Landscape


$a$ =

$c$ =

$\leq a \leq$

$\leq c \leq$

id =



Chosen Fixed Point

Here is the data for the chosen fixed point.
$F_{UV}$ represents the flavor symmetries in the UV Lagrangian, and $F_{IR}$ represents the flavor symmetries in the IR. $F_{UV}$ and $F_{IR}$ can differ due to accidental symmetry enhancement.
The number of marginal operators, $n_{marginal}$, minus the dimension of flavor symmetries in IR, $|F_{IR}|$, corresponds to the coefficient of $t^6$ in the superconformal index.

#TheorySuperpotentialCentral charge $a$Central charge $c$Ratio $a/c$Matter field: $R$-chargeU(1) part of $F_{UV}$Rank of $F_{UV}$Rational
55325 SU2adj1nf2 $M_1q_1q_2$ + $ M_2q_1\tilde{q}_1$ + $ \phi_1q_1^2$ + $ M_3q_1\tilde{q}_2$ + $ M_3^2$ + $ M_4\phi_1\tilde{q}_2^2$ + $ M_5\phi_1^2$ + $ M_6\phi_1q_2\tilde{q}_2$ + $ M_1\phi_1\tilde{q}_1\tilde{q}_2$ 0.6431 0.8465 0.7597 [X:[], M:[0.7515, 0.7535, 1.0, 0.998, 0.998, 0.7495], q:[0.7495, 0.499], qb:[0.497, 0.2505], phi:[0.501]] [X:[], M:[[3], [7], [0], [-4], [-4], [-1]], q:[[-1], [-2]], qb:[[-6], [1]], phi:[[2]]] 1
Relevant OperatorsMarginal Operators$n_{marginal}$$-$$|F_{IR}|$Superconformal IndexRefined index
$\tilde{q}_1\tilde{q}_2$, $ M_6$, $ q_2\tilde{q}_2$, $ M_1$, $ M_2$, $ q_2\tilde{q}_1$, $ M_4$, $ M_5$, $ M_3$, $ \phi_1\tilde{q}_1\tilde{q}_2$, $ \phi_1\tilde{q}_1^2$, $ \tilde{q}_1^2\tilde{q}_2^2$, $ \phi_1q_2\tilde{q}_1$, $ M_6\tilde{q}_1\tilde{q}_2$, $ q_2\tilde{q}_1\tilde{q}_2^2$, $ M_6^2$, $ \phi_1q_2^2$, $ M_6q_2\tilde{q}_2$, $ M_1\tilde{q}_1\tilde{q}_2$, $ q_2^2\tilde{q}_2^2$, $ M_1M_6$, $ \phi_1q_1\tilde{q}_2$, $ M_2\tilde{q}_1\tilde{q}_2$, $ M_1^2$, $ M_2M_6$, $ M_2q_2\tilde{q}_2$, $ M_1M_2$, $ M_2^2$, $ q_2\tilde{q}_1^2\tilde{q}_2$, $ M_6q_2\tilde{q}_1$, $ M_4\tilde{q}_1\tilde{q}_2$, $ M_5\tilde{q}_1\tilde{q}_2$, $ q_2^2\tilde{q}_1\tilde{q}_2$, $ M_4M_6$, $ M_5M_6$, $ \phi_1q_1\tilde{q}_1$, $ M_4q_2\tilde{q}_2$, $ M_5q_2\tilde{q}_2$, $ M_3\tilde{q}_1\tilde{q}_2$, $ M_1M_4$, $ M_1M_5$, $ M_3M_6$, $ \phi_1q_1q_2$, $ M_2q_2\tilde{q}_1$, $ M_3q_2\tilde{q}_2$, $ M_1M_3$, $ M_2M_4$, $ M_2M_5$, $ q_2^2\tilde{q}_1^2$, $ M_4q_2\tilde{q}_1$, $ M_5q_2\tilde{q}_1$, $ M_4^2$, $ M_4M_5$, $ M_5^2$, $ M_3q_2\tilde{q}_1$, $ \phi_1\tilde{q}_1^2\tilde{q}_2^2$, $ M_3M_4$, $ M_3M_5$, $ M_6\phi_1\tilde{q}_1\tilde{q}_2$ . -2 t^2.24 + 3*t^2.25 + t^2.26 + 3*t^2.99 + t^3. + t^3.75 + 5*t^4.49 + 8*t^4.5 + 4*t^4.51 + t^4.52 + t^5.23 + 10*t^5.24 + 7*t^5.25 + 3*t^5.98 + 6*t^5.99 - 2*t^6. - t^6.01 + 7*t^6.73 + 7*t^6.74 + 13*t^6.75 + 8*t^6.76 + 3*t^6.77 + 2*t^6.78 + 2*t^7.47 + 6*t^7.48 + 24*t^7.49 + 12*t^7.5 + 3*t^7.51 + 5*t^8.22 + 9*t^8.23 + 12*t^8.24 - 13*t^8.25 - 5*t^8.26 - t^8.27 + t^8.96 + 5*t^8.97 + 22*t^8.98 + 12*t^8.99 - t^4.5/y - t^6.75/y - (2*t^6.76)/y + (2*t^7.49)/y + (4*t^7.5)/y + (4*t^7.51)/y + t^8.23/y + (11*t^8.24)/y + (10*t^8.25)/y + t^8.26/y + (2*t^8.98)/y + (7*t^8.99)/y - t^4.5*y - t^6.75*y - 2*t^6.76*y + 2*t^7.49*y + 4*t^7.5*y + 4*t^7.51*y + t^8.23*y + 11*t^8.24*y + 10*t^8.25*y + t^8.26*y + 2*t^8.98*y + 7*t^8.99*y t^2.24/g1^5 + (2*t^2.25)/g1 + g1^3*t^2.25 + g1^7*t^2.26 + t^2.99/g1^8 + (2*t^2.99)/g1^4 + t^3. + t^3.75/g1^3 + (2*t^4.49)/g1^10 + (3*t^4.49)/g1^6 + (5*t^4.5)/g1^2 + 3*g1^2*t^4.5 + 3*g1^6*t^4.51 + g1^10*t^4.51 + g1^14*t^4.52 + t^5.23/g1^13 + (4*t^5.24)/g1^9 + (6*t^5.24)/g1^5 + (5*t^5.25)/g1 + 2*g1^3*t^5.25 + t^5.98/g1^16 + (2*t^5.98)/g1^12 + (4*t^5.99)/g1^8 + (2*t^5.99)/g1^4 - 2*t^6. - g1^4*t^6.01 + (2*t^6.73)/g1^15 + (5*t^6.73)/g1^11 + (7*t^6.74)/g1^7 + (8*t^6.75)/g1^3 + 5*g1*t^6.75 + 5*g1^5*t^6.76 + 3*g1^9*t^6.76 + 3*g1^13*t^6.77 + g1^17*t^6.78 + g1^21*t^6.78 + (2*t^7.47)/g1^18 + (6*t^7.48)/g1^14 + (11*t^7.49)/g1^10 + (13*t^7.49)/g1^6 + (8*t^7.5)/g1^2 + 4*g1^2*t^7.5 + 2*g1^6*t^7.51 + g1^10*t^7.51 + t^8.22/g1^21 + (4*t^8.22)/g1^17 + (9*t^8.23)/g1^13 + (9*t^8.24)/g1^9 + (3*t^8.24)/g1^5 - (6*t^8.25)/g1 - 7*g1^3*t^8.25 - 5*g1^7*t^8.26 - g1^11*t^8.27 + t^8.96/g1^24 + (5*t^8.97)/g1^20 + (9*t^8.98)/g1^16 + (13*t^8.98)/g1^12 + (8*t^8.99)/g1^8 + (4*t^8.99)/g1^4 - (g1^2*t^4.5)/y - (g1*t^6.75)/y - (g1^5*t^6.76)/y - (g1^9*t^6.76)/y + (2*t^7.49)/(g1^6*y) + t^7.5/(g1^2*y) + (3*g1^2*t^7.5)/y + (3*g1^6*t^7.51)/y + (g1^10*t^7.51)/y + t^8.23/(g1^13*y) + (4*t^8.24)/(g1^9*y) + (7*t^8.24)/(g1^5*y) + (6*t^8.25)/(g1*y) + (4*g1^3*t^8.25)/y + (g1^7*t^8.26)/y + (2*t^8.98)/(g1^12*y) + (3*t^8.99)/(g1^8*y) + (4*t^8.99)/(g1^4*y) - g1^2*t^4.5*y - g1*t^6.75*y - g1^5*t^6.76*y - g1^9*t^6.76*y + (2*t^7.49*y)/g1^6 + (t^7.5*y)/g1^2 + 3*g1^2*t^7.5*y + 3*g1^6*t^7.51*y + g1^10*t^7.51*y + (t^8.23*y)/g1^13 + (4*t^8.24*y)/g1^9 + (7*t^8.24*y)/g1^5 + (6*t^8.25*y)/g1 + 4*g1^3*t^8.25*y + g1^7*t^8.26*y + (2*t^8.98*y)/g1^12 + (3*t^8.99*y)/g1^8 + (4*t^8.99*y)/g1^4


Deformation

Here is the data for the deformed fixed points from the chosen fixed point.

#SuperpotentialCentral Charge $a$ Central Charge $c$ Ratio $a/c$$R$-chargesSuperconformal IndexMore Info.Rational


Equivalent Fixed Points from Other Seed Theories

Here is a list of equivalent fixed points from other gauge theories.

#TheorySuperpotentialCentral Charge $a$ Central Charge $c$ Ratio $a/c$$R$-chargesSuperconformal IndexMore Info.Rational


Equivalent Fixed Points from the Same Seed Theory

Below is a list of equivalent fixed points from the same seed theories.

id Theory Superpotential Central Charge $a$ Central Charge $c$ Ratio $a/c$ $R$-charges More Info. Rational


Previous Theory

The previous fixed point before deforming to get the chosen fixed point.

#TheorySuperpotentialCentral Charge $a$ Central Charge $c$ Ratio $a/c$$R$-chargesSuperconformal IndexMore Info.Rational
46926 SU2adj1nf2 $M_1q_1q_2$ + $ M_2q_1\tilde{q}_1$ + $ \phi_1q_1^2$ + $ M_3q_1\tilde{q}_2$ + $ M_3^2$ + $ M_4\phi_1\tilde{q}_2^2$ + $ M_5\phi_1^2$ + $ M_6\phi_1q_2\tilde{q}_2$ 0.6433 0.8468 0.7596 [X:[], M:[0.7397, 0.7573, 1.0, 1.0012, 1.0012, 0.7409], q:[0.7503, 0.51], qb:[0.4924, 0.2497], phi:[0.4994]] 2*t^2.22 + t^2.23 + t^2.27 + t^2.28 + 3*t^3. + t^3.01 + t^3.72 + 2*t^4.44 + 5*t^4.45 + 2*t^4.49 + 3*t^4.5 + 2*t^4.51 + t^4.54 + t^4.55 + 2*t^4.56 + 3*t^5.22 + 8*t^5.23 + 6*t^5.28 + t^5.29 + t^5.94 + t^5.95 - t^6. - t^4.5/y - t^4.5*y detail