引用：A Catalogue of Lattices（格子的分类）

A Catalogue of Lattices

NOTE: This database has moved to Gabriele Nebe's web site in Aachen.

Please click here.

Keywords: tables, lattices, quadratic forms, lattice packings, lattice coverings, An lattices, An* lattices, anabasic lattice, Barnes-Wall lattices, binary quadratic forms, body-centered cubic lattice, Borcherds's lists of 25-dim lattices, Brandt-Intrau ternary forms, Bravais lattices, contact numbers, Coxeter-Todd lattice, crystallographic lattices, densest packings, Dn lattices, Dn* lattices, E6, E7, E8 lattices and their duals, Eisenstein lattices, Elkies-Shioda lattices, face-centered cubic lattice, Hurwitzian lattices, isodual lattices, William Jagy: ternary forms that are spinor regular but not regular, kissing numbers, Kleinian lattices, Kschischang-Pasupathy lattices, laminated lattices, Leech lattice, links, mean-centered cubic lattice, modular lattices, Mordell-Weil lattices, Newton numbers, Niemeier lattices, Gordon Nipp's tables of quaternary and quinary forms, perfect lattices, Quebbemann lattices, Rao-Reddy code, root lattices,SPLAG, ternary quadratic forms, unimodular lattices, weight lattices, lattices in 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30,31, 32, 33, 34, 35, 36, 38, 39, 40, and higher, dimensions, abbreviations, change library file in html format to standard format, change standard format to GAP format, change standard format to MACSYMA format, change standard format to MAGMA format, change standard format to MAPLE format, change standard format to PARI format, etc.

This data-base of lattices is a joint project of Gabriele Nebe, RWTH Aaachen (nebe(AT)math.rwth-aachen.de) and Neil Sloane. AT&T Shannon Labs (njas(AT)research.att.com).

Our aim is to give information about all the interesting lattices in "low" dimensions (and to provide them with a "home page"!). The data-base now contains about 160,000 lattices!

Remarks

For the format and for various programs to convert to other formats, see ABBREVIATIONS.

A gzipped file containing all the .std files can be downloaded here (about 1 meg).

Warning! Not all the entries have been checked!

Most lattices can be described in many different ways, e.g. the face-centered cubic lattice can be described using three coordinates, as D3, or using four coordinates, as A3. Our policy is that different definitions (or scales) for the same lattice should be in different files. Inside any particular file everything should be on the same scale and should be consistent. The determinant given should be the determinant of the Gram matrix given in the file, and so on.

Contributions of new lattices or additional information about the given lattices will be welcomed.

Usually a star (*) denotes a dual lattice -- but in the file names "*" is replaced by an "s"; and in the two tables below "*" indicates a nonlattice packing that is better than any lattice presently known.

As a general reference for the subject covered in this catalogue see SPLAG

Note that the theta series of many of these lattices can be found in NJAS's On-Line Encyclopedia of Integer Sequences. The sequence 1, 6, 12, 8, 6, 24, 24, ... for example is the theta series of the simple cubic lattice.

The data-base has also benefitted from contributions or suggestions from the following friends:
Richard Borcherds (R.E.Borcherds(AT)pmms.cam.ac.uk), John Conway (conway(AT)math.princeton.edu), Will Jagy (jagy(AT)msri.org), Irving Kaplansky (kap(AT)msri.org), Gordon Nipp (gnipp(AT)calstatela.edu), Richard Parker (richard(AT)ukonline.co.uk), Eric Rains (rains(AT)research.att.com), Alexander Schiemann (aschi(AT)math.uni-sb.de), Bernd Souvignier (bernd(AT)maths.usyd.edu.au), Allan Steel (allan(AT)maths.su.oz.au).

A Table of the Densest Packings Presently Known

(In a separate file)

A Table of the Highest Kissing Numbers Presently Known

(In a separate file)

A Table of Perfect Lattices

(In a separate file)

Unimodular Lattices, Including A Table of the Best Such Lattices

(In a separate file)

Modular Lattices, Including A Table of the Best Such Lattices

(In a separate file)

Named Lattices

The Coxeter-Todd lattice K12
Leech lattice
Leech lattice as a Hurwitzian lattice
Barnes-Wall lattices BW4 = D4, BW4' = D4*, BW8 = E8, BW8' = E8_code, BW16 = LAMBDA16, BW16 as a Hurwitzian lattice, the odd 16-dim Barnes-Wall lattice, BW32, BW32 as a Hurwitzian lattice
Quebbemann lattices Q32, Q32'
Mordell-Weil lattice MW44, Mordell-Weil lattice MW64

Root Lattices and Dual (or Weight) Lattices

The A_n lattices: A1, A2, A3, A4, A5, A6, A7, A8, A9, A10, A11, A12, A13, A14, A15, A16, A17, A18, A19, A20, A21, A22, A23, A24
The A_n* lattices: A1*, A2*, A3*, A4*, A5*, A6*, A7*, A8*, A9*, A10*, A11*, A12*, A13*, A14*, A15*, A16*, A17*, A18*, A19*, A20*, A21*, A22*, A23*, A24*
The D_n lattices: D1, D2, D3, D4, D5, D6, D7, D8, D9, D10, D11, D12, D13, D14, D15, D16, D17, D18, D19, D20, D21, D22, D23, D24
The D_n* lattices: D2*, D3*, D4*, D5*, D6*, D7*, D8*, D9*, D10*, D11*, D12*, D13*, D14*, D15*, D16*, D17*, D18*, D19*, D20*, D21*, D22*, D23*, D24*
The E_n lattices and their duals: E6, E6*, E7, E7a (a second version of E7), E7*, E8, E8 as a Hurwitzian lattice. For other versions of E6, E6*, E7, E7* and E8 see under 6, 7 and8 dimensional lattices below.

Laminated Lattices

Reference: SPLAG Chap. 6.

LAMBDA1 = A1, LAMBDA2 = A2, LAMBDA3 = D3, LAMBDA4 = D4,
LAMBDA5 = D5, LAMBDA6 = E6, LAMBDA7 = E7, LAMBDA8 = E8,
LAMBDA9, LAMBDA10, LAMBDA11_MAX, LAMBDA11_MIN,
LAMBDA12_MAX, LAMBDA12_MID, LAMBDA12_MIN,
LAMBDA13_MAX, LAMBDA13_MID, LAMBDA13_MIN,
LAMBDA14, LAMBDA15, LAMBDA16 = BW16,
LAMBDA17, LAMBDA18, LAMBDA19, LAMBDA20,
LAMBDA21, LAMBDA22, LAMBDA23, LAMBDA24 (The Leech lattice)
LAMBDA25, LAMBDA26, LAMBDA27, LAMBDA28
LAMBDA29, LAMBDA30, LAMBDA31
The table also contains many integral laminated lattices, including these from the paper
W.Plesken, M.Pohst, Constructing integral lattices with prescribed minimum II, Math. Comp. Vol 60 (1993), pp. 817-825:
LAMBDA14.2, LAMBDA14.3, LAMBDA14.4, LAMBDA15.2, LAMBDA15.3, LAMBDA15.4, LAMBDA16.2, LAMBDA16.3, LAMBDA16.4, LAMBDA17.2, LAMBDA17.3, LAMBDA17.4, LAMBDA18.2, LAMBDA18.3,

The KAPPA_n Lattices

Reference: SPLAG Chap. 6.

KAPPA7, KAPPA7*, KAPPA8, KAPPA8*, KAPPA9, KAPPA9*, KAPPA10, KAPPA10*,
KAPPA11, KAPPA11*, KAPPA12 = K12 (The Coxeter-Todd lattice), KAPPA13, KAPPA13*
KAPPA14, KAPPA15, KAPPA16, KAPPA17, KAPPA18, KAPPA19, KAPPA20,
The table also contains the following "integral Kappa's" from the paper
W.Plesken, M.Pohst, Constructing integral lattices with prescribed minimum II, Math. Comp. Vol 60 (1993), pp. 817-825:
KAPPA8.2, KAPPA9.2, KAPPA14.2, KAPPA15.2, KAPPA16.2, KAPPA16.3, KAPPA17.2

Kleinian Lattices

That is, lattices over Z[(1+sqrt(-7))/2].

L20

1-Dimensional Lattices

The integer lattice Z, or (equivalently) the root lattice A1

2-Dimensional Lattices

The root lattices A2, A2*, D2, D2*. The last two are equivalent to the simple square lattice Z2

3-Dimensional Lattices

Face-centered cubic lattice as D3 or as A3
Body-centered cubic lattice as D3* or as A3*
"Mean-centered cuboidal" lattice, the densest isodual lattice in 3 dimensions
The 14 Bravais lattices We give both the classical holotype (the smallest determinant of any classically integral lattice of the type) and the even holotype (the smallest determinant of any even lattice of the type):
cubic P (the simple cubic lattice), cubic P (even), cubic I, cubic I (even), cubic F, cubic F (even),
hexagonal P, hexagonal P (even),
tetragonal P, tetragonal P (even), tetragonal I, tetragonal I (even),
trigonal (or rhombohedral) R, trigonal (or rhombohedral) R (even),
digonal (or orthorhombic) P, digonal (or orthorhombic) P (even), digonal (or orthorhombic) C, digonal (or orthorhombic) C (even), digonal (or orthorhombic) I, digonal (or orthorhombic) I (even), digonal (or orthorhombic) F, digonal (or orthorhombic) F (even),
monoclinic P, monoclinic P (even), monoclinic C, monoclinic C (even),
triclinic P, triclinic P (even),
The Brandt-Intrau tables of primitive positive-definite odd ternary quadratic forms and even ternary quadratic forms of discriminants up to -1000, as recomputed by Alexander Schiemann.
William C. Jagy, Table of integer coefficient positive ternary quadratic forms that are spinor regular but are not regular.

4-Dimensional Lattices

The root lattices D4, F4 (the same lattice as D4), D4*, A4, A4*
D4 as a Hurwitzian lattice
The 4-D simple cubic lattice
4-d modular lattices: 5-modular, strongly 6-modular in "-" genus, strongly 6-modular in "+" genus, 7-modular, 11-modular, strongly 14-modular, strongly 15-modular in genus "-", strongly 15-modular even lattice E(15) in genus "+", strongly 15-modular odd associate O(15) of previous lattice , 23-modular lattice
Gordon Nipp's table of 74,000 reduced regular primitive positive-definite quaternary quadratic forms of discriminants up through 1732.

5-Dimensional Lattices

The lattices (A5)+2, P5.2 = (A5)+3
The root lattices D5, D5*, A5, A5*
Gordon Nipp's table of 48,000 reduced regular primitive positive-definite quinary quadratic forms of discriminants up through 513.

6-Dimensional Lattices

The root lattices A6 = P6.7, A6*, D6 = P6.3, D6*, E6 = P6.1, another version of E6, E6* = P6.2
The other perfect lattices in six dimensions: P6.4 = A6,2, P6.5 = A6 sup (2), P6.6 = A6,1
Other 6-dimensional lattices: M6,2 = Q_6(4)^{+2} = F_15, the unique indecomposable lattice of det 8,
Some modular lattices: a 3-modular lattice of minimal norm 2, a 7-modular lattice of minimal norm 3, O(7), a strongly 8-modular lattice of minimal norm 4, an 11-modular lattice of minimal norm 4 (in the "-" genus), an 11-modular lattice of minimal norm 4 (in the "+" genus), a strongly 14-modular lattice of minimal norm 4, a 23-modular lattice of minimal norm 7

7-Dimensional Lattices

See also under perfect lattices above.
The root lattices A7, A7*, D7, D7*, E7, another version of E7, a third version of E7, E7*, another version of E7*
The lattices KAPPA7, KAPPA7*

8-Dimensional Lattices

The root lattices A8, A8*, D8, D8*, E8, another version of the root lattice E8
The coding theory version of E8
- this and the root lattice version of E8 are the two 8-dim. Barnes-Wall lattices.
E8 as a Hurwitzian lattice
The lattices KAPPA8, KAPPA8*, KAPPA8.2
Other integral lattices: A2 tensor D4, H4, (A2 X A4)*, M8,3, odd 5-modular lattice O(5), odd 6-modular lattice O(6), extremal 11-modular lattice in genus "-" extremal 11-modular lattice in genus "+" extremal strongly 14-modular lattice in genus "+" extremal strongly 15-modular lattice in genus "+" extremal strongly 15-modular lattice in genus "+"
See Jacques Martinet's home page for a list of the known perfect lattices in 8 dimensions.
8-Dim. isodual lattice from Bring curve

9-Dimensional Lattices

10-Dimensional Lattices

11-Dimensional Lattices

The laminated lattices LAMBDA11_MAX, LAMBDA11_MIN
The lattices KAPPA11, KAPPA11*
A lattice without a basis of minimal vectors
The root lattices D11, D11*, A11, A11*

12-Dimensional Lattices

The Coxeter-Todd lattice K12
The laminated lattices LAMBDA12_MAX, LAMBDA12_MID, LAMBDA12_MIN
Lattices from the maximal finite subgroups of GL(12,Q) [see G. Nebe, W. Plesken, Finite rational matrix groups. AMS-Memoir No. 556, vol. 116 (1995)]: C6.PSU(4,3).(C2 x C2),((3+^(1+2):SL(2,3)) x SL(2,3)).C2, (C2 x D10 x A5):C2, (SL(2,5) Y SL(2,3)).C2, A2xM6,2, (C2 x C3.Alt6).(C2 x C2), (PSL(2,7) x D8):C2, (PSL(2,7) x D8):C2, A2xA6, A2 x A6^(2)
The unimodular lattice D12+
The complete list of even 3-modular lattices in 12 dimensions: The Coxeter-Todd lattice K12 as a modular lattice, A1^6.sqrt(3)A1^6, A2^3.sqrt(3)A2^3, A3^2.sqrt(3)A3^2,A6.sqrt(3)A6, D6.sqrt(D6), E6.sqrt(3)E6, G2.A5.sqrt(3)A5, G2^2.D4.sqrt(3)D4, G2^6
An extremal strongly 6-modular lattice.

The root lattices D12, D12*, A12, A12*

13-Dimensional Lattices

The laminated lattices LAMBDA13_MAX, LAMBDA13_MID, LAMBDA13_MIN
The lattices KAPPA13, KAPPA13*
The lattices C2 x L(3,3):C2 = Q'_13(4)^{+2}, C2 x PSL(2,25):C2 = Q_13(2)^{+2}
The root lattices D13, D13*, A13, A13*

14-Dimensional Lattices

The laminated lattice LAMBDA14
The unimodular lattice E7^2+
Lattices from the maximal finite subgroups of GL(14,Q) [see G. Nebe, W. Plesken, Finite rational matrix groups. AMS-Memoir No. 556, vol. 116 (1995)]: LAMBDA14.2,LAMBDA14.3, LAMBDA14.4, KAPPA14, KAPPA14.2
The lattices C2 x G(2,3), (SU(3,3) x C4).C2, A2 x E7, C2 x S7, C2 x S8, M14,2, M14,3, M14,6
The root lattices D14, D14*, A14, A14*

15-Dimensional Lattices

The laminated lattice LAMBDA15
The lattices LAMBDA15.2, LAMBDA15.3, LAMBDA15.4, KAPPA15, KAPPA15.2
Lattices from the maximal finite subgroups of GL(15,Q) [see G. Nebe, W. Plesken, Finite rational matrix groups. AMS-Memoir No. 556, vol. 116 (1995)]: Lambda2(E6), C2 x Sp(6,2), Lambda2(A6)
The unimodular lattice A15+
The root lattices D15, D15*, A15, A15*

16-Dimensional Lattices

Laminated lattice LAMBDA16 = Barnes-Wall BW16, another version of BW16; BW16 as a Hurwitzian lattice; the odd Barnes-Wall lattice; Overlattice of the Barnes-Wall lattice of minimum 3;
The lattices LAMBDA16.2, LAMBDA16.3, LAMBDA16.4, KAPPA16, KAPPA16.2, KAPPA16.3
Lattices from the maximal finite subgroups of GL(16,Q) [see G. Nebe, W. Plesken, Finite rational matrix groups. AMS-Memoir No. 556, vol. 116 (1995)]: The lattices (SL(2,9) Y SL(2,9)).(C2 x C2), E8 x A2, ((Sp(4,3) x C3) Y SL(2,3)).C2, (((SL(2,5) Y SL(2,5)):C2) x D10):C2, C2 x (S5 x S5):C2, C2.A10, A4 x F4, (SL(2,5) Y (D8 Y Q8).A5).C2, A2xH4, (SL(2,5) Y SL(2,9)):C2, (C2 x Alt6).(C2 x C2), (SL(2,5) Y ((SL(2,3) x C3).C2)).C2, D120.(C4 x C2), (SL(2,7) Y C2.S3).C2, C2 x S3 x PGL(2,7), (C2.Alt7 Y C2.S3).C2, (SL(2,7) Y C2.S3).C2, D120.C2, D120.C2.b, A16^(3)
Root lattices A16, A16*, D16, D16*

17-Dimensional Lattices

Laminated lattice LAMBDA17
The lattices LAMBDA17.2, LAMBDA17.3, LAMBDA17.4, KAPPA17, KAPPA17.2
The eight lattices associated with the group C2 x L(2,16):C4, namely Q_17(6), Q_17(6)^{+2}, Q_17(6)^{+3}, Q_17(6)^{+6}, Q'_17(6), Q'_17(6)^{+2}, Q'_17(6)^{+3},Q'_17(6)^{+6}
Root lattices A17, A17*, D17, D17*

18-Dimensional Lattices

Laminated lattice LAMBDA18
The lattices LAMBDA18.2, LAMBDA18.3, KAPPA18
Lattices from the maximal finite subgroups of GL(18,Q) [see G. Nebe, W. Plesken, Finite rational matrix groups. AMS-Memoir No. 556, vol. 116 (1995)]: (C2 x Sp(4,4)).C2,(C2 x 3^(1+4):Sp(4,3)).C2, (C2 x Alt5 x Alt5).(C2 x C2), (C2 x C3.Alt6).(C2 x C2), A2xA9, (C2 x PSL(2,7) x PSL(2,7)).(C2 x C2), M18,2, M18,4, A18^(5)
Root lattices A18, A18*, D18, D18*

19-Dimensional Lattices

Laminated lattice LAMBDA19
The lattice KAPPA19
Root lattices A19, A19*, D19, D19*

20-Dimensional Lattices

Lattices from the maximal finite subgroups of GL(20,Q) [see G. Nebe, W. Plesken, Finite rational matrix groups. AMS-Memoir No. 556, vol. 116 (1995)]: (SU(5,2) x SL(2,3)).C2, C2.M12.C2, (D8 x S6).C2, F4 x A5, (C2 x SU(4,2)).C2, (SU(4,2) x C6).C2, C2 x 5^(1+2):GL(25), A4 x A5, (C2.PSL(3,4)).(C2 x C2), C2.M22.C2, C2 x S7, (C2 x PSL(3,4)).(C2 x S3), C2 x S8, (PSL(2,11) x D12).C2, (PSL(2,11) x D12).C2, (SL(2,11) Y SL(2,3)).C2, A2 x A10, C2 x S3 x PGL(2,11), C2 x S3 x PGL(2,11), M20,3
Kleinian lattice L20 with group 2.M22.2
Hurwitzian lattice L5(P^5)
Hurwitzian lattice R20
Cyclo-quaternionic lattice L_20,4
Cyclo-quaternionic lattice A_11.otimes(3).A_2
Laminated lattice LAMBDA20
The lattice KAPPA20
The three extremal 2-modular lattices: (SU(5,2) x SL(2,3)).C2, C2.M12.C2, HS20
Root lattices A20, A20*, D20, D20*

21-Dimensional Lattices

Lattices from the maximal finite subgroups of GL(21,Q) [see G. Nebe, W. Plesken, Finite rational matrix groups. AMS-Memoir No. 556, vol. 116 (1995)]: Lambda2(E7), (C2 x PSU(4,3)).D8, C2 x Sp(6,2), (C2 x PSU(3.5)).S3, C2 x S7
Laminated lattice LAMBDA21
Root lattices A21, A21*, D21, D21*

22-Dimensional Lattices

Lattices from the maximal finite subgroups of GL(22,Q) [see G. Nebe, W. Plesken, Finite rational matrix groups. AMS-Memoir No. 556, vol. 116 (1995)]: (C2 x PSU(6,2)).S3,A2 x A11, (C2 x HS).C2, (C2 x Mc).C2, hA22^(2), hA22^(3), A22^(4), A22^(6)
Laminated lattice LAMBDA22
Root lattices A22, A22*, D22, D22*
Extremal 3-modular lattice of minimum 4

23-Dimensional Lattices

24-Dimensional Lattices

Leech lattice LAMBDA24; another version of Leech; Leech lattice as a Hurwitzian lattice; the odd Leech lattice
The Niemeier Lattices (see SPLAG Table 16.1).
Here are the 23 Niemeier lattices, labeled by their root system: D24, D16_E8, 3E8, A24, 2D12, A17_E7, D10_2E7, A15_D9, 3D8, 2A12, A11_D7_E6, 4E6, 2A9_D6, 4D6, 3A8,2A7_2D5, 4A6, 4A5_D4, 6D4, 6A4, 8A3, 12A2, 24A1
Hurwitzian lattices L6(P^6), J24, R24
Cyclo-quaternionic (extremal 3-modular) lattice C((5+sqrt(13))/2)L_24,2

An extremal 11-modular lattice (4+sqrt(5)) x Leech

Lattices from the maximal finite subgroups of GL(24,Q) [see G. Nebe, Finite subgroups of GL(24,Q). Exp. Math. Vol. 5, Number 3 (1996), 163-195]: (((SL(2,5) Y SL(2,5)):C2) x Alt5).C2, (C6.PSU(4,3).C2 Y SL(2,3)).C2, ((C2 x C3.Alt6).C2 Y SL(2,3)).C2, (Sp(4,3) x 3^(1+2):SL(2,3)).C2, F4xE6, (C3.S6 x D8).C2, (C6.PSL(3,4).C2 Y D8).C2, ((SL(2,3) Y C4).C2 x PSU(3,3)).C2, (C2.J2 Y SL(2,5)):C2, (SL(2,5) Y (D8 Y Q8).A5).C2, (((SL(2,5) Y SL(2,5)):C2) x A5):C2, W(F4) x S5, (SL(2,5) Y (C2 x 3^(1+2)).GL(2,3)).C2, S3 x (SL(2,5) Y SL(2,3)).C2, (PSL(2,7) x W(F4)).C2, (PSL(2,7) x W(F4)).C2, F4 x A6, W(F4) x PGL(2,7), (SL(2,13) Y SL(2,3)).C2, (SL(2,7) x PSL(2,7)).C2, C6.Alt7:C2, (C3.M10 x SL(2,3)).C2, (Alt5 x ((C3 x D8).C2)).C2, (C3.M10 x D8).C2, S3 x ((PSL(2,7) x D8).C2), S3 x ((PSL(2,7) x D8).C2), ((C2 x PSL(3,3)).C2 x C3).C2, A2 x A12, (C2 x D78).C12, A4 x E6, (C2 x C3.PGL(2,9) x D10).C2, S3 x (C2 x D10 x A5).C2, (C2 x PSU(4,2)).C2, SL(2,7) Y (C2.S4), (SL(2,7) Y Q16).C2, A4xA6, C2 x S5 x PGL(2,7), (SL(2,11) Y SL(2,3)).C2, C2 x PSL(2,11):C2
Root lattices A24, A24*, D24, D24*

25-Dimensional Lattices

Laminated lattice LAMBDA25
R. E. Borcherds's list of 25-Dim. unimodular lattices; also two explicit examples, with kissing numbers 2 and 92.
R. E. Borcherds's list of even 25 -dimensional lattices of determinant 2.

Lattices from the maximal finite subgroups of GL(25,Q) [see G. Nebe, Finite subgroups of GL(n,Q) for 25 <= n <= 31. Comm. Algebra 24 (7) (1996), 2341-2397]: A5 tilde(otimes) A5, C2xPSL(2,49):2
The root lattice D25

26-Dimensional Lattices

Bachoc's 13-dimensional Eisenstein lattice,
Laminated lattice LAMBDA26
The Conway-Borcherds unimodular lattices S26 and T26
Lattices from the maximal finite subgroups of GL(26,Q)
[See G. Nebe, Finite subgroups of GL(n,Q) for 25 <= n <= 31. Comm. Algebra 24 (7) (1996), 2341-2397.] L4(3):2, S6(3)C3.2, S4(5):2, L2(25):2^2, L2(25):2, L2(25):2

27-Dimensional Lattices

Laminated lattice LAMBDA27
Borcherds's unimodular lattice T27 with minimal norm 3.
Lattices from the maximal finite subgroups of GL(27,Q) [see G. Nebe, Finite subgroups of GL(n,Q) for 25 <= n <= 31. Comm. Algebra 24 (7) (1996), 2341-2397]: S9, L3(3):2

28-Dimensional Lattices

Bachoc's 14-dimensional Eisenstein lattice,
Hurwitzian lattice L7(P^7)
Hurwitzian lattice L7(P^3)
Hurwitzian lattice L7(P)
Hurwitzian lattice LL28
Hurwitzian lattice R28
Hurwitzian lattice R28'
Hurwitzian lattice R28''
Lattices from the maximal finite subgroups of GL(28,Q) [see G. Nebe, Finite subgroups of GL(n,Q) for 25 <= n <= 31. Comm. Algebra 24 (7) (1996), 2341-2397]: Sp6(3)C3.2,2.J2YSL(2,3).2, O8+(2):S3, Sz(8):3YC4, J2.2, G2(3)xS3.2, U3(3)(Q8C4).S3.2, U3(5):2, S8, J2:2, SL2(13)YSL2(3).2, L2(13)S3.2
Laminated lattice LAMBDA28
Extremal 2-modular lattice of minimum 4
Extremal 5-modular lattice of minimum 8

29-Dimensional Lattices

30-Dimensional Lattices

Lattices from the maximal finite subgroups of GL(30,Q) [see G. Nebe, Finite subgroups of GL(n,Q) for 25 <= n <= 31. Comm. Algebra 24 (7) (1996), 2341-2397]: U4(2):2,3.U4(3).2^2, U4(2)3^1+2:SL2(3).2, 3.Alt6.2^2, 3.L3(4).2^2, 3.S7, M30,2, hat(A)30^(4), hat(A)30^(8)
Laminated lattice LAMBDA30
A 30-dim. section of Quebbemann lattice Q32

31-Dimensional Lattices

Lattices from the maximal finite subgroups of GL(31,Q) [see G. Nebe, Finite subgroups of GL(n,Q) for 25 <= n <= 31. Comm. Algebra 24 (7) (1996), 2341-2397]: L2(32):5,L3(5):2
Laminated lattice LAMBDA31
A 31-dim. section of the Quebbemann lattice Q32
An extremal unimodular lattice in dimension 31

32-Dimensional Lattices

Barnes-Wall BW32, BW32 as a Hurwitzian lattice
Quebbemann lattices Q32, Q32'
Bachoc's 8-dimensional Hurwitzian lattice,
Bachoc's 16-dimensional Eisenstein lattice,
Cyclo-quaternionic lattices C((5+sqrt(17))/2)L_32,2, L_32,2, L_32,6

32-dimensional even unimodular lattices

These have not yet been classified, and perhaps never will be. However, the mass (the sum of reciprocals of orders of automorphism groups) of all inequivalent 32 dimensional even unimodular lattices having any prescribed root system has been determined by Oliver King (king(AT)math.berkeley.edu). (Root systems which aren't listed have mass zero.)

The 15 Koch-Venkov extremal 32-dimensional unimodular lattices:

LAMBDA(RM)=BW32, LAMBDA(QR), LAMBDA(G), LAMBDA(F), LAMBDA(U),
LAMBDA(C1), LAMBDA(C2), LAMBDA(C3), LAMBDA(C4), LAMBDA(C5),
LAMBDA(G1), LAMBDA(G2), LAMBDA(G3), LAMBDA(G4), LAMBDA(S3)