Percolation threshold

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The percolation threshold is a mathematical concept in percolation theory that describes the formation of long-range connectivity in random systems. Below the threshold a giant connected component does not exist; while above it, there exists a giant component of the order of system size. In engineering and coffee making, percolation represents the flow of fluids through porous media, but in the mathematics and physics worlds it generally refers to simplified lattice models of random systems or networks (graphs), and the nature of the connectivity in them. The percolation threshold is the critical value of the occupation probability p, or more generally a critical surface for a group of parameters p₁, p₂, ..., such that infinite connectivity (percolation) first occurs.^[1]

The most common percolation model is to take a regular lattice, like a square lattice, and make it into a random network by randomly "occupying" sites (vertices) or bonds (edges) with a statistically independent probability p. At a critical threshold p_c, large clusters and long-range connectivity first appear, and this is called the percolation threshold. Depending on the method for obtaining the random network, one distinguishes between the site percolation threshold and the bond percolation threshold. More general systems have several probabilities p₁, p₂, etc., and the transition is characterized by a critical surface or manifold. One can also consider continuum systems, such as overlapping disks and spheres placed randomly, or the negative space (Swiss-cheese models).

To understand the threshold, you can consider a quantity such as the probability that there is a continuous path from one boundary to another along occupied sites or bonds—that is, within a single cluster. For example, one can consider a square system, and ask for the probability P that there is a path from the top boundary to the bottom boundary. As a function of the occupation probability p, one finds a sigmoidal plot that goes from P=0 at p=0 to P=1 at p=1. The larger the square is compared to the lattice spacing, the sharper the transition will be. When the system size goes to infinity, P(p) will be a step function at the threshold value p_c. For finite large systems, P(p_c) is a constant whose value depends upon the shape of the system; for the square system discussed above, P(p_c)=Template:Frac exactly for any lattice by a simple symmetry argument.

There are other signatures of the critical threshold. For example, the size distribution (number of clusters of size s) drops off as a power-law for large s at the threshold, n_s(p_c) ~ s^−τ, where τ is a dimension-dependent percolation critical exponents. For an infinite system, the critical threshold corresponds to the first point (as p increases) where the size of the clusters become infinite.

In the systems described so far, it has been assumed that the occupation of a site or bond is completely random—this is the so-called Bernoulli percolation. For a continuum system, random occupancy corresponds to the points being placed by a Poisson process. Further variations involve correlated percolation, such as percolation clusters related to Ising and Potts models of ferromagnets, in which the bonds are put down by the Fortuin–Kasteleyn method.^[2] In bootstrap or k-sat percolation, sites and/or bonds are first occupied and then successively culled from a system if a site does not have at least k neighbors. Another important model of percolation, in a different universality class altogether, is directed percolation, where connectivity along a bond depends upon the direction of the flow. Another variation of recent interest is Explosive Percolation, whose thresholds are listed on that page.

Over the last several decades, a tremendous amount of work has gone into finding exact and approximate values of the percolation thresholds for a variety of these systems. Exact thresholds are only known for certain two-dimensional lattices that can be broken up into a self-dual array, such that under a triangle-triangle transformation, the system remains the same. Studies using numerical methods have led to numerous improvements in algorithms and several theoretical discoveries.

Simple duality in two dimensions implies that all fully triangulated lattices (e.g., the triangular, union jack, cross dual, martini dual and asanoha or 3-12 dual, and the Delaunay triangulation) all have site thresholds of Template:Frac, and self-dual lattices (square, martini-B) have bond thresholds of Template:Frac.

The notation such as (4,8²) comes from Grünbaum and Shephard,^[3] and indicates that around a given vertex, going in the clockwise direction, one encounters first a square and then two octagons. Besides the eleven Archimedean lattices composed of regular polygons with every site equivalent, many other more complicated lattices with sites of different classes have been studied.

Error bars in the last digit or digits are shown by numbers in parentheses. Thus, 0.729724(3) signifies 0.729724 ± 0.000003, and 0.74042195(80) signifies 0.74042195 ± 0.00000080. The error bars variously represent one or two standard deviations in net error (including statistical and expected systematic error), or an empirical confidence interval, depending upon the source.

For a random tree-like network (i.e., a connected network with no cycle) without degree-degree correlation, it can be shown that such network can have a giant component, and the percolation threshold (transmission probability) is given by

${\displaystyle p_c=\frac{1}{{g_1}^{\prime }(1)}=\frac{⟨k⟩}{⟨k^2⟩-⟨k⟩}}$.

Where ${\displaystyle g_1(z)}$ is the generating function corresponding to the excess degree distribution, ${\displaystyle ⟨k⟩}$ is the average degree of the network and ${\displaystyle ⟨k^2⟩}$ is the second moment of the degree distribution. So, for example, for an ER network, since the degree distribution is a Poisson distribution, where${\displaystyle ⟨k^2⟩=⟨k{⟩}^2+⟨k⟩,}$ the threshold is at ${\displaystyle p_c={⟨k⟩}^{-1}}$.

In networks with low clustering, ${\displaystyle 0<C\ll 1}$, the critical point gets scaled by ${\displaystyle (1-C{)}^{-1}}$ such that:^[4]

${\displaystyle p_c=\frac{1}{1-C}\frac{1}{{g_1}^{\prime }(1)}.}$

This indicates that for a given degree distribution, the clustering leads to a larger percolation threshold, mainly because for a fixed number of links, the clustering structure reinforces the core of the network with the price of diluting the global connections. For networks with high clustering, strong clustering could induce the core–periphery structure, in which the core and periphery might percolate at different critical points, and the above approximate treatment is not applicable.^[5]

Template:Clear

Lattice	z	${\displaystyle \bar{z}}$	Site percolation threshold	Bond percolation threshold
3-12 or super-kagome, (3, 122 )	3	3	0.807900764... = (1 − 2 sin (Template:Pi/18))Template:Frac[7]	0.74042195(80),[8] 0.74042077(2),[9] 0.740420800(2),[10] 0.7404207988509(8),[11][12] 0.740420798850811610(2),[13]
cross, truncated trihexagonal (4, 6, 12)	3	3	0.746,[14] 0.750,[15] 0.747806(4),[7] 0.7478008(2)[11]	0.6937314(1),[11] 0.69373383(72),[8] 0.693733124922(2)[13]
square octagon, bathroom tile, 4-8, truncated square (4, 82)	3	-	0.729,[14] 0.729724(3),[7] 0.7297232(5)[11]	0.6768,[16] 0.67680232(63),[8] 0.6768031269(6),[11] 0.6768031243900113(3),[13]
honeycomb (63)	3	3	0.6962(6),[17] 0.697040230(5),[11] 0.6970402(1),[18] 0.6970413(10),[19] 0.697043(3),[7]	0.652703645... = 1-2 sin (π/18), 1+ p3-3p2=0[20]
kagome (3, 6, 3, 6)	4	4	0.652703645... = 1 − 2 sin(Template:Pi/18)[20]	0.5244053(3),[21] 0.52440516(10),[19] 0.52440499(2),[18] 0.524404978(5),[9] 0.52440572...,[22] 0.52440500(1),[10] 0.524404999173(3),[11][12] 0.524404999167439(4)[23] 0.52440499916744820(1)[13]
ruby,[24] rhombitrihexagonal (3, 4, 6, 4)	4	4	0.620,[14] 0.621819(3),[7] 0.62181207(7)[11]	0.52483258(53),[8] 0.5248311(1),[11] 0.524831461573(1)[13]
square (44)	4	4	0.59274(10),[25] 0.59274605079210(2),[23] 0.59274601(2),[11] 0.59274605095(15),[26] 0.59274621(13),[27] 0.592746050786(3),[28] 0.59274621(33),[29] 0.59274598(4),[30][31] 0.59274605(3),[18] 0.593(1),[32] 0.591(1),[33] 0.569(13),[34] 0.59274(5)[35]	Template:Frac
snub hexagonal, maple leaf[36] (34,6)	5	5	0.579[15] 0.579498(3)[7]	0.43430621(50),[8] 0.43432764(3),[11] 0.4343283172240(6),[13]
snub square, puzzle (32, 4, 3, 4 )	5	5	0.550,[14][37] 0.550806(3)[7]	0.41413743(46),[8] 0.4141378476(7),[11] 0.4141378565917(1),[13]
frieze, elongated triangular(33, 42)	5	5	0.549,[14] 0.550213(3),[7] 0.5502(8)[38]	0.4196(6),[38] 0.41964191(43),[8] 0.41964044(1),[11] 0.41964035886369(2) [13]
triangular (36)	6	6	Template:Frac	0.347296355... = 2 sin (Template:Pi/18), 1 + p3 − 3p = 0[20]

Note: sometimes "hexagonal" is used in place of honeycomb, although in some contexts a triangular lattice is also called a hexagonal lattice. z = bulk coordination number.

In this section, sq-1,2,3 corresponds to square (NN+2NN+3NN),^[39] etc. Equivalent to square-2N+3N+4N,^[40] sq(1,2,3).^[41] tri = triangular, hc = honeycomb.

Lattice	z	Site percolation threshold	Bond percolation threshold
sq-1, sq-2, sq-3, sq-5	4	0.5927...[39][40] (square site)
sq-1,2, sq-2,3, sq-3,5	8	0.407...[39][40][42] (square matching)	0.25036834(6),[18] 0.2503685,[43] 0.25036840(4)[44]
sq-1,3	8	0.337[39][40]	0.2214995[43]
sq-2,5: 2NN+5NN	8	0.337[40]
hc-1,2,3: honeycomb-NN+2NN+3NN	12	0.300,[41] 0.300,[15] 0.302960... = 1-pc(site, hc) [45]
tri-1,2: triangular-NN+2NN	12	0.295,[41] 0.289,[15] 0.290258(19)[46]
tri-2,3: triangular-2NN+3NN	12	0.232020(36),[47] 0.232020(20)[46]
sq-4: square-4NN	8	0.270...[40]
sq-1,5: square-NN+5NN (r ≤ 2)	8	0.277[40]
sq-1,2,3: square-NN+2NN+3NN	12	0.292,[48] 0.290(5) [49] 0.289,[15] 0.288,[39][40]	0.1522203[43]
sq-2,3,5: square-2NN+3NN+5NN	12	0.288[40]
sq-1,4: square-NN+4NN	12	0.236[40]
sq-2,4: square-2NN+4NN	12	0.225[40]
tri-4: triangular-4NN	12	0.192450(36),[47] 0.1924428(50)[46]
hc-2,4: honeycomb-2NN+4NN	12	0.2374[50]
tri-1,3: triangular-NN+3NN	12	0.264539(21)[46]
tri-1,2,3: triangular-NN+2NN+3NN	18	0.225,[48] 0.215,[15] 0.215459(36)[47] 0.2154657(17)[46]
sq-3,4: 3NN+4NN	12	0.221[40]
sq-1,2,5: NN+2NN+5NN	12	0.240[40]	0.13805374[43]
sq-1,3,5: NN+3NN+5NN	12	0.233[40]
sq-4,5: 4NN+5NN	12	0.199[40]
sq-1,2,4: NN+2NN+4NN	16	0.219[40]
sq-1,3,4: NN+3NN+4NN	16	0.208[40]
sq-2,3,4: 2NN+3NN+4NN	16	0.202[40]
sq-1,4,5: NN+4NN+5NN	16	0.187[40]
sq-2,4,5: 2NN+4NN+5NN	16	0.182[40]
sq-3,4,5: 3NN+4NN+5NN	16	0.179[40]
sq-1,2,3,5 asterisk pattern	16	0.208[40]	0.1032177[43]
tri-4,5: 4NN+5NN	18	0.140250(36),[47]
sq-1,2,3,4: NN+2NN+3NN+4NN (${\displaystyle r\le \sqrt{5}}$)	20	0.19671(9),[51] 0.196,[40] 0.196724(10)[52]	0.0841509[43]
sq-1,2,4,5: NN+2NN+4NN+5NN	20	0.177[40]
sq-1,3,4,5: NN+3NN+4NN+5NN	20	0.172[40]
sq-2,3,4,5: 2NN+3NN+4NN+5NN	20	0.167[40]
sq-1,2,3,5,6 asterisk pattern	20		0.0783110[43]
sq-1,2,3,4,5: NN+2NN+3NN+4NN+5NN (${\displaystyle r\le \sqrt{8}}$)	24	0.164[40]
tri-1,4,5: NN+4NN+5NN	24	0.131660(36)[47]
sq-1,...,6: NN+...+6NN (r≤3)	28	0.142[15]	0.0558493[43]
tri-2,3,4,5: 2NN+3NN+4NN+5NN	30	0.117460(36)[47] 0.135823(27)[46]
tri-1,2,3,4,5: NN+2NN+3NN+4NN+5NN	36	0.115,[15] 0.115740(36),[47] 0.1157399(58) [46]
sq-1,...,7: NN+...+7NN (${\displaystyle r\le \sqrt{10}}$)	36	0.113[15]	0.04169608[43]
sq lat, diamond boundary: dist. ≤ 4	40	0.105(5)[49]
sq-(1,...,8: NN+..+8NN (${\displaystyle r\le \sqrt{13}}$)	44	0.095,[37] 0.095765(5),[52] 0.09580(2)[51]
sq-1,...,9: NN+..+9NN (r≤4)	48	0.086[15]	0.02974268[43]
sq-1,...,11: NN+...+11NN (${\displaystyle r\le \sqrt{18}}$)	60		0.02301190(3)[43]
sq-1,...,23 (r ≤ 7)	148		0.008342595[44]
sq-1,...,32: NN+...+32NN (${\displaystyle r\le \sqrt{72}}$)	224		0.0053050415(33)[43]
sq-1,...,86: NN+...+86NN (r≤15)	708		0.001557644(4)[53]
sq-1,...,141: NN+...+141NN (${\displaystyle r\le \sqrt{389}}$)	1224		0.000880188(90)[43]
sq-1,...,185: NN+...+185NN (r≤23)	1652		0.000645458(4)[53]
sq-1,...,317: NN+...+317NN (r≤31)	3000		0.000349601(3)[53]
sq-1,...,413: NN+...+413NN (${\displaystyle r\le \sqrt{1280}}$)	4016		0.0002594722(11)[43]
sq lat, diamond boundary: dist. ≤ 6	84	0.049(5)[49]
sq lat, diamond boundary: dist. ≤ 8	144	0.028(5)[49]
sq lat, diamond boundary: dist. ≤ 10	220	0.019(5)[49]
2x2 lattice squares* (same as sq-1,2,3,4)	20	φc = 0.58365(2),[52] pc = 0.196724(10),[52] 0.19671(9),[51]
3x3 lattice squares* (same as sq-1,...,8))	44	φc = 0.59586(2),[52] pc = 0.095765(5),[52] 0.09580(2) [51]
4x4 lattice squares*	76	φc = 0.60648(1),[52] pc = 0.0566227(15),[52] 0.05665(3),[51]
5x5 lattice squares*	116	φc = 0.61467(2),[52] pc = 0.037428(2),[52] 0.03745(2),[51]
6x6 lattice squares*	220	pc = 0.02663(1),[51]
10x10 lattice squares*	436	φc = 0.36391(2),[52] pc = 0.0100576(5) [52]
within 11 x 11 square (r=5)	120	0.01048079(6)[53]
within 15 x 15 square (r=7)	224	0.005287692(22)[53]
within 31 x 31 square (r=15)	960	0.001131082(5) [53]

Here NN = nearest neighbor, 2NN = second nearest neighbor (or next nearest neighbor), 3NN = third nearest neighbor (or next-next nearest neighbor), etc. These are also called 2N, 3N, 4N respectively in some papers.^[39]

• For overlapping or touching squares, ${\displaystyle p_c}$(site) given here is the net fraction of sites occupied ${\displaystyle {\varphi }_c}$ similar to the ${\displaystyle {\varphi }_c}$ in continuum percolation. The case of a 2×2 square is equivalent to percolation of a square lattice NN+2NN+3NN+4NN or sq-1,2,3,4 with threshold ${\displaystyle 1-(1-{\varphi }_c{)}^{1/4}=0.196724(10)\dots }$ with ${\displaystyle {\varphi }_c=0.58365(2)}$.^[52] The 3×3 square corresponds to sq-1,2,3,4,5,6,7,8 with z=44 and ${\displaystyle p_c=1-(1-{\varphi }_c{)}^{1/9}=0.095765(5)\dots }$. The value of z for a k x k square is (2k+1)²-5. For larger overlapping squares, see.^[52]

Here, one distorts a regular lattice of unit spacing by moving vertices uniformly within the box ${\displaystyle (x-\alpha ,x+\alpha ),(y-\alpha ,y+\alpha )}$, and considers percolation when sites are within Euclidean distance ${\displaystyle d}$ of each other.

Lattice	${\displaystyle \bar{z}}$	${\displaystyle \alpha }$	${\displaystyle d}$	Site percolation threshold	Bond percolation threshold
square		0.2	1.1	0.8025(2)[54]
		0.2	1.2	0.6667(5)[54]
		0.1	1.1	0.6619(1)[54]

Site threshold is number of overlapping objects per lattice site. k is the length (net area). Overlapping squares are shown in the complex neighborhood section. Here z is the coordination number to k-mers of either orientation, with ${\displaystyle z=k^2+10k-2}$ for ${\displaystyle 1\times k}$ sticks.

System	k	z	Site coverage φc	Site percolation threshold pc
1 x 2 dimer, square lattice	2	22	0.54691[51] 0.5483(2)[55]	0.17956(3)[51] 0.18019(9)[55]
1 x 2 aligned dimer, square lattice	2	14	0.5715(18)[55]	0.3454(13) [55]
1 x 3 trimer, square lattice	3	37	0.49898[51] 0.50004(64)[55]	0.10880(2)[51] 0.1093(2)[55]
1 x 4 stick, square lattice	4	54	0.45761[51]	0.07362(2)[51]
1 x 5 stick, square lattice	5	73	0.42241[51]	0.05341(1)[51]
1 x 6 stick, square lattice	6	94	0.39219[51]	0.04063(2)[51]

The coverage is calculated from ${\displaystyle p_c}$ by ${\displaystyle {\varphi }_c=1-(1-p_c{)}^{2k}}$ for ${\displaystyle 1\times k}$ sticks, because there are ${\displaystyle 2k}$ sites where a stick will cause an overlap with a given site.

For aligned ${\displaystyle 1\times k}$ sticks: ${\displaystyle {\varphi }_c=1-(1-p_c{)}^k}$

Lattice	z	Site percolation threshold	Bond percolation threshold
(3, 122 )	3
(4, 6, 12)	3
(4, 82)	3		0.676835..., 4p3 + 3p4 − 6 p5 − 2 p6 = 1[56]
honeycomb (63)	3
kagome (3, 6, 3, 6)	4		0.524430..., 3p2 + 6p3 − 12 p4+ 6 p5 − p6 = 1[57]
(3, 4, 6, 4)	4
square (44)	4		Template:Frac (exact)
(34,6 )	5		0.434371..., 12p3 + 36p4 − 21p5 − 327 p6 + 69p7 + 2532p8 − 6533 p9 + 8256 p10 − 6255p11 + 2951p12 − 837 p13 + 126 p14 − 7p15 = 1 Template:Citation needed
snub square, puzzle (32, 4, 3, 4 )	5
(33, 42)	5
triangular (36)	6	Template:Frac (exact)

In AB percolation, a ${\displaystyle p_{\mathrm{s}\mathrm{i}\mathrm{t}\mathrm{e}}}$ is the proportion of A sites among B sites, and bonds are drawn between sites of opposite species.^[58] It is also called antipercolation.

In colored percolation, occupied sites are assigned one of ${\displaystyle n}$ colors with equal probability, and connection is made along bonds between neighbors of different colors.^[59]

Lattice	z	${\displaystyle \bar{z}}$	Site percolation threshold
triangular AB	6	6	0.2145,[58] 0.21524(34),[60] 0.21564(3)[61]
AB on square-covering lattice	6	6	${\displaystyle 1-\sqrt{1-p_c(site,sq)}=0.361835}$[62]
square three-color	4	4	0.80745(5)[59]
square four-color	4	4	0.73415(4)[59]
square five-color	4	4	0.69864(7)[59]
square six-color	4	4	0.67751(5)[59]
triangular two-color	6	6	0.72890(4)[59]
triangular three-color	6	6	0.63005(4)[59]
triangular four-color	6	6	0.59092(3)[59]
triangular five-color	6	6	0.56991(5)[59]
triangular six-color	6	6	0.55679(5)[59]

Site bond percolation. Here ${\displaystyle p_s}$ is the site occupation probability and ${\displaystyle p_b}$ is the bond occupation probability, and connectivity is made only if both the sites and bonds along a path are occupied. The criticality condition becomes a curve ${\displaystyle f(p_s,p_b)}$ = 0, and some specific critical pairs ${\displaystyle (p_s,p_b)}$ are listed below.

Square lattice:

Lattice	z	${\displaystyle \bar{z}}$	Site percolation threshold	Bond percolation threshold
square	4	4	0.615185(15)[63]	0.95
			0.667280(15)[63]	0.85
			0.732100(15)[63]	0.75
			0.75	0.726195(15)[63]
			0.815560(15)[63]	0.65
			0.85	0.615810(30)[63]
			0.95	0.533620(15)[63]

Honeycomb (hexagonal) lattice:

Lattice	z	${\displaystyle \bar{z}}$	Site percolation threshold	Bond percolation threshold
honeycomb	3	3	0.7275(5)[64]	0.95
			0. 0.7610(5)[64]	0.90
			0.7986(5)[64]	0.85
			0.80	0.8481(5)[64]
			0.8401(5)[64]	0.80
			0.85	0.7890(5)[64]
			0.90	0.7377(5)[64]
			0.95	0.6926(5)[64]

Kagome lattice:

Lattice	z	${\displaystyle \bar{z}}$	Site percolation threshold	Bond percolation threshold
kagome	4	4	0.6711(4),[64] 0.67097(3)[65]	0.95
			0.6914(5),[64] 0.69210(2)[65]	0.90
			0.7162(5),[64] 0.71626(3)[65]	0.85
			0.7428(5),[64] 0.74339(3)[65]	0.80
			0.75	0.7894(9)[64]
			0.7757(8),[64] 0.77556(3)[65]	0.75
			0.80	0.7152(7)[64]
			0.81206(3)[65]	0.70
			0.85	0.6556(6)[64]
			0.85519(3)[65]	0.65
			0.90	0.6046(5)[64]
			0.90546(3)[65]	0.60
			0.95	0.5615(4)[64]
			0.96604(4)[65]	0.55
			0.9854(3)[65]	0.53

* For values on different lattices, see "An investigation of site-bond percolation on many lattices".^[64]

Approximate formula for site-bond percolation on a honeycomb lattice

Lattice	z	${\displaystyle \bar{z}}$	Threshold	Notes
(63) honeycomb	3	3	${\displaystyle p_b{p}_s[1-(\sqrt{p_{bc}}/(3-p_{bc}))(\sqrt{p_b}-\sqrt{p_{bc}})]=p_{bc}}$, When equal: ps = pb = 0.82199	approximate formula, ps = site prob., pb = bond prob., pbc = 1 − 2 sin (Template:Pi/18),[19] exact at ps=1, pb=pbc.

Laves lattices are the duals to the Archimedean lattices. Drawings from.^[6] See also Uniform tilings.

Lattice	z	${\displaystyle \bar{z}}$	Site percolation threshold	Bond percolation threshold
Cairo pentagonal D(32,4,3,4)=(Template:Frac)(53)+(Template:Frac)(54)	3,4	3 Template:Frac	0.6501834(2),[11] 0.650184(5)[6]	0.585863... = 1 − pcbond(32,4,3,4)
Pentagonal D(33,42)=(Template:Frac)(54)+(Template:Frac)(53)	3,4	3 Template:Frac	0.6470471(2),[11] 0.647084(5),[6] 0.6471(6)[38]	0.580358... = 1 − pcbond(33,42), 0.5800(6)[38]
D(34,6)=(Template:Frac)(46)+(Template:Frac)(43)	3,6	3 Template:Frac	0.639447[6]	0.565694... = 1 − pcbond(34,6 )
dice, rhombille tiling D(3,6,3,6) = (Template:Frac)(46) + (Template:Frac)(43)	3,6	4	0.5851(4),[66] 0.585040(5)[6]	0.475595... = 1 − pcbond(3,6,3,6 )
ruby dual D(3,4,6,4) = (Template:Frac)(46) + (Template:Frac)(43) + (Template:Frac)(44)	3,4,6	4	0.582410(5)[6]	0.475167... = 1 − pcbond(3,4,6,4 )
union jack, tetrakis square tiling D(4,82) = (Template:Frac)(34) + (Template:Frac)(38)	4,8	6	Template:Frac	0.323197... = 1 − pcbond(4,82 )
bisected hexagon,[67] cross dual D(4,6,12)= (Template:Frac)(312)+(Template:Frac)(36)+(Template:Frac)(34)	4,6,12	6	Template:Frac	0.306266... = 1 − pcbond(4,6,12)
asanoha (hemp leaf)[68] D(3, 122)=(Template:Frac)(33)+(Template:Frac)(312)	3,12	6	Template:Frac	0.259579... = 1 − pcbond(3, 122)

Top 3 lattices: #13 #12 #36
Bottom 3 lattices: #34 #37 #11 Template:Clear

^[3] Template:Clear Top 2 lattices: #35 #30
Bottom 2 lattices: #41 #42 Template:Clear

^[3] Template:Clear Top 4 lattices: #22 #23 #21 #20
Bottom 3 lattices: #16 #17 #15

^[3] Template:Clear Top 2 lattices: #31 #32
Bottom lattice: #33

^[3] Template:Clear

#	Lattice	z	${\displaystyle \bar{z}}$	Site percolation threshold	Bond percolation threshold
41	(Template:Frac)(3,4,3,12) + (Template:Frac)(3, 122)	4,3	3.5	0.7680(2)[69]	0.67493252(36)Template:Citation needed
42	(Template:Frac)(3,4,6,4) + (Template:Frac)(4,6,12)	4,3	3Template:Frac	0.7157(2)[69]	0.64536587(40)Template:Citation needed
36	(Template:Frac)(36) + (Template:Frac)(32,4,12)	6,4	4 Template:Frac	0.6808(2)[69]	0.55778329(40)Template:Citation needed
15	(Template:Frac)(32,62) + (Template:Frac)(3,6,3,6)	4,4	4	0.6499(2)[69]	0.53632487(40)Template:Citation needed
34	(Template:Frac)(36) + (Template:Frac)(32,62)	6,4	4 Template:Frac	0.6329(2)[69]	0.51707873(70)Template:Citation needed
16	(Template:Frac)(3,42,6) + (Template:Frac)(3,6,3,6)	4,4	4	0.6286(2)[69]	0.51891529(35)Template:Citation needed
17	(Template:Frac)(3,42,6) + (Template:Frac)(3,6,3,6)*	4,4	4	0.6279(2)[69]	0.51769462(35)Template:Citation needed
35	(Template:Frac)(3,42,6) + (Template:Frac)(3,4,6,4)	4,4	4	0.6221(2)[69]	0.51973831(40)Template:Citation needed
11	(Template:Frac)(34,6) + (Template:Frac)(32,62)	5,4	4.5	0.6171(2)[69]	0.48921280(37)Template:Citation needed
37	(Template:Frac)(33,42) + (Template:Frac)(3,4,6,4)	5,4	4.5	0.5885(2)[69]	0.47229486(38)Template:Citation needed
30	(Template:Frac)(32,4,3,4) + (Template:Frac)(3,4,6,4)	5,4	4.5	0.5883(2)[69]	0.46573078(72)Template:Citation needed
23	(Template:Frac)(33,42) + (Template:Frac)(44)	5,4	4.5	0.5720(2)[69]	0.45844622(40)Template:Citation needed
22	(Template:Frac)(33,42) + (Template:Frac)(44)	5,4	4 Template:Frac	0.5648(2)[69]	0.44528611(40)Template:Citation needed
12	(Template:Frac)(36) + (Template:Frac)(34,6)	6,5	5 Template:Frac	0.5607(2)[69]	0.41109890(37)Template:Citation needed
33	(Template:Frac)(33,42) + (Template:Frac)(32,4,3,4)	5,5	5	0.5505(2)[69]	0.41628021(35)Template:Citation needed
32	(Template:Frac)(33,42) + (Template:Frac)(32,4,3,4)	5,5	5	0.5504(2)[69]	0.41549285(36)Template:Citation needed
31	(Template:Frac)(36) + (Template:Frac)(32,4,3,4)	6,5	5 Template:Frac	0.5440(2)[69]	0.40379585(40)Template:Citation needed
13	(Template:Frac)(36) + (Template:Frac)(34,6)	6,5	5.5	0.5407(2)[69]	0.38914898(35)Template:Citation needed
21	(Template:Frac)(36) + (Template:Frac)(33,42)	6,5	5 Template:Frac	0.5342(2)[69]	0.39491996(40)Template:Citation needed
20	(Template:Frac)(36) + (Template:Frac)(33,42)	6,5	5.5	0.5258(2)[69]	0.38285085(38)Template:Citation needed

This figure shows something similar to the 2-uniform lattice #37, except the polygons are not all regular—there is a rectangle in the place of the two squares—and the size of the polygons is changed. This lattice is in the isoradial representation in which each polygon is inscribed in a circle of unit radius. The two squares in the 2-uniform lattice must now be represented as a single rectangle in order to satisfy the isoradial condition. The lattice is shown by black edges, and the dual lattice by red dashed lines. The green circles show the isoradial constraint on both the original and dual lattices. The yellow polygons highlight the three types of polygons on the lattice, and the pink polygons highlight the two types of polygons on the dual lattice. The lattice has vertex types (Template:Frac)(3³,4²) + (Template:Frac)(3,4,6,4), while the dual lattice has vertex types (Template:Frac)(4⁶)+(Template:Frac)(4²,5²)+(Template:Frac)(5³)+(Template:Frac)(5²,4). The critical point is where the longer bonds (on both the lattice and dual lattice) have occupation probability p = 2 sin (π/18) = 0.347296... which is the bond percolation threshold on a triangular lattice, and the shorter bonds have occupation probability 1 − 2 sin(π/18) = 0.652703..., which is the bond percolation on a hexagonal lattice. These results follow from the isoradial condition^[70] but also follow from applying the star-triangle transformation to certain stars on the honeycomb lattice. Finally, it can be generalized to having three different probabilities in the three different directions, p₁, p₂ and p₃ for the long bonds, and Template:Nowrap, Template:Nowrap, and Template:Nowrap for the short bonds, where p₁, p₂ and p₃ satisfy the critical surface for the inhomogeneous triangular lattice.

Template:Clear

To the left, center, and right are: the martini lattice, the martini-A lattice, the martini-B lattice. Below: the martini covering/medial lattice, same as the 2×2, 1×1 subnet for kagome-type lattices (removed).

Some other examples of generalized bow-tie lattices (a-d) and the duals of the lattices (e-h):

Lattice	z	${\displaystyle \bar{z}}$	Site percolation threshold	Bond percolation threshold
martini (Template:Frac)(3,92)+(Template:Frac)(93)	3	3	0.764826..., 1 + p4 − 3p3 = 0[71]	0.707107... = 1/Template:Radic[72]
bow-tie (c)	3,4	3 Template:Frac		0.672929..., 1 − 2p3 − 2p4 − 2p5 − 7p6 + 18p7 + 11p8 − 35p9 + 21p10 − 4p11 = 0[73]
bow-tie (d)	3,4	3 Template:Frac		0.625457..., 1 − 2p2 − 3p3 + 4p4 − p5 = 0[73]
martini-A (Template:Frac)(3,72)+(Template:Frac)(3,73)	3,4	3 Template:Frac	1/Template:Radic[73]	0.625457..., 1 − 2p2 − 3p3 + 4p4 − p5 = 0[73]
bow-tie dual (e)	3,4	3 Template:Frac		0.595482..., 1-pcbond (bow-tie (a))[73]
bow-tie (b)	3,4,6	3 Template:Frac		0.533213..., 1 − p − 2p3 -4p4-4p5+156+ 13p7-36p8+19p9+ p10 + p11=0[73]
martini covering/medial (Template:Frac)(33,9) + (Template:Frac)(3,9,3,9)	4	4	0.707107... = 1/Template:Radic[72]	0.57086651(33)Template:Citation needed
martini-B (Template:Frac)(3,5,3,52) + (Template:Frac)(3,52)	3, 5	4	0.618034... = 2/(1 + Template:Radic), 1- p2 − p = 0[71][73]	Template:Frac[72][73]
bow-tie dual (f)	3,4,8	4 Template:Frac		0.466787..., 1 − pcbond (bow-tie (b))[73]
bow-tie (a) (Template:Frac)(32,4,32,4) + (Template:Frac)(3,4,3)	4,6	5	0.5472(2),[38] 0.5479148(7)[74]	0.404518..., 1 − p − 6p2 + 6p3 − p5 = 0[73][75]
bow-tie dual (h)	3,6,8	5		0.374543..., 1 − pcbond(bow-tie (d))[73]
bow-tie dual (g)	3,6,10	5 Template:Frac	0.547... = pcsite(bow-tie(a))	0.327071..., 1 − pcbond(bow-tie (c))[73]
martini dual (Template:Frac)(33) + (Template:Frac)(39)	3,9	6	Template:Frac	0.292893... = 1 − 1/Template:Radic[72]

Lattice	z	${\displaystyle \bar{z}}$	Site percolation threshold	Bond percolation threshold
(4, 6, 12) covering/medial	4	4	pcbond(4, 6, 12) = 0.693731...	0.5593140(2),[11] 0.559315(1)Template:Citation needed
(4, 82) covering/medial, square kagome	4	4	pcbond(4,82) = 0.676803...	0.544798017(4),[11] 0.54479793(34)Template:Citation needed
(34, 6) medial	4	4		0.5247495(5)[11]
(3,4,6,4) medial	4	4		0.51276[11]
(32, 4, 3, 4) medial	4	4		0.512682929(8)[11]
(33, 42) medial	4	4		0.5125245984(9)[11]
square covering (non-planar)	6	6	Template:Frac	0.3371(1)[56]
square matching lattice (non-planar)	8	8	1 − pcsite(square) = 0.407253...	0.25036834(6)[18]

Template:Multiple image

Template:Multiple image Template:Clear

Lattice	z	${\displaystyle \bar{z}}$	Site percolation threshold	Bond percolation threshold
K(2,2)	4	4	0.51253(14)[76]	0.44778(15)[76]
K(3,3)	6	6	0.43760(15)[76]	0.35502(15)[76]
K(4,4)	8	8	0.38675(7)[76]	0.29427(12)[76]
K(5,5)	10	10	0.35115(13)[76]	0.25159(13)[76]
K(6,6)	12	12	0.32232(13)[76]	0.21942(11)[76]
K(7,7)	14	14	0.30052(14)[76]	0.19475(9)[76]
K(8,8)	16	16	0.28103(11)[76]	0.17496(10)[76]

Example image caption

The 2 x 2, 3 x 3, and 4 x 4 subnet kagome lattices. The 2 × 2 subnet is also known as the "triangular kagome" lattice.^[77]

Lattice	z	${\displaystyle \bar{z}}$	Site percolation threshold	Bond percolation threshold
checkerboard – 2 × 2 subnet	4,3			0.596303(1)[78]
checkerboard – 4 × 4 subnet	4,3			0.633685(9)[78]
checkerboard – 8 × 8 subnet	4,3			0.642318(5)[78]
checkerboard – 16 × 16 subnet	4,3			0.64237(1)[78]
checkerboard – 32 × 32 subnet	4,3			0.64219(2)[78]
checkerboard – ${\displaystyle \mathrm{\infty }}$ subnet	4,3			0.642216(10)[78]
kagome – 2 × 2 subnet = (3, 122) covering/medial	4		pcbond (3, 122) = 0.74042077...	0.600861966960(2),[11] 0.6008624(10),[19] 0.60086193(3)[9]
kagome – 3 × 3 subnet	4			0.6193296(10),[19] 0.61933176(5),[9] 0.61933044(32)Template:Citation needed
kagome – 4 × 4 subnet	4			0.625365(3),[19] 0.62536424(7)[9]
kagome – ${\displaystyle \mathrm{\infty }}$ subnet	4			0.628961(2)[19]
kagome – (1 × 1):(2 × 2) subnet = martini covering/medial	4		pcbond(martini) = 1/Template:Radic = 0.707107...	0.57086648(36)Template:Citation needed
kagome – (1 × 1):(3 × 3) subnet	4,3		0.728355596425196...[9]	0.58609776(37)Template:Citation needed
kagome – (1 × 1):(4 × 4) subnet			0.738348473943256...[9]
kagome – (1 × 1):(5 × 5) subnet			0.743548682503071...[9]
kagome – (1 × 1):(6 × 6) subnet			0.746418147634282...[9]
kagome – (2 × 2):(3 × 3) subnet				0.61091770(30)Template:Citation needed
triangular – 2 × 2 subnet	6,4			0.471628788[78]
triangular – 3 × 3 subnet	6,4			0.509077793[78]
triangular – 4 × 4 subnet	6,4			0.524364822[78]
triangular – 5 × 5 subnet	6,4			0.5315976(10)[78]
triangular – ${\displaystyle \mathrm{\infty }}$ subnet	6,4			0.53993(1)[78]

(For more results and comparison to the jamming density, see Random sequential adsorption)

system	z	Site threshold
dimers on a honeycomb lattice	3	0.69,[79] 0.6653 [80]
dimers on a triangular lattice	6	0.4872(8),[79] 0.4873,[80]
aligned linear dimers on a triangular lattice	6	0.5157(2) [81]
aligned linear 4-mers on a triangular lattice	6	0.5220(2)[81]
aligned linear 8-mers on a triangular lattice	6	0.5281(5)[81]
aligned linear 12-mers on a triangular lattice	6	0.5298(8)[81]
linear 16-mers on a triangular lattice	6	aligned 0.5328(7)[81]
linear 32-mers on a triangular lattice	6	aligned 0.5407(6)[81]
linear 64-mers on a triangular lattice	6	aligned 0.5455(4)[81]
aligned linear 80-mers on a triangular lattice	6	0.5500(6)[81]
aligned linear k ${\displaystyle ⟶\mathrm{\infty }}$ on a triangular lattice	6	0.582(9)[81]
dimers and 5% impurities, triangular lattice	6	0.4832(7)[82]
parallel dimers on a square lattice	4	0.5863[83]
dimers on a square lattice	4	0.5617,[83] 0.5618(1),[84] 0.562,[85] 0.5713[80]
linear 3-mers on a square lattice	4	0.528[85]
3-site 120° angle, 5% impurities, triangular lattice	6	0.4574(9)[82]
3-site triangles, 5% impurities, triangular lattice	6	0.5222(9)[82]
linear trimers and 5% impurities, triangular lattice	6	0.4603(8)[82]
linear 4-mers on a square lattice	4	0.504[85]
linear 5-mers on a square lattice	4	0.490[85]
linear 6-mers on a square lattice	4	0.479[85]
linear 8-mers on a square lattice	4	0.474,[85] 0.4697(1)[84]
linear 10-mers on a square lattice	4	0.469[85]
linear 16-mers on a square lattice	4	0.4639(1)[84]
linear 32-mers on a square lattice	4	0.4747(2)[84]

The threshold gives the fraction of sites occupied by the objects when site percolation first takes place (not at full jamming). For longer k-mers see Ref.^[86]

Here, we are dealing with networks that are obtained by covering a lattice with dimers, and then consider bond percolation on the remaining bonds. In discrete mathematics, this problem is known as the 'perfect matching' or the 'dimer covering' problem.

system	z	Bond threshold
Parallel covering, square lattice	6	0.381966...[87]
Shifted covering, square lattice	6	0.347296...[87]
Staggered covering, square lattice	6	0.376825(2)[87]
Random covering, square lattice	6	0.367713(2)[87]
Parallel covering, triangular lattice	10	0.237418...[87]
Staggered covering, triangular lattice	10	0.237497(2)[87]
Random covering, triangular lattice	10	0.235340(1)[87]

System is composed of ordinary (non-avoiding) random walks of length l on the square lattice.^[88]

l (polymer length)	z	Bond percolation
1	4	0.5(exact)[89]
2	4	0.47697(4)[89]
4	4	0.44892(6)[89]
8	4	0.41880(4)[89]

k	z	Site thresholds	Bond thresholds
1	4	0.593(2)[90]	0.5009(2)[90]
2	4	0.564(2)[90]	0.4859(2)[90]
3	4	0.552(2)[90]	0.4732(2)[90]
4	4	0.542(2)[90]	0.4630(2)[90]
5	4	0.531(2)[90]	0.4565(2)[90]
6	4	0.522(2)[90]	0.4497(2)[90]
7	4	0.511(2)[90]	0.4423(2)[90]
8	4	0.502(2)[90]	0.4348(2)[90]
9	4	0.493(2)[90]	0.4291(2)[90]
10	4	0.488(2)[90]	0.4232(2)[90]
11	4	0.482(2)[90]	0.4159(2)[90]
12	4	0.476(2)[90]	0.4114(2)[90]
13	4	0.471(2)[90]	0.4061(2)[90]
14	4	0.467(2)[90]	0.4011(2)[90]
15	4	0.4011(2)[90]	0.3979(2)[90]

Lattice	z	Site percolation threshold	Bond percolation threshold
bow-tie with p = Template:Frac on one non-diagonal bond	3		0.3819654(5),[91] ${\displaystyle (3-\sqrt{5})/2}$[56]

System	Φc	ηc	nc
Disks of radius r	0.67634831(2),[92] 0.6763475(6),[93] 0.676339(4),[94] 0.6764(4),[95] 0.6766(5),[96] 0.676(2),[97] 0.679,[98] 0.674[99] 0.676,[100] 0.680[101]	1.1280867(5),[102] 1.1276(9),[103] 1.12808737(6),[92] 1.128085(2),[93] 1.128059(12),[94] 1.13,Template:Citation needed 0.8[104]	1.43632505(10),[105] 1.43632545(8),[92] 1.436322(2),[93] 1.436289(16),[94] 1.436320(4),[106] 1.436323(3),[107] 1.438(2),[108] 1.216 (48)[109]
Ellipses, ε = 1.5	0.0043[98]	0.00431	2.059081(7)[107]
Ellipses, ε = Template:Frac	0.65[110]	1.05[110]	2.28[110]
Ellipses, ε = 2	0.6287945(12),[107] 0.63[110]	0.991000(3),[107] 0.99[110]	2.523560(8),[107] 2.5[110]
Ellipses, ε = 3	0.56[110]	0.82[110]	3.157339(8),[107] 3.14[110]
Ellipses, ε = 4	0.5[110]	0.69[110]	3.569706(8),[107] 3.5[110]
Ellipses, ε = 5	0.455,[98] 0.455,[100] 0.46[110]	0.607[98]	3.861262(12),[107] 3.86[98]
Ellipses, ε = 6			4.079365(17)[107]
Ellipses, ε = 7			4.249132(16)[107]
Ellipses, ε = 8			4.385302(15)[107]
Ellipses, ε = 9			4.497000(8)[107]
Ellipses, ε = 10	0.301,[98] 0.303,[100] 0.30[110]	0.358[98] 0.36[110]	4.590416(23)[107] 4.56,[98] 4.5[110]
Ellipses, ε = 15			4.894752(30)[107]
Ellipses, ε = 20	0.178,[98] 0.17[110]	0.196[98]	5.062313(39),[107] 4.99[98]
Ellipses, ε = 50	0.081[98]	0.084[98]	5.393863(28),[107] 5.38[98]
Ellipses, ε = 100	0.0417[98]	0.0426[98]	5.513464(40),[107] 5.42[98]
Ellipses, ε = 200	0.021[110]	0.0212[110]	5.40[110]
Template:Nowrap	0.0043[98]	0.00431	5.624756(22),[107] 5.5
Superellipses, ε = 1, m = 1.5	0.671[100]
Superellipses, ε = 2.5, m = 1.5	0.599[100]
Superellipses, ε = 5, m = 1.5	0.469[100]
Superellipses, ε = 10, m = 1.5	0.322[100]
disco-rectangles, ε = 1.5			1.894 [106]
disco-rectangles, ε = 2			2.245 [106]
Aligned squares of side ${\displaystyle \ell }$	0.66675(2),[52] 0.66674349(3),[92] 0.66653(1),[111] 0.6666(4),[112] 0.668[99]	1.09884280(9),[92] 1.0982(3),[111] 1.098(1)[112]	1.09884280(9),[92] 1.0982(3),[111] 1.098(1)[112]
Randomly oriented squares	0.62554075(4),[92] 0.6254(2)[112] 0.625,[100]	0.9822723(1),[92] 0.9819(6)[112] 0.982278(14)[113]	0.9822723(1),[92] 0.9819(6)[112] 0.982278(14)[113]
Randomly oriented squares within angle ${\displaystyle \pi /4}$	0.6255(1)[112]	0.98216(15)[112]
Rectangles, ε = 1.1	0.624870(7)	0.980484(19)	1.078532(21)[113]
Rectangles, ε = 2	0.590635(5)	0.893147(13)	1.786294(26)[113]
Rectangles, ε = 3	0.5405983(34)	0.777830(7)	2.333491(22)[113]
Rectangles, ε = 4	0.4948145(38)	0.682830(8)	2.731318(30)[113]
Rectangles, ε = 5	0.4551398(31), 0.451[100]	0.607226(6)	3.036130(28)[113]
Rectangles, ε = 10	0.3233507(25), 0.319[100]	0.3906022(37)	3.906022(37)[113]
Rectangles, ε = 20	0.2048518(22)	0.2292268(27)	4.584535(54)[113]
Rectangles, ε = 50	0.09785513(36)	0.1029802(4)	5.149008(20)[113]
Rectangles, ε = 100	0.0523676(6)	0.0537886(6)	5.378856(60)[113]
Rectangles, ε = 200	0.02714526(34)	0.02752050(35)	5.504099(69)[113]
Rectangles, ε = 1000	0.00559424(6)	0.00560995(6)	5.609947(60)[113]
Sticks (needles) of length ${\displaystyle \ell }$			5.63726(2),[114] 5.6372858(6),[92] 5.637263(11),[113] 5.63724(18) [115]
sticks with log-normal length dist. STD=0.5			4.756(3) [115]
sticks with correlated angle dist. s=0.5			6.6076(4) [115]
Power-law disks, x = 2.05	0.993(1)[116]	4.90(1)	0.0380(6)
Power-law disks, x = 2.25	0.8591(5)[116]	1.959(5)	0.06930(12)
Power-law disks, x = 2.5	0.7836(4)[116]	1.5307(17)	0.09745(11)
Power-law disks, x = 4	0.69543(6)[116]	1.18853(19)	0.18916(3)
Power-law disks, x = 5	0.68643(13)[116]	1.1597(3)	0.22149(8)
Power-law disks, x = 6	0.68241(8)[116]	1.1470(1)	0.24340(5)
Power-law disks, x = 7	0.6803(8)[116]	1.140(6)	0.25933(16)
Power-law disks, x = 8	0.67917(9)[116]	1.1368(5)	0.27140(7)
Power-law disks, x = 9	0.67856(12)[116]	1.1349(4)	0.28098(9)
Voids around disks of radius r	1 − Φc(disk) = 0.32355169(2),[92] 0.318(2),[117] 0.3261(6)[118]

For disks, ${\displaystyle n_c=4r^{2}N/L^2}$ equals the critical number of disks per unit area, measured in units of the diameter ${\displaystyle 2r}$, where ${\displaystyle N}$ is the number of objects and ${\displaystyle L}$ is the system size

For disks, ${\displaystyle {\eta }_c=\pi r^{2}N/L^2=(\pi /4)n_c}$ equals critical total disk area.

${\displaystyle 4{\eta }_c}$ gives the number of disk centers within the circle of influence (radius 2 r).

${\displaystyle r_c=L\sqrt{\frac{{\eta }_c}{\pi N}}=\frac{L}{2}\sqrt{\frac{n_c}{N}}}$ is the critical disk radius.

${\displaystyle {\eta }_c=\pi abN/L^2}$ for ellipses of semi-major and semi-minor axes of a and b, respectively. Aspect ratio ${\displaystyle ϵ=a/b}$ with ${\displaystyle a>b}$.

${\displaystyle {\eta }_c=\ell mN/L^2}$ for rectangles of dimensions ${\displaystyle \ell }$ and ${\displaystyle m}$. Aspect ratio ${\displaystyle ϵ=\ell /m}$ with ${\displaystyle \ell >m}$.

${\displaystyle {\eta }_c=\pi xN/(4L^2(x-2))}$ for power-law distributed disks with ${\displaystyle \text{Prob(radius}\ge R)=R^{-x}}$, ${\displaystyle R\ge 1}$.

${\displaystyle {\varphi }_c=1-e^{-{\eta }_c}}$ equals critical area fraction.

For disks, Ref.^[97] use ${\displaystyle {\varphi }_c=1-e^{-\pi x/2}}$ where ${\displaystyle x}$ is the density of disks of radius ${\displaystyle 1/\sqrt{2}}$.

${\displaystyle n_c={\ell }^{2}N/L^2}$ equals number of objects of maximum length ${\displaystyle \ell =2a}$ per unit area.

For ellipses, ${\displaystyle n_c=(4ϵ/\pi ){\eta }_c}$

For void percolation, ${\displaystyle {\varphi }_c=e^{-{\eta }_c}}$ is the critical void fraction.

For more ellipse values, see ^[107][110]

For more rectangle values, see ^[113]

Both ellipses and rectangles belong to the superellipses, with ${\displaystyle |x/a{|}^{2m}+|y/b{|}^{2m}=1}$. For more percolation values of superellipses, see.^[100]

For the monodisperse particle systems, the percolation thresholds of concave-shaped superdisks are obtained as seen in ^[119]

For binary dispersions of disks, see ^{[93][120][121]}

File:Delaunay triangulation example.png

Lattice	z	${\displaystyle \bar{z}}$	Site percolation threshold	Bond percolation threshold
Relative neighborhood graph		2.5576	0.796(2)[122]	0.771(2)[122]
Voronoi tessellation	3		0.71410(2),[124] 0.7151*[69]	0.68,[125] 0.6670(1),[126] 0.6680(5),[127] 0.666931(5)[124]
Voronoi covering/medial	4		0.666931(2)[124][126]	0.53618(2)[124]
Randomized kagome/square-octagon, fraction r=Template:Frac	4		0.6599[16]
Penrose rhomb dual	4		0.6381(3)[66]	0.5233(2)[66]
Gabriel graph		4	0.6348(8),[128] 0.62[129]	0.5167(6),[128] 0.52[129]
Random-line tessellation, dual		4	0.586(2)[130]
Penrose rhomb		4	0.5837(3),[66] 0.0.5610(6) (weighted bonds)[131] 0.58391(1)[132]	0.483(5),[133] 0.4770(2)[66]
Octagonal lattice, "chemical" links (Ammann–Beenker tiling)		4	0.585[134]	0.48[134]
Octagonal lattice, "ferromagnetic" links		5.17	0.543[134]	0.40[134]
Dodecagonal lattice, "chemical" links		3.63	0.628[134]	0.54[134]
Dodecagonal lattice, "ferromagnetic" links		4.27	0.617[134]	0.495[134]
Delaunay triangulation		6	Template:Frac[135]	0.3333(1)[126] 0.3326(5),[127] 0.333069(2)[124]
Uniform Infinite Planar Triangulation[136]		6	Template:Frac	(2Template:Radic – 1)/11 ≈ 0.2240[123][137]

*Theoretical estimate

Assuming power-law correlations ${\displaystyle C(r)\sim |r{|}^{-\alpha }}$

lattice	α	Site percolation threshold	Bond percolation threshold
square	3	0.561406(4)[138]
square	2	0.550143(5)[138]
square	0.1	0.508(4)[138]

h is the thickness of the slab, h × ∞ × ∞. Boundary conditions (b.c.) refer to the top and bottom planes of the slab.

Lattice	h	z	${\displaystyle \bar{z}}$	Site percolation threshold	Bond percolation threshold
simple cubic (open b.c.)	2	5	5	0.47424,[139] 0.4756[140]
bcc (open b.c.)	2			0.4155[140]
hcp (open b.c.)	2			0.2828[140]
diamond (open b.c.)	2			0.5451[140]
simple cubic (open b.c.)	3			0.4264[140]
bcc (open b.c.)	3			0.3531[140]
bcc (periodic b.c.)	3				0.21113018(38)[141]
hcp (open b.c.)	3			0.2548[140]
diamond (open b.c.)	3			0.5044[140]
simple cubic (open b.c.)	4			0.3997,[139] 0.3998[140]
bcc (open b.c.)	4			0.3232[140]
bcc (periodic b.c.)	4				0.20235168(59)[141]
hcp (open b.c.)	4			0.2405[140]
diamond (open b.c.)	4			0.4842[140]
simple cubic (periodic b.c.)	5	6	6		0.278102(5)[141]
simple cubic (open b.c.)	6			0.3708[140]
simple cubic (periodic b.c.)	6	6	6		0.272380(2)[141]
bcc (open b.c.)	6			0.2948[140]
hcp (open b.c.)	6			0.2261[140]
diamond (open b.c.)	6			0.4642[140]
simple cubic (periodic b.c.)	7	6	6	0.3459514(12)[141]	0.268459(1)[141]
simple cubic (open b.c.)	8			0.3557,[139] 0.3565[140]
simple cubic (periodic b.c.)	8	6	6		0.265615(5)[141]
bcc (open b.c.)	8			0.2811[140]
hcp (open b.c.)	8			0.2190[140]
diamond (open b.c.)	8			0.4549[140]
simple cubic (open b.c.)	12			0.3411[140]
bcc (open b.c.)	12			0.2688[140]
hcp (open b.c.)	12			0.2117[140]
diamond (open b.c.)	12			0.4456[140]
simple cubic (open b.c.)	16			0.3219,[139] 0.3339[140]
bcc (open b.c.)	16			0.2622[140]
hcp (open b.c.)	16			0.2086[140]
diamond (open b.c.)	16			0.4415[140]
simple cubic (open b.c.)	32			0.3219,[139]
simple cubic (open b.c.)	64			0.3165,[139]
simple cubic (open b.c.)	128			0.31398,[139]

Lattice	z	${\displaystyle \bar{z}}$	filling factor*	filling fraction*	Site percolation threshold	Bond percolation threshold
(10,3)-a oxide (or site-bond)[142]	23 32	2.4			0.748713(22)[142]	= (pc,bond(10,3) – a)Template:Frac = 0.742334(25)[143]
(10,3)-b oxide (or site-bond)[142]	23 32	2.4	0.233[144]	0.174	0.745317(25)[142]	= (pc,bond(10,3) – b)Template:Frac = 0.739388(22)[143]
silicon dioxide (diamond site-bond)[142]	4,22	2 Template:Frac			0.638683(35)[142]
Modified (10,3)-b[145]	32,2	2 Template:Frac				0.627[145]
(8,3)-a[143]	3	3			0.577962(33)[143]	0.555700(22)[143]
(10,3)-a[143] gyroid[146]	3	3			0.571404(40)[143]	0.551060(37)[143]
(10,3)-b[143]	3	3			0.565442(40)[143]	0.546694(33)[143]
cubic oxide (cubic site-bond)[142]	6,23	3.5			0.524652(50)[142]
bcc dual		4			0.4560(6)[147]	0.4031(6)[147]
ice Ih	4	4	π Template:Radic / 16 = 0.340087	0.147	0.433(11)[148]	0.388(10)[149]
diamond (Ice Ic)	4	4	π Template:Radic / 16 = 0.340087	0.1462332	0.4299(8),[150] 0.4299870(4),[151] Template:Val,[152] 0.4297(4) [153] 0.4301(4),[154] 0.428(4),[155] 0.425(15),[156] 0.425,[41][48] 0.436(12)[148]	0.3895892(5),[151] 0.3893(2),[154] 0.3893(3),[153] 0.388(5),[156] 0.3886(5),[150] 0.388(5)[155] 0.390(11)[149]
diamond dual		6 Template:Frac			0.3904(5)[147]	0.2350(5)[147]
3D kagome (covering graph of the diamond lattice)	6		π Template:Radic / 12 = 0.37024	0.1442	0.3895(2)[157] =pc(site) for diamond dual and pc(bond) for diamond lattice[147]	0.2709(6)[147]
Bow-tie stack dual		5 Template:Frac			0.3480(4)[38]	0.2853(4)[38]
honeycomb stack	5	5			0.3701(2)[38]	0.3093(2)[38]
octagonal stack dual	5	5			0.3840(4)[38]	0.3168(4)[38]
pentagonal stack		5 Template:Frac			0.3394(4)[38]	0.2793(4)[38]
kagome stack	6	6	0.453450	0.1517	0.3346(4)[38]	0.2563(2)[38]
fcc dual	42,8	5 Template:Frac			0.3341(5)[147]	0.2703(3)[147]
simple cubic	6	6	π / 6 = 0.5235988	0.1631574	0.307(10),[156] 0.307,[41] 0.3115(5),[158] 0.3116077(2),[159] 0.311604(6),[160] 0.311605(5),[161] 0.311600(5),[162] 0.3116077(4),[163] 0.3116081(13),[164] 0.3116080(4),[165] 0.3116060(48),[166] 0.3116004(35),[167] 0.31160768(15)[151]	0.247(5),[156] 0.2479(4),[150] 0.2488(2),[168] 0.24881182(10),[159] 0.2488125(25),[169] 0.2488126(5),[170]
hcp dual	44,82	5 Template:Frac			0.3101(5)[147]	0.2573(3)[147]
dice stack	5,8	6	π Template:Radic / 9 = 0.604600	0.1813	0.2998(4)[38]	0.2378(4)[38]
bow-tie stack	7	7			0.2822(6)[38]	0.2092(4)[38]
Stacked triangular / simple hexagonal	8	8			0.26240(5),[171] 0.2625(2),[172] 0.2623(2)[38]	0.18602(2),[171] 0.1859(2)[38]
octagonal (union-jack) stack	6,10	8			0.2524(6)[38]	0.1752(2)[38]
bcc	8	8			0.243(10),[156] 0.243,[41] 0.2459615(10),[165] 0.2460(3),[173] 0.2464(7),[150] 0.2458(2)[154]	0.178(5),[156] 0.1795(3),[150] 0.18025(15),[168] 0.1802875(10)[170]
simple cubic with 3NN (same as bcc)	8	8			0.2455(1),[174] 0.2457(7)[175]
fcc, D3	12	12	π / (3 Template:Radic) = 0.740480	0.147530	0.195,[41] 0.198(3),[176] 0.1998(6),[150] 0.1992365(10),[165] 0.19923517(20),[151] 0.1994(2),[154] 0.199236(4)[177]	0.1198(3),[150] 0.1201635(10)[170] 0.120169(2)[177]
hcp	12	12	π / (3 Template:Radic) = 0.740480	0.147545	0.195(5),[156] 0.1992555(10)[178]	0.1201640(10),[178] 0.119(2)[156]
La2−x Srx Cu O4	12	12			0.19927(2)[179]
simple cubic with 2NN (same as fcc)	12	12			0.1991(1)[174]
simple cubic with NN+4NN	12	12			0.15040(12),[180] 0.1503793(7)[181]	0.1068263(7)[182]
simple cubic with 3NN+4NN	14	14			0.20490(12)[180]	0.1012133(7)[182]
bcc NN+2NN (= sc(3,4) sc-3NN+4NN)	14	14			0.175,[41] 0.1686,(20)[183] 0.1759432(8)	0.0991(5),[183] 0.1012133(7),[45] 0.1759432(8) [45]
Nanotube fibers on FCC	14	14			0.1533(13)[184]
simple cubic with NN+3NN	14	14			0.1420(1)[174]	0.0920213(7)[182]
simple cubic with 2NN+4NN	18	18			0.15950(12)[180]	0.0751589(9)[182]
simple cubic with NN+2NN	18	18			0.137,[48] 0.136,[185] 0.1372(1),[174] 0.13735(5),Template:Citation needed 0.1373045(5)[45]	0.0752326(6) [182]
fcc with NN+2NN (=sc-2NN+4NN)	18	18			0.136,[41] 0.1361408(8)[45]	0.0751589(9) [45]
simple cubic with short-length correlation	6+	6+			0.126(1)[186]
simple cubic with NN+3NN+4NN	20	20			0.11920(12)[180]	0.0624379(9)[182]
simple cubic with 2NN+3NN	20	20			0.1036(1)[174]	0.0629283(7)[182]
simple cubic with NN+2NN+4NN	24	24			0.11440(12)[180]	0.0533056(6)[182]
simple cubic with 2NN+3NN+4NN	26	26			0.11330(12)[180]	0.0474609(9)
simple cubic with NN+2NN+3NN	26	26			0.097,[41] 0.0976(1),[174] 0.0976445(10), 0.0976444(6)[45]	0.0497080(10)[182]
bcc with NN+2NN+3NN	26	26			0.095,[48] 0.0959084(6)[45]	0.0492760(10)[45]
simple cubic with NN+2NN+3NN+4NN	32	32			0.10000(12),[180] 0.0801171(9)[45]	0.0392312(8)[182]
fcc with NN+2NN+3NN	42	42			0.061,[48] 0.0610(5),[185] 0.0618842(8)[45]	0.0290193(7) [45]
fcc with NN+2NN+3NN+4NN	54	54			0.0500(5)[185]
sc-1,2,3,4,5 simple cubic with NN+2NN+3NN+4NN+5NN	56	56			0.0461815(5)[45]	0.0210977(7)[45]
sc-1,...,6 (2x2x2 cube [51])	80	80			0.0337049(9),[45] 0.03373(13)[51]	0.0143950(10)[45]
sc-1,...,7	92	92			0.0290800(10)[45]	0.0123632(8)[45]
sc-1,...,8	122	122			0.0218686(6)[45]	0.0091337(7)[45]
sc-1,...,9	146	146			0.0184060(10)[45]	0.0075532(8)[45]
sc-1,...,10	170	170				0.0064352(8)[45]
sc-1,...,11	178	178				0.0061312(8)[45]
sc-1,...,12	202	202				0.0053670(10)[45]
sc-1,...,13	250	250				0.0042962(8)[45]
3x3x3 cube	274	274			φc= 0.76564(1),[52] pc = 0.0098417(7),[52] 0.009854(6)[51]
4x4x4 cube	636	636			φc=0.76362(1),[52] pc = 0.0042050(2),[52] 0.004217(3)[51]
5x5x5 cube	1214	1250			φc=0.76044(2),[52] pc = 0.0021885(2),[52] 0.002185(4)[51]
6x6x6 cube	2056	2056			0.001289(2)[51]

Filling factor = fraction of space filled by touching spheres at every lattice site (for systems with uniform bond length only). Also called Atomic Packing Factor.

Filling fraction (or Critical Filling Fraction) = filling factor * p_c(site).

NN = nearest neighbor, 2NN = next-nearest neighbor, 3NN = next-next-nearest neighbor, etc.

kxkxk cubes are cubes of occupied sites on a lattice, and are equivalent to extended-range percolation of a cube of length (2k+1), with edges and corners removed, with z = (2k+1)³-12(2k-1)-9 (center site not counted in z).

Question: the bond thresholds for the hcp and fcc lattice agree within the small statistical error. Are they identical, and if not, how far apart are they? Which threshold is expected to be bigger? Similarly for the ice and diamond lattices. See ^[187]

System	polymer Φc
percolating excluded volume of athermal polymer matrix (bond-fluctuation model on cubic lattice)	0.4304(3)[188]

Here, one distorts a regular lattice of unit spacing by moving vertices uniformly within the cube ${\displaystyle (x-\alpha ,x+\alpha ),(y-\alpha ,y+\alpha ),(z-\alpha ,z+\alpha )}$, and considers percolation when sites are within Euclidean distance ${\displaystyle d}$ of each other.

Lattice	${\displaystyle \bar{z}}$	${\displaystyle \alpha }$	${\displaystyle d}$	Site percolation threshold	Bond percolation threshold
cubic		0.05	1.0	0.60254(3)[189]
		0.1	1.00625	0.58688(4)[189]
		0.15	1.025	0.55075(2)[189]
		0.175	1.05	0.50645(5)[189]
		0.2	1.1	0.44342(3)[189]

Site threshold is the number of overlapping objects per lattice site. The coverage φ_c is the net fraction of sites covered, and v is the volume (number of cubes). Overlapping cubes are given in the section on thresholds of 3D lattices. Here z is the coordination number to k-mers of either orientation, with ${\displaystyle z=6k^2+18k-4}$

System	k	z	Site coverage φc	Site percolation threshold pc
1 x 2 dimer, cubic lattice	2	56	0.24542[51]	0.045847(2)[51]
1 x 3 trimer, cubic lattice	3	104	0.19578[51]	0.023919(9)[51]
1 x 4 stick, cubic lattice	4	164	0.16055[51]	0.014478(7)[51]
1 x 5 stick, cubic lattice	5	236	0.13488[51]	0.009613(8)[51]
1 x 6 stick, cubic lattice	6	320	0.11569[51]	0.006807(2)[51]
2 x 2 plaquette, cubic lattice	2		0.22710[51]	0.021238(2)[51]
3 x 3 plaquette, cubic lattice	3		0.18686[51]	0.007632(5)[51]
4 x 4 plaquette, cubic lattice	4		0.16159[51]	0.003665(3)[51]
5 x 5 plaquette, cubic lattice	5		0.14316[51]	0.002058(5)[51]
6 x 6 plaquette, cubic lattice	6		0.12900[51]	0.001278(5)[51]

The coverage is calculated from ${\displaystyle p_c}$ by ${\displaystyle {\varphi }_c=1-(1-p_c{)}^{3k}}$ for sticks, and ${\displaystyle {\varphi }_c=1-(1-p_c{)}^{3k^2}}$ for plaquettes.

System	Site percolation threshold	Bond percolation threshold
Simple cubic		0.2555(1)[190]

All overlapping except for jammed spheres and polymer matrix.

System	Φc	ηc
Spheres of radius r	0.289,[191] 0.293,[192] 0.286,[193] 0.295.[99] 0.2895(5),[194] 0.28955(7),[195] 0.2896(7),[196] 0.289573(2),[197] 0.2896,[198] 0.2854,[199] 0.290,[200] 0.290[201]	0.3418(7),[194] 0.3438(13),[202] 0.341889(3),[197] 0.3360,[199] 0.34189(2) [111] [corrected], 0.341935(8),[203] 0.335,[204]
Oblate ellipsoids with major radius r and aspect ratio Template:Frac	0.2831[199]	0.3328[199]
Prolate ellipsoids with minor radius r and aspect ratio Template:Frac	0.2757,[198] 0.2795,[199] 0.2763[200]	0.3278[199]
Oblate ellipsoids with major radius r and aspect ratio 2	0.2537,[198] 0.2629,[199] 0.254[200]	0.3050[199]
Prolate ellipsoids with minor radius r and aspect ratio 2	0.2537,[198] 0.2618,[199] 0.25(2),[205] 0.2507[200]	0.3035,[199] 0.29(3)[205]
Oblate ellipsoids with major radius r and aspect ratio 3	0.2289[199]	0.2599[199]
Prolate ellipsoids with minor radius r and aspect ratio 3	0.2033,[198] 0.2244,[199] 0.20(2)[205]	0.2541,[199] 0.22(3)[205]
Oblate ellipsoids with major radius r and aspect ratio 4	0.2003[199]	0.2235[199]
Prolate ellipsoids with minor radius r and aspect ratio 4	0.1901,[199] 0.16(2)[205]	0.2108,[199] 0.17(3)[205]
Oblate ellipsoids with major radius r and aspect ratio 5	0.1757[199]	0.1932[199]
Prolate ellipsoids with minor radius r and aspect ratio 5	0.1627,[199] 0.13(2)[205]	0.1776,[199] 0.15(2)[205]
Oblate ellipsoids with major radius r and aspect ratio 10	0.0895,[198] 0.1058[199]	0.1118[199]
Prolate ellipsoids with minor radius r and aspect ratio 10	0.0724,[198] 0.08703,[199] 0.07(2)[205]	0.09105,[199] 0.07(2)[205]
Oblate ellipsoids with major radius r and aspect ratio 100	0.01248[199]	0.01256[199]
Prolate ellipsoids with minor radius r and aspect ratio 100	0.006949[199]	0.006973[199]
Oblate ellipsoids with major radius r and aspect ratio 1000	0.001275[199]	0.001276[199]
Oblate ellipsoids with major radius r and aspect ratio 2000	0.000637[199]	0.000637[199]
Spherocylinders with H/D = 1	0.2439(2)[196]
Spherocylinders with H/D = 4	0.1345(1)[196]
Spherocylinders with H/D = 10	0.06418(20)[196]
Spherocylinders with H/D = 50	0.01440(8)[196]
Spherocylinders with H/D = 100	0.007156(50)[196]
Spherocylinders with H/D = 200	0.003724(90)[196]
Aligned cylinders	0.2819(2)[206]	0.3312(1)[206]
Aligned cubes of side ${\displaystyle \ell =2a}$	0.2773(2)[112] 0.27727(2),[52] 0.27730261(79)[166]	0.3247(3),[111] 0.3248(3),[112] 0.32476(4)[206] 0.324766(1)[166]
Randomly oriented icosahedra		0.3030(5)[207]
Randomly oriented dodecahedra		0.2949(5)[207]
Randomly oriented octahedra		0.2514(6)[207]
Randomly oriented cubes of side ${\displaystyle \ell =2a}$	0.2168(2)[112] 0.2174,[198]	0.2444(3),[112] 0.2443(5)[207]
Randomly oriented tetrahedra		0.1701(7)[207]
Randomly oriented disks of radius r (in 3D)		0.9614(5)[208]
Randomly oriented square plates of side ${\displaystyle \sqrt{\pi }r}$		0.8647(6)[208]
Randomly oriented triangular plates of side ${\displaystyle \sqrt{2\pi }/3^{1/4}r}$		0.7295(6)[208]
Jammed spheres (average z = 6)	0.183(3),[209] 0.1990,[210] see also contact network of jammed spheres below.	0.59(1)[209] (volume fraction of all spheres)

${\displaystyle {\eta }_c=(4/3)\pi r^{3}N/L^3}$ is the total volume (for spheres), where N is the number of objects and L is the system size.

${\displaystyle {\varphi }_c=1-e^{-{\eta }_c}}$ is the critical volume fraction, valid for overlapping randomly placed objects.

For disks and plates, these are effective volumes and volume fractions.

For void ("Swiss-Cheese" model), ${\displaystyle {\varphi }_c=e^{-{\eta }_c}}$ is the critical void fraction.

For more results on void percolation around ellipsoids and elliptical plates, see.^[211]

For more ellipsoid percolation values see.^[199]

For spherocylinders, H/D is the ratio of the height to the diameter of the cylinder, which is then capped by hemispheres. Additional values are given in.^[196]

For superballs, m is the deformation parameter, the percolation values are given in.,^[212][213] In addition, the thresholds of concave-shaped superballs are also determined in ^[119]

For cuboid-like particles (superellipsoids), m is the deformation parameter, more percolation values are given in.^[198]

Void percolation refers to percolation in the space around overlapping objects. Here ${\displaystyle {\varphi }_c}$ refers to the fraction of the space occupied by the voids (not of the particles) at the critical point, and is related to ${\displaystyle {\eta }_c}$ by ${\displaystyle {\varphi }_c=e^{-{\eta }_c}}$. ${\displaystyle {\eta }_c}$ is defined as in the continuum percolation section above.

System	Φc	ηc
Voids around disks of radius r		22.86(2)[211]
Voids around randomly oriented tetrahedra	0.0605(6)[214]
Voids around oblate ellipsoids of major radius r and aspect ratio 32	0.5308(7)[215]	0.6333[215]
Voids around oblate ellipsoids of major radius r and aspect ratio 16	0.3248(5)[215]	1.125[215]
Voids around oblate ellipsoids of major radius r and aspect ratio 10		1.542(1)[211]
Voids around oblate ellipsoids of major radius r and aspect ratio 8	0.1615(4)[215]	1.823[215]
Voids around oblate ellipsoids of major radius r and aspect ratio 4	0.0711(2)[215]	2.643,[215] 2.618(5)[211]
Voids around oblate ellipsoids of major radius r and aspect ratio 2		3.239(4) [211]
Voids around prolate ellipsoids of aspect ratio 8	0.0415(7)[216]
Voids around prolate ellipsoids of aspect ratio 6	0.0397(7)[216]
Voids around prolate ellipsoids of aspect ratio 4	0.0376(7)[216]
Voids around prolate ellipsoids of aspect ratio 3	0.03503(50)[216]
Voids around prolate ellipsoids of aspect ratio 2	0.0323(5)[216]
Voids around aligned square prisms of aspect ratio 2	0.0379(5) [217]
Voids around randomly oriented square prisms of aspect ratio 20	0.0534(4) [217]
Voids around randomly oriented square prisms of aspect ratio 15	0.0535(4) [217]
Voids around randomly oriented square prisms of aspect ratio 10	0.0524(5) [217]
Voids around randomly oriented square prisms of aspect ratio 8	0.0523(6) [217]
Voids around randomly oriented square prisms of aspect ratio 7	0.0519(3) [217]
Voids around randomly oriented square prisms of aspect ratio 6	0.0519(5) [217]
Voids around randomly oriented square prisms of aspect ratio 5	0.0515(7) [217]
Voids around randomly oriented square prisms of aspect ratio 4	0.0505(7) [217]
Voids around randomly oriented square prisms of aspect ratio 3	0.0485(11) [217]
Voids around randomly oriented square prisms of aspect ratio 5/2	0.0483(8) [217]
Voids around randomly oriented square prisms of aspect ratio 2	0.0465(7) [217]
Voids around randomly oriented square prisms of aspect ratio 3/2	0.0461(14) [217]
Voids around hemispheres	0.0455(6)[218]
Voids around aligned tetrahedra	0.0605(6)[214]
Voids around randomly oriented tetrahedra	0.0605(6)[214]
Voids around aligned cubes	0.036(1),[52] 0.0381(3)[214]
Voids around randomly oriented cubes	0.0452(6),[214] 0.0449(5)[217]
Voids around aligned octahedra	0.0407(3)[214]
Voids around randomly oriented octahedra	0.0398(5)[214]
Voids around aligned dodecahedra	0.0356(3)[214]
Voids around randomly oriented dodecahedra	0.0360(3)[214]
Voids around aligned icosahedra	0.0346(3)[214]
Voids around randomly oriented icosahedra	0.0336(7)[214]
Voids around spheres	0.034(7),[219] 0.032(4),[220] 0.030(2),[117] 0.0301(3),[221] 0.0294,[216] 0.0300(3),[222] 0.0317(4),[223] 0.0308(5)[218] 0.0301(1),[215] 0.0301(1)[214]	3.506(8),[222] 3.515(6),[211] 3.510(2)[103]

Lattice	z	${\displaystyle \bar{z}}$	Site percolation threshold	Bond percolation threshold
Contact network of packed spheres		6	0.310(5),[209] 0.287(50),[224] 0.3116(3),[210]
Random-plane tessellation, dual		6	0.290(7)[225]
Icosahedral Penrose		6	0.285[226]	0.225[226]
Penrose w/2 diagonals		6.764	0.271[226]	0.207[226]
Penrose w/8 diagonals		12.764	0.188[226]	0.111[226]
Voronoi network		15.54	0.1453(20)[183]	0.0822(50)[183]

Lattice	z	${\displaystyle \bar{z}}$	Site percolation threshold	Critical coverage fraction ${\displaystyle {\varphi }_c}$	Bond percolation threshold
Drilling percolation, simple cubic lattice*	6	6	0.6345(3),[227] 0.6339(5),[228] 0.633965(15)[229]	0.25480
Drill in z direction on cubic lattice, remove single sites	6	6	0.592746 (columns), 0.4695(10) (sites)[230]	0.2784
Random tube model, simple cubic lattice†					0.231456(6)[231]
Pac-Man percolation, simple cubic lattice					0.139(6)[232]

${}^{\ast }$ In drilling percolation, the site threshold ${\displaystyle p_c}$ represents the fraction of columns in each direction that have not been removed, and ${\displaystyle {\varphi }_c=p_c^3}$. For the 1d drilling, we have ${\displaystyle {\varphi }_c=p_c}$(columns) ${\displaystyle p_c}$(sites).

^† In tube percolation, the bond threshold represents the value of the parameter ${\displaystyle \mu }$ such that the probability of putting a bond between neighboring vertical tube segments is ${\displaystyle 1-e^{-\mu h_i}}$, where ${\displaystyle h_i}$ is the overlap height of two adjacent tube segments.^[231]

d	System	Φc	ηc
4	Overlapping hyperspheres	0.1223(4)[111]	0.1300(13),[202] 0.1304(5)[111]
4	Aligned hypercubes	0.1132(5),[111] 0.1132348(17) [166]	0.1201(6)[111]
4	Voids around hyperspheres	0.00211(2)[118]	6.161(10)[118] 6.248(2),[103]
5	Overlapping hyperspheres		0.0544(6),[202] 0.05443(7)[111]
5	Aligned hypercubes	0.04900(7),[111] 0.0481621(13)[166]	0.05024(7)[111]
5	Voids around hyperspheres	1.26(6)x10−4[118]	8.98(4),[118] 9.170(8)[103]
6	Overlapping hyperspheres		0.02391(31),[202] 0.02339(5)[111]
6	Aligned hypercubes	0.02082(8),[111] 0.0213479(10)[166]	0.02104(8)[111]
6	Voids around hyperspheres	8.0(6)x10−6 [118]	11.74(8),[118] 12.24(2),[103]
7	Overlapping hyperspheres		0.01102(16),[202] 0.01051(3)[111]
7	Aligned hypercubes	0.00999(5),[111] 0.0097754(31)[166]	0.01004(5)[111]
7	Voids around hyperspheres		15.46(5)[103]
8	Overlapping hyperspheres		0.00516(8),[202] 0.004904(6)[111]
8	Aligned hypercubes		0.004498(5)[111]
8	Voids around hyperspheres		18.64(8)[103]
9	Overlapping hyperspheres		0.002353(4)[111]
9	Aligned hypercubes		0.002166(4)[111]
9	Voids around hyperspheres		22.1(4)[103]
10	Overlapping hyperspheres		0.001138(3)[111]
10	Aligned hypercubes		0.001058(4)[111]
11	Overlapping hyperspheres		0.0005530(3)[111]
11	Aligned hypercubes		0.0005160(3)[111]

${\displaystyle {\eta }_c=({\pi }^{d/2}/\Gamma [d/2+1])r^{d}N/L^d.}$

In 4d, ${\displaystyle {\eta }_c=(1/2){\pi }^2{r}^{4}N/L^4}$.

In 5d, ${\displaystyle {\eta }_c=(8/15){\pi }^2{r}^{5}N/L^5}$.

In 6d, ${\displaystyle {\eta }_c=(1/6){\pi }^3{r}^{6}N/L^6}$.

${\displaystyle {\varphi }_c=1-e^{-{\eta }_c}}$ is the critical volume fraction, valid for overlapping objects.

For void models, ${\displaystyle {\varphi }_c=e^{-{\eta }_c}}$ is the critical void fraction, and ${\displaystyle {\eta }_c}$ is the total volume of the overlapping objects

d	z	Site thresholds	Bond thresholds
4	8	0.198(1)[233] 0.197(6),[234] 0.1968861(14),[235] 0.196889(3),[236] 0.196901(5),[237] 0.19680(23),[238] 0.1968904(65),[166] 0.19688561(3)[239]	0.1600(1),[240] 0.16005(15),[168] 0.1601314(13),[235] 0.160130(3),[236] 0.1601310(10),[169] 0.1601312(2),[241] 0.16013122(6)[239]
5	10	0.141(1),0.198(1)[233] 0.141(3),[234] 0.1407966(15),[235] 0.1407966(26),[166] 0.14079633(4)[239]	0.1181(1),[240] 0.118(1),[242] 0.11819(4),[168] 0.118172(1),[235] 0.1181718(3)[169] 0.11817145(3)[239]
6	12	0.106(1),[233] 0.108(3),[234] 0.109017(2),[235] 0.1090117(30),[166] 0.109016661(8)[239]	0.0943(1),[240] 0.0942(1),[243] 0.0942019(6),[235] 0.09420165(2)[239]
7	14	0.05950(5),[243] 0.088939(20),[244] 0.0889511(9),[235] 0.0889511(90),[166] 0.088951121(1),[239]	0.0787(1),[240] 0.078685(30),[243] 0.0786752(3),[235] 0.078675230(2)[239]
8	16	0.0752101(5),[235] 0.075210128(1)[239]	0.06770(5),[243] 0.06770839(7),[235] 0.0677084181(3)[239]
9	18	0.0652095(3),[235] 0.0652095348(6)[239]	0.05950(5),[243] 0.05949601(5),[235] 0.0594960034(1)[239]
10	20	0.0575930(1),[235] 0.0575929488(4)[239]	0.05309258(4),[235] 0.0530925842(2)[239]
11	22	0.05158971(8),[235] 0.0515896843(2)[239]	0.04794969(1),[235] 0.04794968373(8)[239]
12	24	0.04673099(6),[235] 0.0467309755(1)[239]	0.04372386(1),[235] 0.04372385825(10)[239]
13	26	0.04271508(8),[235] 0.04271507960(10)[239]	0.04018762(1),[235] 0.04018761703(6)[239]

For thresholds on high dimensional hypercubic lattices, we have the asymptotic series expansions ^{[234] [242] [245]}

${\displaystyle p_c^{\mathrm{s}\mathrm{i}\mathrm{t}\mathrm{e}}(d)={\sigma }^{-1}+\frac{3}{2}{\sigma }^{-2}+\frac{15}{4}{\sigma }^{-3}+\frac{83}{4}{\sigma }^{-4}+\frac{6577}{48}{\sigma }^{-5}+\frac{119077}{96}{\sigma }^{-6}+𝒪({\sigma }^{-7})}$

${\displaystyle p_c^{\mathrm{b}\mathrm{o}\mathrm{n}\mathrm{d}}(d)={\sigma }^{-1}+\frac{5}{2}{\sigma }^{-3}+\frac{15}{2}{\sigma }^{-4}+57{\sigma }^{-5}+\frac{4855}{12}{\sigma }^{-6}+𝒪({\sigma }^{-7})}$

where ${\displaystyle \sigma =2d-1}$. For 13-dimensional bond percolation, for example, the error with the measured value is less than 10⁻⁶, and these formulas can be useful for higher-dimensional systems.

d	lattice	z	Site thresholds	Bond thresholds
4	diamond	5	0.2978(2)[154]	0.2715(3)[154]
4	kagome	8	0.2715(3)[157]	0.177(1) [154]
4	bcc	16	0.1037(3)[154]	0.074(1),[154] 0.074212(1)[241]
4	fcc, D4, hypercubic 2NN	24	0.0842(3),[154] 0.08410(23),[238] 0.0842001(11)[177]	0.049(1),[154] 0.049517(1),[241] 0.0495193(8)[177]
4	hypercubic NN+2NN	32	0.06190(23),[238] 0.0617731(19)[246]	0.035827(1),[241] 0.0338047(27)[246]
4	hypercubic 3NN	32	0.04540(23)[238]
4	hypercubic NN+3NN	40	0.04000(23)[238]	0.0271892(22)[246]
4	hypercubic 2NN+3NN	56	0.03310(23)[238]	0.0194075(15)[246]
4	hypercubic NN+2NN+3NN	64	0.03190(23),[238] 0.0319407(13)[246]	0.0171036(11)[246]
4	hypercubic NN+2NN+3NN+4NN	88	0.0231538(12)[246]	0.0122088(8)[246]
4	hypercubic NN+...+5NN	136	0.0147918(12)[246]	0.0077389(9)[246]
4	hypercubic NN+...+6NN	232	0.0088400(10)[246]	0.0044656(11)[246]
4	hypercubic NN+...+7NN	296	0.0070006(6)[246]	0.0034812(7)[246]
4	hypercubic NN+...+8NN	320	0.0064681(9)[246]	0.0032143(8)[246]
4	hypercubic NN+...+9NN	424	0.0048301(9)[246]	0.0024117(7)[246]
5	diamond	6	0.2252(3)[154]	0.2084(4)[157]
5	kagome	10	0.2084(4)[157]	0.130(2)[154]
5	bcc	32	0.0446(4)[154]	0.033(1)[154]
5	fcc, D5, hypercubic 2NN	40	0.0431(3),[154] 0.0435913(6)[177]	0.026(2),[154] 0.0271813(2)[177]
5	hypercubic NN+2NN	50	0.0334(2)[247]	0.0213(1)[247]
6	diamond	7	0.1799(5)[154]	0.1677(7)[157]
6	kagome	12	0.1677(7)[157]
6	fcc, D6	60	0.0252(5),[154] 0.02602674(12)[177]	0.01741556(5)[177]
6	bcc	64	0.0199(5)[154]
6	E6[177]	72	0.02194021(14)[177]	0.01443205(8)[177]
7	fcc, D7	84	0.01716730(5)[177]	0.012217868(13)[177]
7	E7[177]	126	0.01162306(4)[177]	0.00808368(2)[177]
8	fcc, D8	112	0.01215392(4)[177]	0.009081804(6)[177]
8	E8[177]	240	0.00576991(2)[177]	0.004202070(2)[177]
9	fcc, D9	144	0.00905870(2)[177]	0.007028457(3)[177]
9	${\displaystyle {\Lambda }_9}$[177]	272	0.00480839(2)[177]	0.0037006865(11)[177]
10	fcc, D10	180	0.007016353(9)[177]	0.005605579(6)[177]
11	fcc, D11	220	0.005597592(4)[177]	0.004577155(3)[177]
12	fcc, D12	264	0.004571339(4)[177]	0.003808960(2)[177]
13	fcc, D13	312	0.003804565(3)[177]	0.0032197013(14)[177]

In a one-dimensional chain we establish bonds between distinct sites ${\displaystyle i}$ and ${\displaystyle j}$ with probability ${\displaystyle p=\frac{C}{|i-j{|}^{1+\sigma }}}$ decaying as a power-law with an exponent ${\displaystyle \sigma >0}$. Percolation occurs^[248][249] at a critical value ${\displaystyle C_c<1}$ for ${\displaystyle \sigma <1}$. The numerically determined percolation thresholds are given by:^[250]

${\displaystyle \sigma }$	${\displaystyle C_c}$	Critical thresholds ${\displaystyle C_c}$ as a function of ${\displaystyle \sigma }$.[250] The dotted line is the rigorous lower bound.[248]
0.1	0.047685(8)
0.2	0.093211(16)
0.3	0.140546(17)
0.4	0.193471(15)
0.5	0.25482(5)
0.6	0.327098(6)
0.7	0.413752(14)
0.8	0.521001(14)
0.9	0.66408(7)

Template:Clear

In these lattices there may be two percolation thresholds: the lower threshold is the probability above which infinite clusters appear, and the upper is the probability above which there is a unique infinite cluster.

Lattice	z	${\displaystyle \bar{z}}$	Site percolation threshold		Bond percolation threshold
			Lower	Upper	Lower	Upper
{3,7} hyperbolic	7	7	0.26931171(7),[253] 0.20[254]	0.73068829(7),[253] 0.73(2)[254]	0.20,[255] 0.1993505(5)[253]	0.37,[255] 0.4694754(8)[253]
{3,8} hyperbolic	8	8	0.20878618(9)[253]	0.79121382(9)[253]	0.1601555(2)[253]	0.4863559(6)[253]
{3,9} hyperbolic	9	9	0.1715770(1)[253]	0.8284230(1)[253]	0.1355661(4)[253]	0.4932908(1)[253]
{4,5} hyperbolic	5	5	0.29890539(6)[253]	0.8266384(5)[253]	0.27,[255] 0.2689195(3)[253]	0.52,[255] 0.6487772(3) [253]
{4,6} hyperbolic	6	6	0.22330172(3)[253]	0.87290362(7)[253]	0.20714787(9)[253]	0.6610951(2)[253]
{4,7} hyperbolic	7	7	0.17979594(1)[253]	0.89897645(3)[253]	0.17004767(3)[253]	0.66473420(4)[253]
{4,8} hyperbolic	8	8	0.151035321(9)[253]	0.91607962(7)[253]	0.14467876(3)[253]	0.66597370(3)[253]
{4,9} hyperbolic	8	8	0.13045681(3)[253]	0.92820305(3)[253]	0.1260724(1)[253]	0.66641596(2)[253]
{5,5} hyperbolic	5	5	0.26186660(5)[253]	0.89883342(7)[253]	0.263(10),[256] 0.25416087(3)[253]	0.749(10)[256] 0.74583913(3)[253]
{7,3} hyperbolic	3	3	0.54710885(10)[253]	0.8550371(5),[253] 0.86(2)[254]	0.53,[255] 0.551(10),[256] 0.5305246(8)[253]	0.72,[255] 0.810(10),[256] 0.8006495(5)[253]
{∞,3} Cayley tree	3	3	Template:Frac		Template:Frac[255]	1[255]
Enhanced binary tree (EBT)					0.304(1),[257] 0.306(10),[256] (Template:Radic − 3)/2 = 0.302776[258]	0.48,[255] 0.564(1),[257] 0.564(10),[256] Template:Frac[258]
Enhanced binary tree dual					0.436(1),[257] 0.452(10)[256]	0.696(1),[257] 0.699(10)[256]
Non-Planar Hanoi Network (HN-NP)					0.319445[252]	0.381996[252]
Cayley tree with grandparents		8			0.158656326[259]

Note: {m,n} is the Schläfli symbol, signifying a hyperbolic lattice in which n regular m-gons meet at every vertex

For bond percolation on {P,Q}, we have by duality ${\displaystyle p_{c,\ell }(P,Q)+p_{c,u}(Q,P)=1}$. For site percolation, ${\displaystyle p_{c,\ell }(3,Q)+p_{c,u}(3,Q)=1}$ because of the self-matching of triangulated lattices.

Cayley tree (Bethe lattice) with coordination number ${\displaystyle z:p_c=1/(z-1)}$

Lattice	z	Site percolation threshold	Bond percolation threshold
(1+1)-d honeycomb	1.5	0.8399316(2),[260] 0.839933(5),[261] ${\displaystyle =\sqrt{p_c(\mathrm{s}\mathrm{i}\mathrm{t}\mathrm{e})}}$ of (1+1)-d sq.	0.8228569(2),[260] 0.82285680(6)[260]
(1+1)-d kagome	2	0.7369317(2),[260] 0.73693182(4)[262]	0.6589689(2),[260] 0.65896910(8)[260]
(1+1)-d square, diagonal	2	0.705489(4),[263] 0.705489(4),[264] 0.70548522(4),[265] 0.70548515(20),[262] 0.7054852(3),[260]	0.644701(2),[266] 0.644701(1),[267] 0.644701(1),[263] 0.6447006(10),[261] 0.64470015(5),[268] 0.644700185(5),[265] 0.6447001(2),[260] 0.643(2)[269]
(1+1)-d triangular	3	0.595646(3),[263] 0.5956468(5),[268] 0.5956470(3)[260]	0.478018(2),[263] 0.478025(1),[268] 0.4780250(4)[260] 0.479(3)[269]
(2+1)-d simple cubic, diagonal planes	3	0.43531(1),[270] 0.43531411(10)[260]	0.382223(7),[270] 0.38222462(6)[260] 0.383(3)[269]
(2+1)-d square nn (= bcc)	4	0.3445736(3),[271] 0.344575(15)[272] 0.3445740(2)[260]	0.2873383(1),[273] 0.287338(3)[270] 0.28733838(4)[260] 0.287(3)[269]
(2+1)-d fcc			0.199(2))[269]
(3+1)-d hypercubic, diagonal	4	0.3025(10),[274] 0.30339538(5) [260]	0.26835628(5),[260] 0.2682(2)[269]
(3+1)-d cubic, nn	6	0.2081040(4)[271]	0.1774970(5)[169]
(3+1)-d bcc	8	0.160950(30),[272] 0.16096128(3)[260]	0.13237417(2)[260]
(4+1)-d hypercubic, diagonal	5	0.23104686(3)[260]	0.20791816(2),[260] 0.2085(2)[269]
(4+1)-d hypercubic, nn	8	0.1461593(2),[271] 0.1461582(3)[275]	0.1288557(5)[169]
(4+1)-d bcc	16	0.075582(17),[272] 0.0755850(3),[275] 0.07558515(1)[260]	0.063763395(5)[260]
(5+1)-d hypercubic, diagonal	6	0.18651358(2)[260]	0.170615155(5),[260] 0.1714(1) [269]
(5+1)-d hypercubic, nn	10	0.1123373(2)[271]	0.1016796(5)[169]
(5+1)-d hypercubic bcc	32	0.035967(23),[272] 0.035972540(3)[260]	0.0314566318(5)[260]
(6+1)-d hypercubic, diagonal	7	0.15654718(1)[260]	0.145089946(3),[260] 0.1458[269]
(6+1)-d hypercubic, nn	12	0.0913087(2)[271]	0.0841997(14)[169]
(6+1)-d hypercubic bcc	64	0.017333051(2)[260]	0.01565938296(10)[260]
(7+1)-d hypercubic, diagonal	8	0.135004176(10)[260]	0.126387509(3),[260] 0.1270(1) [269]
(7+1)-d hypercubic,nn	14	0.07699336(7)[271]	0.07195(5)[169]
(7+1)-d bcc	128	0.008 432 989(2)[260]	0.007 818 371 82(6)[260]

nn = nearest neighbors. For a (d + 1)-dimensional hypercubic system, the hypercube is in d dimensions and the time direction points to the 2D nearest neighbors.

(1+1)-d square with z NN, square lattice for z odd, tilted square lattice for z even

Lattice	z	Site percolation threshold	Bond percolation threshold
(1+1)-d square	3		0.4395(3),[276]
(1+1)-d square	5		0.2249(3)[276]
(1+1)-d square	7		0.1470(2)[276]
(1+1)-d square	9		0.1081(2)[276]
(1+1)-d square	11		0.0851(2)[276]
(1+1)-d square	13		0.0701(2)[276]
(1+1)-d tilted sq	2		0.6447(2)[276]
(1+1)-d tilted sq	4		0.3272(2)[276]
(1+1)-d tilted sq	6		0.2121(3)[276]
(1+1)-d tilted sq	8		0.1553(3)[276]
(1+1)-d tilted sq	10		0.1220(2)[276]
(1+1)-d tilted sq	12		0.0999(2)[276]

For large z, p_c ~ 1/z ^[277]

p_b = bond threshold

p_s = site threshold

Site-bond percolation is equivalent to having different probabilities of connections:

P_0 = probability that no sites are connected

P_2 = probability that exactly one descendant is connected to the upper vertex (two connected together)

P_3 = probability that both descendants are connected to the original vertex (all three connected together)

Formulas:

P_0 = (1-p_s) + p_s(1-p_b)^2

P_2 = p_s p_b (1-p_b)

P_3 = p_s p_b^2

P_0 + 2P_2 + P_3 = 1

Lattice	z	p_s	p_b	P_0	P_2	P_3
(1+1)-d square [278]	3	0.644701	1	0.126237	0.229062	0.415639
		0.7	0.93585	0.148376	0.196529	0.458567
		0.75	0.88565	0.169703	0.166059	0.498178
		0.8	0.84135	0.192304	0.134616	0.538464
		0.85	0.80190	0.216143	0.102242	0.579373
		0.9	0.76645	0.241215	0.068981	0.620825
		0.95	0.73450	0.267336	0.034889	0.662886
		1	0.705489	0.294511	0	0.705489

Inhomogeneous triangular lattice bond percolation^[20]

${\displaystyle 1-p_1-p_2-p_3+p_1{p}_2{p}_3=0}$

Inhomogeneous honeycomb lattice bond percolation = kagome lattice site percolation^[20]

${\displaystyle 1-p_1{p}_2-p_1{p}_3-p_2{p}_3+p_1{p}_2{p}_3=0}$

Inhomogeneous (3,12^2) lattice, site percolation^[7][279]

${\displaystyle 1-3(s_1{s}_2{)}^2+(s_1{s}_2{)}^3=0,}$ or ${\displaystyle s_1{s}_2=1-2\sin (\pi /18)}$

Inhomogeneous union-jack lattice, site percolation with probabilities ${\displaystyle p_1,p_2,p_3,p_4}$^[280]

${\displaystyle p_3=1-p_1;p_4=1-p_2}$

Inhomogeneous martini lattice, bond percolation^[73][281]

${\displaystyle 1-(p_1{p}_2{r}_3+p_2{p}_3{r}_1+p_1{p}_3{r}_2)-(p_1{p}_2{r}_1{r}_2+p_1{p}_3{r}_1{r}_3+p_2{p}_3{r}_2{r}_3)+p_1{p}_2{p}_3(r_1{r}_2+r_1{r}_3+r_2{r}_3)+r_1{r}_2{r}_3(p_1{p}_2+p_1{p}_3+p_2{p}_3)-2p_1{p}_2{p}_3{r}_1{r}_2{r}_3=0}$

Inhomogeneous martini lattice, site percolation. r = site in the star

${\displaystyle 1-r(p_1{p}_2+p_1{p}_3+p_2{p}_3-p_1{p}_2{p}_3)=0}$

Inhomogeneous martini-A (3–7) lattice, bond percolation. Left side (top of "A" to bottom): ${\displaystyle r_2,p_1}$. Right side: ${\displaystyle r_1,p_2}$. Cross bond: ${\displaystyle r_3}$.

${\displaystyle 1-p_1{r}_2-p_2{r}_1-p_1{p}_2{r}_3-p_1{r}_1{r}_3-p_2{r}_2{r}_3+p_1{p}_2{r}_1{r}_3+p_1{p}_2{r}_2{r}_3+p_1{r}_1{r}_2{r}_3+p_2{r}_1{r}_2{r}_3-p_1{p}_2{r}_1{r}_2{r}_3=0}$

Inhomogeneous martini-B (3–5) lattice, bond percolation

Inhomogeneous martini lattice with outside enclosing triangle of bonds, probabilities ${\displaystyle y,x,z}$ from inside to outside, bond percolation^[281]

${\displaystyle 1-3z+z^3-(1-z^2)[3x^{2}y(1+y-y^2)(1+z)+x^3{y}^2(3-2y)(1+2z)]=0}$

Inhomogeneous checkerboard lattice, bond percolation^[57][91]

${\displaystyle 1-(p_1{p}_2+p_1{p}_3+p_1{p}_4+p_2{p}_3+p_2{p}_4+p_3{p}_4)+p_1{p}_2{p}_3+p_1{p}_2{p}_4+p_1{p}_3{p}_4+p_2{p}_3{p}_4=0}$

Inhomogeneous bow-tie lattice, bond percolation^[56][91]

${\displaystyle 1-(p_1{p}_2+p_1{p}_3+p_1{p}_4+p_2{p}_3+p_2{p}_4+p_3{p}_4)+p_1{p}_2{p}_3+p_1{p}_2{p}_4+p_1{p}_3{p}_4+p_2{p}_3{p}_4-u(1-p_1{p}_2-p_3{p}_4+p_1{p}_2{p}_3{p}_4)=0}$

where ${\displaystyle p_1,p_2,p_3,p_4}$ are the four bonds around the square and ${\displaystyle u}$ is the diagonal bond connecting the vertex between bonds ${\displaystyle p_4,p_1}$ and ${\displaystyle p_2,p_3}$.

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• 2D percolation cluster
• Bootstrap percolation
• Directed percolation
• Effective medium approximations
• Epidemic models on lattices
• Graph theory
• Network science
• Percolation
• Percolation critical exponents
• Percolation theory
• Continuum percolation theory
• Random sequential adsorption
• Uniform tilings

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