Landscape

Select a theory SU(2): 4 fund + 4 anti-fund (not completed) SU(2): 1 Adj + 1 fund + 1 anti-fund SU(2): 1 Adj + 2 fund + 2 anti-fund (not completed) SU(2): 1 Adj + 3 fund + 3 anti-fund (not completed) SU(3): 1 Adj + 1 fund + 1 anti-fund SU(3): 1 Adj + 2 fund + 2 anti-fund (not completed) SO(5): 5 vector (not completed) SO(5): 1 Adj + 1 vector SO(5): 1 Adj + 2 vector SO(5): 1 Symm SO(5): 1 Symm + 1 vector SO(5): 1 Symm + 2 vector Sp(2): 1 Adj + 2 fund Sp(2): 1 14 + 2 fund Sp(2): 2 Adj G2: 1 Adj + 1 fund All theories

$a$ =

$c$ =

$\leq a \leq$

$\leq c \leq$

id =

Check if you want only theories with rational charges.

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.

#	Theory	Superpotential	Central charge $a$	Central charge $c$	Ratio $a/c$	Matter field: $R$-charge	U(1) part of $F_{UV}$	Rank of $F_{UV}$	Rational
4088	SU2adj1nf2	$\phi_1q_1^2$ + $ M_1q_2\tilde{q}_1$ + $ M_2\phi_1^2$ + $ M_3q_2\tilde{q}_2$ + $ M_4\tilde{q}_1\tilde{q}_2$ + $ M_1M_4$ + $ M_5q_1\tilde{q}_1$ + $ M_6q_1q_2$ + $ M_1M_5$ + $ M_5M_7$ + $ M_8\phi_1q_2^2$	0.6393	0.8004	0.7988	[X:[], M:[1.1721, 1.2186, 0.7348, 0.8279, 0.8279, 0.7348, 1.1721, 0.6882], q:[0.8047, 0.4605], qb:[0.3674, 0.8047], phi:[0.3907]]	[X:[], M:[[-6], [4], [-14], [6], [6], [-14], [-6], [-24]], q:[[1], [13]], qb:[[-7], [1]], phi:[[-2]]]	1

Relevant Operators	Marginal Operators	$n_{marginal}$$-$$|F_{IR}|$	Superconformal Index	Refined index
$M_8$, $ M_3$, $ M_6$, $ M_4$, $ \phi_1\tilde{q}_1^2$, $ M_1$, $ M_7$, $ M_2$, $ \phi_1q_2\tilde{q}_1$, $ M_8^2$, $ M_3M_8$, $ M_6M_8$, $ M_3^2$, $ M_3M_6$, $ M_6^2$, $ M_4M_8$, $ M_3M_4$, $ M_4M_6$, $ \phi_1\tilde{q}_1\tilde{q}_2$, $ q_1\tilde{q}_2$, $ M_4^2$, $ \phi_1q_2\tilde{q}_2$, $ M_8\phi_1\tilde{q}_1^2$, $ M_1M_8$, $ M_7M_8$, $ M_3\phi_1\tilde{q}_1^2$, $ M_6\phi_1\tilde{q}_1^2$, $ M_1M_3$, $ M_1M_6$, $ M_3M_7$, $ M_6M_7$, $ M_2M_8$, $ M_8\phi_1q_2\tilde{q}_1$, $ M_2M_3$, $ M_2M_6$, $ M_6\phi_1q_2\tilde{q}_1$, $ M_4\phi_1\tilde{q}_1^2$	$M_4M_7$, $ \phi_1\tilde{q}_2^2$	-1	t^2.06 + 2*t^2.2 + t^2.48 + t^3.38 + 2*t^3.52 + 2*t^3.66 + t^4.13 + 2*t^4.27 + 3*t^4.41 + t^4.55 + 2*t^4.69 + t^4.83 + t^4.97 + t^5.44 + 4*t^5.58 + 5*t^5.72 + 3*t^5.86 - t^6. + t^6.19 - t^6.28 + 2*t^6.33 + 3*t^6.47 + 5*t^6.61 + 3*t^6.75 + 5*t^6.89 + 5*t^7.03 + 2*t^7.17 - t^7.31 - 2*t^7.45 + t^7.51 - t^7.59 + 4*t^7.65 + 8*t^7.79 + 7*t^7.92 + 3*t^8.06 - 3*t^8.2 + t^8.26 - t^8.34 + 2*t^8.4 - 3*t^8.48 + 3*t^8.54 - 2*t^8.62 + 5*t^8.68 - 2*t^8.76 + 8*t^8.82 + 7*t^8.96 - t^4.17/y - t^6.24/y - (2*t^6.38)/y + (2*t^7.27)/y + t^7.41/y + t^7.55/y + (2*t^7.69)/y + (2*t^7.97)/y + t^8.11/y - t^8.3/y - t^8.44/y + t^8.58/y + (6*t^8.72)/y + (5*t^8.86)/y - t^4.17*y - t^6.24*y - 2*t^6.38*y + 2*t^7.27*y + t^7.41*y + t^7.55*y + 2*t^7.69*y + 2*t^7.97*y + t^8.11*y - t^8.3*y - t^8.44*y + t^8.58*y + 6*t^8.72*y + 5*t^8.86*y	t^2.06/g1^24 + (2*t^2.2)/g1^14 + g1^6*t^2.48 + t^3.38/g1^16 + (2*t^3.52)/g1^6 + 2*g1^4*t^3.66 + t^4.13/g1^48 + (2*t^4.27)/g1^38 + (3*t^4.41)/g1^28 + t^4.55/g1^18 + (2*t^4.69)/g1^8 + g1^2*t^4.83 + g1^12*t^4.97 + t^5.44/g1^40 + (4*t^5.58)/g1^30 + (5*t^5.72)/g1^20 + (3*t^5.86)/g1^10 - t^6. + t^6.19/g1^72 - g1^20*t^6.28 + (2*t^6.33)/g1^62 + (3*t^6.47)/g1^52 + (5*t^6.61)/g1^42 + (3*t^6.75)/g1^32 + (5*t^6.89)/g1^22 + (5*t^7.03)/g1^12 + (2*t^7.17)/g1^2 - g1^8*t^7.31 - 2*g1^18*t^7.45 + t^7.51/g1^64 - g1^28*t^7.59 + (4*t^7.65)/g1^54 + (8*t^7.79)/g1^44 + (7*t^7.92)/g1^34 + (3*t^8.06)/g1^24 - (3*t^8.2)/g1^14 + t^8.26/g1^96 - t^8.34/g1^4 + (2*t^8.4)/g1^86 - 3*g1^6*t^8.48 + (3*t^8.54)/g1^76 - 2*g1^16*t^8.62 + (5*t^8.68)/g1^66 - 2*g1^26*t^8.76 + (8*t^8.82)/g1^56 + (7*t^8.96)/g1^46 - t^4.17/(g1^2*y) - t^6.24/(g1^26*y) - (2*t^6.38)/(g1^16*y) + (2*t^7.27)/(g1^38*y) + t^7.41/(g1^28*y) + t^7.55/(g1^18*y) + (2*t^7.69)/(g1^8*y) + (2*g1^12*t^7.97)/y + (g1^22*t^8.11)/y - t^8.3/(g1^50*y) - t^8.44/(g1^40*y) + t^8.58/(g1^30*y) + (6*t^8.72)/(g1^20*y) + (5*t^8.86)/(g1^10*y) - (t^4.17*y)/g1^2 - (t^6.24*y)/g1^26 - (2*t^6.38*y)/g1^16 + (2*t^7.27*y)/g1^38 + (t^7.41*y)/g1^28 + (t^7.55*y)/g1^18 + (2*t^7.69*y)/g1^8 + 2*g1^12*t^7.97*y + g1^22*t^8.11*y - (t^8.3*y)/g1^50 - (t^8.44*y)/g1^40 + (t^8.58*y)/g1^30 + (6*t^8.72*y)/g1^20 + (5*t^8.86*y)/g1^10

Deformation

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

#	Superpotential	Central Charge $a$	Central Charge $c$	Ratio $a/c$	$R$-charges	Superconformal Index	More Info.	Rational

Equivalent Fixed Points from Other Seed Theories

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

#	Theory	Superpotential	Central Charge $a$	Central Charge $c$	Ratio $a/c$	$R$-charges	Superconformal Index	More 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.

#	Theory	Superpotential	Central Charge $a$	Central Charge $c$	Ratio $a/c$	$R$-charges	Superconformal Index	More Info.	Rational
1606	SU2adj1nf2	$\phi_1q_1^2$ + $ M_1q_2\tilde{q}_1$ + $ M_2\phi_1^2$ + $ M_3q_2\tilde{q}_2$ + $ M_4\tilde{q}_1\tilde{q}_2$ + $ M_1M_4$ + $ M_5q_1\tilde{q}_1$ + $ M_6q_1q_2$ + $ M_1M_5$ + $ M_5M_7$	0.6187	0.7598	0.8142	[X:[], M:[1.1749, 1.2167, 0.7414, 0.8251, 0.8251, 0.7414, 1.1749], q:[0.8042, 0.4544], qb:[0.3707, 0.8042], phi:[0.3916]]	2*t^2.22 + t^2.48 + t^3.4 + 2*t^3.52 + 2*t^3.65 + t^3.9 + 3*t^4.45 + 2*t^4.7 + t^4.83 + t^4.95 + 2*t^5.62 + 3*t^5.75 + 3*t^5.87 - t^6. - t^4.17/y - t^4.17*y	detail