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
46341	SU2adj1nf2	$M_1q_1q_2$ + $ M_2q_1\tilde{q}_1$ + $ \phi_1q_1^2$ + $ \phi_1^4$ + $ M_3\phi_1q_2\tilde{q}_2$ + $ M_4\phi_1\tilde{q}_1\tilde{q}_2$	0.6999	0.9187	0.7619	[X:[], M:[0.823, 0.823, 0.677, 0.677], q:[0.75, 0.427], qb:[0.427, 0.396], phi:[0.5]]	[X:[], M:[[1, 1], [-1, 0], [1, 0], [-1, -1]], q:[[0, 0], [-1, -1]], qb:[[1, 0], [0, 1]], phi:[[0, 0]]]	2

Relevant Operators	Marginal Operators	$n_{marginal}$$-$$|F_{IR}|$	Superconformal Index	Refined index
$M_3$, $ M_4$, $ M_2$, $ q_2\tilde{q}_2$, $ M_1$, $ \tilde{q}_1\tilde{q}_2$, $ q_2\tilde{q}_1$, $ \phi_1^2$, $ q_1\tilde{q}_2$, $ \phi_1\tilde{q}_2^2$, $ M_3^2$, $ \phi_1\tilde{q}_1^2$, $ M_4^2$, $ \phi_1q_2^2$, $ M_3M_4$, $ \phi_1q_2\tilde{q}_1$, $ M_1M_3$, $ M_2M_3$, $ M_1M_4$, $ M_2M_4$, $ M_3q_2\tilde{q}_2$, $ M_4q_2\tilde{q}_2$, $ M_3\tilde{q}_1\tilde{q}_2$, $ M_4\tilde{q}_1\tilde{q}_2$, $ M_2M_4$, $ M_4q_2\tilde{q}_2$, $ M_1M_3$, $ M_3\tilde{q}_1\tilde{q}_2$, $ M_4q_2\tilde{q}_1$, $ M_3q_2\tilde{q}_1$, $ M_2^2$, $ M_2q_2\tilde{q}_2$, $ q_2^2\tilde{q}_2^2$, $ M_1M_2$, $ \phi_1q_1\tilde{q}_2$, $ M_2\tilde{q}_1\tilde{q}_2$, $ q_2\tilde{q}_1\tilde{q}_2^2$, $ M_1^2$, $ M_1\tilde{q}_1\tilde{q}_2$, $ \tilde{q}_1^2\tilde{q}_2^2$, $ M_3\phi_1^2$, $ \phi_1q_1\tilde{q}_1$, $ q_2\tilde{q}_1^2\tilde{q}_2$, $ M_4\phi_1^2$, $ \phi_1q_1q_2$, $ M_2q_2\tilde{q}_1$, $ q_2^2\tilde{q}_1\tilde{q}_2$, $ q_2^2\tilde{q}_1^2$, $ M_2\phi_1^2$, $ M_4q_1\tilde{q}_2$, $ \phi_1^2q_2\tilde{q}_2$, $ M_1\phi_1^2$, $ M_3q_1\tilde{q}_2$, $ \phi_1^2\tilde{q}_1\tilde{q}_2$, $ \phi_1^2q_2\tilde{q}_1$, $ M_4\phi_1\tilde{q}_2^2$, $ q_1q_2\tilde{q}_2^2$, $ M_3\phi_1\tilde{q}_2^2$, $ q_1\tilde{q}_1\tilde{q}_2^2$	.	-4	2*t^2.03 + 4*t^2.47 + t^2.56 + t^3. + t^3.44 + t^3.88 + 6*t^4.06 + 8*t^4.5 + 2*t^4.59 + 10*t^4.94 + 6*t^5.03 + t^5.12 + 6*t^5.47 + t^5.56 + 4*t^5.91 - 4*t^6. + 8*t^6.09 + 4*t^6.34 + 20*t^6.53 + 6*t^6.62 + t^6.88 + 16*t^6.97 + 10*t^7.06 + 2*t^7.16 + t^7.31 + 16*t^7.41 + 16*t^7.5 + 2*t^7.59 + t^7.69 + t^7.75 + 16*t^7.94 - 8*t^8.03 + 16*t^8.12 + 10*t^8.38 - 18*t^8.47 + 20*t^8.56 + 8*t^8.66 + 10*t^8.81 - t^4.5/y - (2*t^6.53)/y - (2*t^6.97)/y + t^7.06/y + (8*t^7.5)/y + (2*t^7.59)/y + (6*t^7.94)/y + (8*t^8.03)/y + (8*t^8.47)/y - (2*t^8.56)/y + (6*t^8.91)/y - t^4.5*y - 2*t^6.53*y - 2*t^6.97*y + t^7.06*y + 8*t^7.5*y + 2*t^7.59*y + 6*t^7.94*y + 8*t^8.03*y + 8*t^8.47*y - 2*t^8.56*y + 6*t^8.91*y	g1*t^2.03 + t^2.03/(g1*g2) + (2*t^2.47)/g1 + 2*g1*g2*t^2.47 + t^2.56/g2 + t^3. + g2*t^3.44 + g2^2*t^3.88 + 2*g1^2*t^4.06 + (2*t^4.06)/(g1^2*g2^2) + (2*t^4.06)/g2 + 4*t^4.5 + (2*t^4.5)/(g1^2*g2) + 2*g1^2*g2*t^4.5 + t^4.59/(g1*g2^2) + (g1*t^4.59)/g2 + (3*t^4.94)/g1^2 + 4*g2*t^4.94 + 3*g1^2*g2^2*t^4.94 + 3*g1*t^5.03 + (3*t^5.03)/(g1*g2) + t^5.12/g2^2 + (3*t^5.47)/g1 + 3*g1*g2*t^5.47 + t^5.56/g2 + (2*g2*t^5.91)/g1 + 2*g1*g2^2*t^5.91 - 2*t^6. - t^6./(g1^2*g2) - g1^2*g2*t^6. + 2*g1^3*t^6.09 + (2*t^6.09)/(g1^3*g2^3) + (2*t^6.09)/(g1*g2^2) + (2*g1*t^6.09)/g2 + (2*g2^2*t^6.34)/g1 + 2*g1*g2^3*t^6.34 + 6*g1*t^6.53 + (4*t^6.53)/(g1^3*g2^2) + (6*t^6.53)/(g1*g2) + 4*g1^3*g2*t^6.53 + (2*t^6.62)/(g1^2*g2^3) + (2*t^6.62)/g2^2 + (2*g1^2*t^6.62)/g2 + g2^2*t^6.88 + (5*t^6.97)/g1 + (3*t^6.97)/(g1^3*g2) + 5*g1*g2*t^6.97 + 3*g1^3*g2^2*t^6.97 + 3*g1^2*t^7.06 + (3*t^7.06)/(g1^2*g2^2) + (4*t^7.06)/g2 + t^7.16/(g1*g2^3) + (g1*t^7.16)/g2^2 + g2^3*t^7.31 + (4*t^7.41)/g1^3 + (4*g2*t^7.41)/g1 + 4*g1*g2^2*t^7.41 + 4*g1^3*g2^3*t^7.41 + 6*t^7.5 + (5*t^7.5)/(g1^2*g2) + 5*g1^2*g2*t^7.5 + t^7.59/(g1*g2^2) + (g1*t^7.59)/g2 + t^7.69/g2^3 + g2^4*t^7.75 + (5*t^7.94)/g1^2 + 6*g2*t^7.94 + 5*g1^2*g2^2*t^7.94 - 3*g1*t^8.03 - t^8.03/(g1^3*g2^2) - (3*t^8.03)/(g1*g2) - g1^3*g2*t^8.03 + 3*g1^4*t^8.12 + (3*t^8.12)/(g1^4*g2^4) + (3*t^8.12)/(g1^2*g2^3) + (4*t^8.12)/g2^2 + (3*g1^2*t^8.12)/g2 + (3*g2*t^8.38)/g1^2 + 4*g2^2*t^8.38 + 3*g1^2*g2^3*t^8.38 - (7*t^8.47)/g1 - (2*t^8.47)/(g1^3*g2) - 7*g1*g2*t^8.47 - 2*g1^3*g2^2*t^8.47 + 5*g1^2*t^8.56 + (4*t^8.56)/(g1^4*g2^3) + (5*t^8.56)/(g1^2*g2^2) + (2*t^8.56)/g2 + 4*g1^4*g2*t^8.56 + (2*t^8.66)/(g1^3*g2^4) + (2*t^8.66)/(g1*g2^3) + (2*g1*t^8.66)/g2^2 + (2*g1^3*t^8.66)/g2 + (3*g2^2*t^8.81)/g1^2 + 4*g2^3*t^8.81 + 3*g1^2*g2^4*t^8.81 - t^4.5/y - (g1*t^6.53)/y - t^6.53/(g1*g2*y) - t^6.97/(g1*y) - (g1*g2*t^6.97)/y + t^7.06/(g2*y) + (4*t^7.5)/y + (2*t^7.5)/(g1^2*g2*y) + (2*g1^2*g2*t^7.5)/y + t^7.59/(g1*g2^2*y) + (g1*t^7.59)/(g2*y) + t^7.94/(g1^2*y) + (4*g2*t^7.94)/y + (g1^2*g2^2*t^7.94)/y + (4*g1*t^8.03)/y + (4*t^8.03)/(g1*g2*y) + (4*t^8.47)/(g1*y) + (4*g1*g2*t^8.47)/y - (g1^2*t^8.56)/y - t^8.56/(g1^2*g2^2*y) + (3*g2*t^8.91)/(g1*y) + (3*g1*g2^2*t^8.91)/y - t^4.5*y - g1*t^6.53*y - (t^6.53*y)/(g1*g2) - (t^6.97*y)/g1 - g1*g2*t^6.97*y + (t^7.06*y)/g2 + 4*t^7.5*y + (2*t^7.5*y)/(g1^2*g2) + 2*g1^2*g2*t^7.5*y + (t^7.59*y)/(g1*g2^2) + (g1*t^7.59*y)/g2 + (t^7.94*y)/g1^2 + 4*g2*t^7.94*y + g1^2*g2^2*t^7.94*y + 4*g1*t^8.03*y + (4*t^8.03*y)/(g1*g2) + (4*t^8.47*y)/g1 + 4*g1*g2*t^8.47*y - g1^2*t^8.56*y - (t^8.56*y)/(g1^2*g2^2) + (3*g2*t^8.91*y)/g1 + 3*g1*g2^2*t^8.91*y

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
46694	$M_1q_1q_2$ + $ M_2q_1\tilde{q}_1$ + $ \phi_1q_1^2$ + $ \phi_1^4$ + $ M_3\phi_1q_2\tilde{q}_2$ + $ M_4\phi_1\tilde{q}_1\tilde{q}_2$ + $ M_5\phi_1\tilde{q}_2^2$	0.7205	0.9585	0.7517	[X:[], M:[0.827, 0.827, 0.673, 0.673, 0.692], q:[0.75, 0.423], qb:[0.423, 0.404], phi:[0.5]]	2*t^2.02 + t^2.08 + 4*t^2.48 + t^2.54 + t^3. + t^3.46 + 6*t^4.04 + 2*t^4.09 + t^4.15 + 8*t^4.5 + 6*t^4.56 + t^4.61 + 10*t^4.96 + 6*t^5.02 + 2*t^5.08 + 6*t^5.48 + 2*t^5.54 + 2*t^5.94 - 4*t^6. - t^4.5/y - t^4.5*y	detail

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
45977	SU2adj1nf2	$M_1q_1q_2$ + $ M_2q_1\tilde{q}_1$ + $ \phi_1q_1^2$ + $ \phi_1^4$ + $ M_3\phi_1q_2\tilde{q}_2$	0.6791	0.8778	0.7737	[X:[], M:[0.8213, 0.8237, 0.6763], q:[0.75, 0.4287], qb:[0.4263, 0.395], phi:[0.5]]	t^2.03 + 2*t^2.46 + 2*t^2.47 + t^2.56 + t^3. + t^3.44 + t^3.87 + t^3.96 + 3*t^4.06 + t^4.07 + 2*t^4.49 + 2*t^4.5 + t^4.59 + 3*t^4.93 + 7*t^4.94 + 3*t^5.03 + 2*t^5.04 + t^5.13 + 3*t^5.46 + 2*t^5.47 + t^5.56 + 2*t^5.9 + t^5.91 - 2*t^6. - t^4.5/y - t^4.5*y	detail