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W2012596303 abstract "Many new physics models beyond the standard model, such as the littlest Higgs models and the left-right twin Higgs models, predict the existence of the large charged Higgs couplings ${H}^{ensuremath{-}}qoverline{b}$ and ${H}^{+}boverline{q}$, where $q=t$ or the new vectorlike heavy quark $T$. On the other hand, some new physics models, like the littlest Higgs, also predict the gauge-Higgs couplings. Such couplings may have rich collider phenomenology. We focus our attention on these couplings induced by the littlest Higgs models and the left-right twin Higgs models and consider their contributions to the production cross section for ${W}^{ifmmodepmelsetextpmfi{}}{H}^{ensuremath{mp}}$ production at the large hadron colliders. We find that the cross sections in the littlest Higgs models on the parton level $ggensuremath{rightarrow}{W}^{ifmmodepmelsetextpmfi{}}{H}^{ensuremath{mp}}$ and $qoverline{q}ensuremath{rightarrow}{W}^{ifmmodepmelsetextpmfi{}}{H}^{ensuremath{mp}}$ ($q=u$, $d$, $s$, $c$, $b$) may reach tens of dozens femtobarns in reasonable parameter space at the collision energy of 14 TeV and that the total cross section can even reach a few hundred femtobarns in certain favored space. While in the left-right twin Higgs models, the production rates are basically one order lower than those in the littlest Higgs models. Therefore, due to the large cross sections of that in the littlest Higgs models, it may be possible to probe the charged Higgs via this process in a certain parameter space." @default.
W2012596303 created "2016-06-24" @default.
W2012596303 creator A5005755055 @default.
W2012596303 creator A5025756253 @default.
W2012596303 creator A5058204770 @default.
W2012596303 date "2013-12-03" @default.
W2012596303 modified "2023-09-26" @default.
W2012596303 title "Charged Higgs production in association withW±at large hadron colliders" @default.
W2012596303 cites W1502155135 @default.
W2012596303 cites W1519971530 @default.
W2012596303 cites W1560266914 @default.
W2012596303 cites W1570624293 @default.
W2012596303 cites W1706693335 @default.
W2012596303 cites W1767233558 @default.
W2012596303 cites W1814723547 @default.
W2012596303 cites W1858542512 @default.
W2012596303 cites W1964716630 @default.
W2012596303 cites W1966311600 @default.
W2012596303 cites W1970928412 @default.
W2012596303 cites W1976740581 @default.
W2012596303 cites W1979522073 @default.
W2012596303 cites W1981240192 @default.
W2012596303 cites W1985904039 @default.
W2012596303 cites W1989660124 @default.
W2012596303 cites W1991437694 @default.
W2012596303 cites W2000332575 @default.
W2012596303 cites W2006184109 @default.
W2012596303 cites W2006544977 @default.
W2012596303 cites W2010765062 @default.
W2012596303 cites W2011385767 @default.
W2012596303 cites W2014108614 @default.
W2012596303 cites W2015992572 @default.
W2012596303 cites W2021342539 @default.
W2012596303 cites W2030894798 @default.
W2012596303 cites W2036403988 @default.
W2012596303 cites W2040039034 @default.
W2012596303 cites W2052880791 @default.
W2012596303 cites W2057161918 @default.
W2012596303 cites W2064748529 @default.
W2012596303 cites W2068351418 @default.
W2012596303 cites W2070086214 @default.
W2012596303 cites W2070559597 @default.
W2012596303 cites W2072910479 @default.
W2012596303 cites W2076214561 @default.
W2012596303 cites W2082691513 @default.
W2012596303 cites W2083474889 @default.
W2012596303 cites W2083876060 @default.
W2012596303 cites W2086005707 @default.
W2012596303 cites W2086074333 @default.
W2012596303 cites W2086927866 @default.
W2012596303 cites W2095324007 @default.
W2012596303 cites W2103439579 @default.
W2012596303 cites W2103705679 @default.
W2012596303 cites W2104193160 @default.
W2012596303 cites W2121129456 @default.
W2012596303 cites W2133842595 @default.
W2012596303 cites W2139805716 @default.
W2012596303 cites W2139830687 @default.
W2012596303 cites W2143735257 @default.
W2012596303 cites W2145250324 @default.
W2012596303 cites W2146713433 @default.
W2012596303 cites W2146789463 @default.
W2012596303 cites W2150901688 @default.
W2012596303 cites W2160306805 @default.
W2012596303 cites W2165739256 @default.
W2012596303 cites W2166083445 @default.
W2012596303 cites W2167727518 @default.
W2012596303 cites W2285251629 @default.
W2012596303 cites W2604059215 @default.
W2012596303 cites W2614392743 @default.
W2012596303 cites W2951969328 @default.
W2012596303 cites W3021874551 @default.
W2012596303 cites W3038119593 @default.
W2012596303 cites W3099682445 @default.
W2012596303 cites W3100707688 @default.
W2012596303 cites W3102059181 @default.
W2012596303 cites W3102931941 @default.
W2012596303 cites W3106498418 @default.
W2012596303 cites W2115344091 @default.
W2012596303 doi "https://doi.org/10.1103/physrevd.88.115006" @default.
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