Changes between Version 2 and Version 3 of kkg_FV

Timestamp:

Nov 3, 2015, 4:11:04 PM (9 years ago)

Author:

Elizabeth Druekeel

Comment:

--

kkg_FV

@@ -14 +14 @@
 Colored vector bosons from new strong dynamics, Kaluza-Klein gluons or KKg’s (G*) in a dual 5D picture, have been searched for mainly in the t-tbar channel.  The analysis in [http://arxiv.org/pdf/1409.7607v2.pdf 1409.7607v2] analyzes the tc decay as depicted below:
 [[Image(wiki:KKg.png)]]
-In this model, the third generation quarks couple differently than the light quarks under an extended 
+The benchmark adopted here is a simple renormalizable model of an
+extended color gauge sector, which realizes next-to-minimal flavor violation (NMFV). In this model, the third generation quarks couple differently than the light quarks under an extended 
 {{{
 #!latex
 $SU(3)_1 \times SU(3)_2$
 }}}
-color gauge group.  The mixing between light and third generation quarks is induced by the interactions of all three generation quarks with a set of new heavy vector0like quarks.  The model reproduces the CKM mixing and generates flavor-changing neutral currents (FCNCs) from non-standard interactions.  Due to the specific structure of the model, dangerous FCNCs are naturally suppressed and a large portion of the model parameter space is allowed by the data on meson mixing process and on 
+color gauge group.  The mixing between light and third generation quarks is induced by the interactions of all three generation quarks with a set of new heavy vector-like quarks.  The model reproduces the CKM mixing and generates flavor-changing neutral currents (FCNCs) from non-standard interactions.  Due to the specific structure of the model, dangerous FCNCs are naturally suppressed and a large portion of the model parameter space is allowed by the data on meson mixing process and on 
 {{{
 #!latex
-$b \to \gamma$.
+$b \to s\gamma$.
+}}}
+The model has the color gauge structure
+{{{
+#!latex
+$SU(3)_1 \times SU(3)_2$
 }}}
 The extended color symmetry is broken down to 
@@ -37 +43 @@
 {{{
 #!latex
-$\bf 3, \bar{3}$
+$(\bf 3, \bar{3})$
 }}}
-under the color gauge structure.  It is assumed that color gauge breaking occurs at a scale much higher than the electroweak scale.
+under the color gauge structure.  It is assumed that color gauge breaking occurs at a scale much higher than the electroweak scale, u>>v.
 
 Breaking the color symmetry induces a mixing between the 
@@ -56 +62 @@
 $\cot\omega = \frac{g_1}{g_2} \qquad g_s = g_1 \sin\omega = g_2 \cos\omega$,
 }}}
-where g_s is the QCD strong coupling and g_1 and g_2 are the SU(3)_1 and SU(3)_2 gauge couplings, respectively.  The mixing diagonalization reveals two color vector boson mass eigenstates: the mass-less SM gluon and a new massive color-octet vector boson G* given by
+where g_s is the QCD strong coupling and g_1, g_2 are the SU(3)_1 and SU(3)_2 gauge couplings, respectively.  The mixing diagonalization reveals two color vector boson mass eigenstates: the mass-less SM gluon and a new massive color-octet vector boson G* given by
 {{{
 #!latex
@@ -83 +89 @@
 
 
-G*'s form an extended color group and can be produced at the LHC by quark-antiquark fusion determined by the G* coupling to light quarks 
+The G* can be produced at the LHC by quark-antiquark fusion determined by the G* coupling to light quarks 
 {{{
 #!latex
@@ -102 +108 @@
 $\Gamma[G^{*} \to t_L \bar c_L]=\Gamma[G^{*} \to c_L \bar t_L]\simeq \left(V_{cb}\right)^2 \frac{g^2_s}{48\pi} M_{G^{*}} \left( \cot\omega+\tan\omega \right)^2,$
 }}}
-where V_cb=0.0415$ is the CKM matrix element. Note here that G* FCNCs are induced by the mixing among left-handed quarks generated by the exchange of heavy vector-like quarks. This mixing is controlled by the 3x3 matrices U_L and D_L in the up- and down-quark sectors, respectively. In particular, the G* to tc flavor violating decay is controlled by the 
+where 
+{{{
+#!latex
+$V_{cb}=0.0415$
+}}}
+is the CKM matrix element. Note here that G* FCNCs are induced by the mixing among left-handed quarks generated by the exchange of heavy vector-like quarks. This mixing is controlled by the 3x3 matrices U_L and D_L in the up- and down-quark sectors, respectively. In particular, the 
+{{{
+#!latex
+$G* \to tc$
+}}}
+flavor violating decay is controlled by the 
 {{{
 #!latex
@@ -120 +136 @@
 {{{
 #!latex
-$b\to s \gamma$. \rm{So } $(D_L)_{23}$
+$b\to s \gamma$. 
+}}}
+So
+{{{
+#!latex
+$(D_L)_{23}$
 }}}
 is thus forced to be small and, as a consequence, 
@@ -127 +148 @@
 $(U_L)_{23}\simeq V_{cb}$.
 }}}
+See more details in
+* [http://arxiv.org/pdf/1409.7607v2.pdf 1409.7607v2]
+* [http://arxiv.org/pdf/1412.3094.pdf 1412.3094]
 
-== Note ==
+== Model Files ==
 
-Need to reread and make sure everything is the same as paper.
+* [attachment:proc_card_mg5.dat proc_card]: for generation of 500 GeV KKg (place in Cards/)
+* [attachment:run_card.dat run_card]: for generation of 500 GeV KKg (place in Cards/)
+* [attachment:kkg_FV.zip kkg_FV]: the model and parameter cards for specific mass generations
+
+== Generation specifics ==
+   
+In [http://arxiv.org/pdf/1409.7607v2.pdf 1409.7607v2], the samples were generated with the mass as the scale, dsqrt_q2fact1, and dsqrt_q2fact2 in the run_card.  These samples were also generated without the pre-included !MadGraph cuts as demonstrated in the run_card.dat for 500 GeV mass included above.  The specific generations run were 
+{{{
+p p > kkg > b~ c l- vl~ @1
+p p > kkg > b c~ l+ vl @2
+}}}
+To generate a specific mass, param_card.dat in the generation file to the card of the appropriate mass in the param_cards directory (included as part of the model zip file).