8

7

(K8a

6

)

A knot diagram

1

Linearized knot diagam

5 7 8 1 3 2 6 4

Solving Sequence

2,7

3 6 8 4 5 1

c

2

c

6

c

7

c

3

c

5

c

1

c

4

, c

8

Ideals for irreducible components

2

of X

par

I

u

1

= hu

11

+ u

10

− 2u

9

− 3u

8

+ 2u

7

+ 4u

6

− 3u

4

− u

3

+ u

2

− 1i

* 1 irreducible components of dim

C

= 0, with total 11 representations.

1

The image of knot diagram is generated by the software “Draw programme” developed by An-

drew Bartholomew(http://www.layer8.co.uk/maths/draw/index.htm#Running-draw), where we modi-

ﬁed some parts for our purpose(https://github.com/CATsTAILs/LinksPainter).

2

All coeﬃcients of polynomials are rational numbers. But the coeﬃcients are sometimes approximated

in decimal forms when there is not enough margin.

1

I. I

u

1

= hu

11

+ u

10

− 2u

9

− 3u

8

+ 2u

7

+ 4u

6

− 3u

4

− u

3

+ u

2

− 1i

(i) Arc colorings

a

2

=



1

0



a

7

=



0

u



a

3

=



1

u

2



a

6

=



u



a

8

=



−u

3

−u

3

+ u



a

4

=



u

8

− u

6

+ u

4

+ 1

u

8

− 2u

6

+ 2u

4



a

5

=



u

3

u

5

− u

3

+ u



a

1

=



u

8

− u

6

+ u

4

+ 1

u

10

− 2u

8

+ 3u

6

− 2u

4

+ u

2



(ii) Obstruction class = −1

(iii) Cusp Shapes = 4u

10

− 12u

8

− 4u

7

+ 16u

6

+ 8u

5

− 8u

4

− 8u

3

+ 4u + 2

2

(iv) u-Polynomials at the component

Crossings u-Polynomials at each crossing

c

1

, c

3

, c

4

c

8

u

11

− u

10

− 6u

9

+ 5u

8

+ 12u

7

− 6u

6

− 10u

5

− u

4

+ 5u

3

+ u

2

− 1

c

2

, c

6

u

11

+ u

10

− 2u

9

− 3u

8

+ 2u

7

+ 4u

6

− 3u

4

− u

3

+ u

2

− 1

c

5

u

11

+ 3u

10

+ 4u

9

+ u

8

+ 2u

7

+ 8u

6

+ 8u

5

− 5u

4

− 3u

3

+ u

2

+ 4u + 1

c

7

u

11

+ 5u

10

+ ··· + 2u + 1

3

(v) Riley Polynomials at the component

Crossings Riley Polynomials at each crossing

c

1

, c

3

, c

4

c

8

y

11

− 13y

10

+ ··· + 2y −1

c

2

, c

6

y

11

− 5y

10

+ ··· + 2y −1

c

5

y

11

− y

10

+ ··· + 14y −1

c

7

y

11

+ 3y

10

+ ··· − 10y −1

4

(vi) Complex Volumes and Cusp Shapes

Solutions to I

u

1

√

−1(vol +

√

−1CS) Cusp shape

u = −0.959860 + 0.351396I

−1.63627 + 1.27541I −1.47945 − 0.80097I

u = −0.959860 − 0.351396I

−1.63627 − 1.27541I −1.47945 + 0.80097I

u = −0.488025 + 0.800566I

9.03866 − 1.64593I 8.04988 + 0.24481I

u = −0.488025 − 0.800566I

9.03866 + 1.64593I 8.04988 − 0.24481I

u = 1.11640

3.38257 2.18570

u = 1.031510 + 0.521913I

−0.37669 − 4.75030I 2.64109 + 6.77690I

u = 1.031510 − 0.521913I

−0.37669 + 4.75030I 2.64109 − 6.77690I

u = −1.081080 + 0.631709I

7.26485 + 7.02220I 5.50054 − 4.88619I

u = −1.081080 − 0.631709I

7.26485 − 7.02220I 5.50054 + 4.88619I

u = 0.439259 + 0.522038I

1.289960 + 0.454766I 7.19508 − 1.36957I

u = 0.439259 − 0.522038I

1.289960 − 0.454766I 7.19508 + 1.36957I

5

II. u-Polynomials

Crossings u-Polynomials at each crossing

c

1

, c

3

, c

4

c

8

u

11

− u

10

− 6u

9

+ 5u

8

+ 12u

7

− 6u

6

− 10u

5

− u

4

+ 5u

3

+ u

2

− 1

c

2

, c

6

u

11

+ u

10

− 2u

9

− 3u

8

+ 2u

7

+ 4u

6

− 3u

4

− u

3

+ u

2

− 1

c

5

u

11

+ 3u

10

+ 4u

9

+ u

8

+ 2u

7

+ 8u

6

+ 8u

5

− 5u

4

− 3u

3

+ u

2

+ 4u + 1

c

7

u

11

+ 5u

10

+ ··· + 2u + 1

6

III. Riley Polynomials

Crossings Riley Polynomials at each crossing

c

1

, c

3

, c

4

c

8

y

11

− 13y

10

+ ··· + 2y −1

c

2

, c

6

y

11

− 5y

10

+ ··· + 2y −1

c

5

y

11

− y

10

+ ··· + 14y −1

c

7

y

11

+ 3y

10

+ ··· − 10y −1

7