mathrm {N}$ ${{\mathit \beta}^{+}}$ decay. The listed limit assumes zero $\mathit L-\mathit R$ mixing.
|
|
16
KUZNETSOV 1995 limit is from measurements of the asymmetry $\langle{}\overrightarrow{{\mathit p}}_{{{\mathit \nu}}}\cdot{}{{\mathit \sigma}_{{{n}}}}\rangle{}$ in the $\beta $ decay of polarized neutrons. Zero mixing assumed. See also KUZNETSOV 1994B.
|
|
17
KUZNETSOV 1994B limit is from measurements of the asymmetry $\langle{}\overrightarrow{{\mathit p}}_{{{\mathit \nu}}}\cdot{}{{\mathit \sigma}_{{{n}}}}\rangle{}$ in the $\beta $ decay of polarized neutrons. Zero mixing assumed.
|
|
18
BHATTACHARYYA 1993 uses ${{\mathit Z}}-{{\mathit Z}^{\,'}}$ mixing limit from LEP '90 data, assuming a specific Higgs sector of SU(2)$_{\mathit L}{\times }SU(2)_{\mathit R}{\times }$U(1) gauge model. The limit is for ${\mathit m}_{{{\mathit t}}}$=200 GeV and slightly improves for smaller ${\mathit m}_{{{\mathit t}}}$.
|
|
19
SEVERIJNS 1993 measured polarization-asymmetry correlation in ${}^{107}\mathrm {In}$ ${{\mathit \beta}^{+}}$ decay. The listed limit assumes zero ${{\mathit L}}-{{\mathit R}}$ mixing. Value quoted here is from SEVERIJNS 1994 erratum.
|
|
20
IMAZATO 1992 measure positron asymmetry in ${{\mathit K}^{+}}$ $\rightarrow$ ${{\mathit \mu}^{+}}{{\mathit \nu}_{{{\mu}}}}$ decay and obtain $\xi {{\mathit P}_{{{\mu}}}}>0.990$ (90$\%$ CL). If ${{\mathit W}_{{{R}}}}$ couples to ${{\mathit u}}{{\overline{\mathit s}}}$ with full weak strength ($\mathit V{}^{\mathit R}_{{{\mathit u}} {{\mathit s}}}$=1), the result corresponds to ${\mathit m}_{{{\mathit W}_{{{R}}}}}>$653 GeV. See their Fig.$~$4 for ${\mathit m}_{{{\mathit W}_{{{R}}}}}$ limits for general $\vert \mathit V{}^{\mathit R}_{{{\mathit u}} {{\mathit s}}}\vert ^2=1−\vert \mathit V{}^{\mathit R}_{{{\mathit u}} {{\mathit d}}}\vert ^2$.
|
|
21
POLAK 1992B limit is from fit to muon decay parameters and is essentially determined by JODIDIO 1986 data assuming $\zeta $=0. Supersedes POLAK 1991.
|
|
22
AQUINO 1991 limits obtained from neutron lifetime and asymmetries together with unitarity of the CKM matrix. Manifest left-right symmetry assumed. Stronger of the two limits also includes muon decay results.
|
|
23
COLANGELO 1991 limit uses hadronic matrix elements evaluated by QCD sum rule and is less restrictive than BEALL 1982 limit which uses vacuum saturation approximation. Manifest left-right symmetry assumed.
|
|
24
POLAK 1991 limit is from fit to muon decay parameters and is essentially determined by JODIDIO 1986 data assuming $\zeta $=0. Superseded by POLAK 1992B.
|
|
25
BARBIERI 1989B limit holds for ${\mathit m}_{{{\mathit \nu}_{{{R}}}}}{}\leq{}$10 MeV.
|
|
26
LANGACKER 1989B limit is for any ${{\mathit \nu}_{{{R}}}}$ mass (either Dirac or Majorana) and for a general class of right-handed quark mixing matrices.
|
|
27
BALKE 1988 limit is for ${\mathit m}_{\mathrm {{{\mathit \nu}}_{{{\mathit e}} {{\mathit R}}}}}$ = 0 and ${\mathit m}_{\mathrm {{{\mathit \nu}}_{{{\mathit \mu}} {{\mathit R}}}}}{}\leq{}$ 50 MeV. Limits come from precise measurements of the muon decay asymmetry as a function of the positron energy.
|
|
28
JODIDIO 1986 is the same TRIUMF experiment as STOKER 1985 (and CARR 1983); however, it uses a different technique. The results given here are combined results of the two techniques. The technique here involves precise measurement of the end-point ${{\mathit e}^{+}}$ spectrum in the decay of the highly polarized ${{\mathit \mu}^{+}}$.
|
|
29
STOKER 1985 is same TRIUMF experiment as CARR 1983. Here they measure the decay ${{\mathit e}^{+}}$ spectrum asymmetry above 46 ${\mathrm {MeV}}/\mathit c$ using a muon-spin-rotation technique. Assumed a light right-handed neutrino. Quoted limits are from combining with CARR 1983.
|
|
30
BERGSMA 1983 set limit ${\mathit m}_{{{\mathit W}_{{{2}}}}}/{\mathit m}_{{{\mathit W}_{{{1}}}}}$ $>$1.9 at CL = 90$\%$.
|
|
31
CARR 1983 is TRIUMF experiment with a highly polarized ${{\mathit \mu}^{+}}$ beam. Looked for deviation from $\mathit V−\mathit A$ at the high momentum end of the decay ${{\mathit e}^{+}}$ energy spectrum. Limit from previous world-average muon polarization parameter is ${\mathit m}_{{{\mathit W}_{{{R}}}}}$ $>$240 GeV. Assumes a light right-handed neutrino.
|
|
32
BEALL 1982 limit is obtained assuming that ${{\mathit W}_{{{R}}}}$ contribution to ${{\mathit K}_L^0}$ $-{{\mathit K}_S^0}$ mass difference is smaller than the standard one, neglecting the top quark contributions. Manifest left-right symmetry assumed.
|
