Embeddings of manifolds with boundary: classification

Theorem 2.1. Assume that $N$ is a compact connected $n$-manifold.

(a) Then $N$ embeds into $\mathbb R^{2n}$.

(b) If $N$ has non-empty boundary, then $N$ embeds into $\mathbb R^{2n-1}$.

Theorem 2.2. Assume that $N$ is a compact connected $n$-manifold and either

(a) $m \ge 2n+1 \ge 5$ or

(b) $N$ has non-empty boundary and $m\geq 2n$.

Then any two embeddings of $N$ into $\mathbb R^m$ are isotopic.

Lemma 3.1. [Wall1966] Assume that $N$ is a closed connected $n$-manifold. Then $N_0$ have handle decomposition with indices of attaching maps at most $n-1$.

Lemma 3.2. Assume that $U$ is a compact $n$-manifold, $\phi:\partial D^i\times D^{n-i}\to \partial U$ is an embedding with $i\leq n-1$, and $f:U \to \mathbb R^{m}$ is an embedding.

$(a)$ If $m=2n-1$, then there is an extension of $f$ to an embedding of $U\cup_{\phi} D^i\times D^{n-i}$.

$(b)$ Assume also that there is an embedding $g : D^i\times 0 \to \mathbb R^m$ such that $f\phi = g$ on $\partial D^i \times 0$. Suppose that on $g(D^i\times 0)$ there is a field of $n-i$ linear independed normal vectors whose restriction to $f(\partial D^i\times 0)$ is tangent to $f(U)$. Then $f\cup g$ extends to a embedding $U \cup_{\phi} D^i\times D^{n-i} \to\ \mathbb R^m$.

Denote by $A$ the $(n-i)\times n$ matrix whose rightmost $(n-i)\times (n-i)$ block is the identity matrix, and whose other elements are zeros. Denote by $v$ the field of $n-i$ normal vectors on $\partial D^i\times 0\subset D^i\times D^{n-i}$ such that the $k$-th vector has coordinates equal to the $k$-th row in $A$. Then the vector field $d\phi (v)= (d\phi (v_1),\ldots , d\phi (v_{n-i}))$ is tangent to $\partial U$. For $x\in g_1(\partial D^i\times 0)$ denote by $v'(x)$ the projection of $df(d\phi(v(x)))$ to the intersection of normal space to $g_1(\partial D^i\times 0)$ at $x$, and tangent space to $f(\partial U)$ at $x$. Since $i-1<2n-1 - (n-i)$, it follows that $\pi_{i-1}(V_{2n-1, n-i})=0$. Hence there is an extension of $v'$ to an linearly independent field of vectors normal to $g_1(D^i\times 0)$. Then by Lemma 3.2.(b) there is an extension of $f\cup g_1$ to an embedding of $U \cup_{\phi} D^i\times D^{n-i}$.

$\square$

Lemma 3.3. Assume that $U$ is a compact $n$-manifold, $\phi:\partial D^i\times D^{n-i}\to \partial U$ is an embedding with $i\leq n-1$, $f_0, f_1: U\cup_{\phi} D^i\times D^{n-i}\to \mathbb{R}^m$ are embeddings and $F:U\times [0, 1]\to \mathbb{R}^m\times [0, 1]$ is a concordance between $f_0|_U$ and $f_1|_U$.

$(a)$ If $m\geq 2n$, then there is an extension of $F$ to a concordance between $f_0$ and $f_1$.

$$\displaystyle F(U\times [0, 1])\quad\text{to}\quad f_0(D^i\times D^{n-i})\times 0,\quad\text{and to}\quad f_1(D^i\times D^{n-i})\times 1,$$

$$\displaystyle \bar{\phi}:\partial (D^i\times [0, 1])\times D^{n-i}\to \partial U\times[0, 1]\cup_{\phi\times 0} D^i\times D^{n-i}\times 0 \cup_{\phi\times 1} D^i\times D^{n-i}\times 1$$

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$$\displaystyle \dim(D^i\times 0\times [0, 1]) + \dim (U\times [0, 1])\leq (i+1)+(n+1)\quad\text{and}\quad 2\dim(D^i\times 0\times [0, 1])+1\leq 2n+1\leq m+1,$$

$$\displaystyle G: D^i\times 0\times [0, 1]\to \mathbb R^m\times [0, 1]$$

Denote by $A$ the $(n-i)\times (n+1)$ matrix whose rightmost $(n-i)\times (n-i)$ submatrix is the identity matrix, and whose other elements are zeroes. Denote by $v$ the field of $n-i$ normal vectors on $\partial (D^i\times 0\times [0, 1])\subset D^i\times D^{n-i}\times [0, 1]$ whose $k$-th vector has coordinates equal to the $k$-th row in $A$. Then $d\bar{\phi} (v)= (d\bar{\phi} (v_1),\ldots , d\bar{\phi} (v_{n-i}))$ is the vector field tangent to $\bar{\phi}(\partial (D^i\times [0, 1])\times D^{n-i})$. For $x\in G_1(\partial (D^i\times 0\times [0, 1])$ denote by $v'(x)$ the projection of $d(F\cup f_0\cup f_1)d\phi (v(x))$ to the intersection of normal space to $G_1(D^i\times 0\times [0, 1])$ at $x$, and tangent space to $F(\partial(U\times [0, 1]))$ at $x$. Since $i<m+1-(n-i)$, it follows that $\pi_{i}(V_{m+1, n-i})=0$. Hence there is an extension of $v'$ to a linear independent field of vectors normal to $G_1(D^i\times 0\times [0, 1])$. Then by Lemma 3.3.(b) there is an extension of $F\cup G_1$ to a concordance $(U \cup_{\phi} D^i\times D^{n-i})\times [0, 1]$.

$\square$

Example 4.1. Let $N=S^k\times [0, 1]$ be the cylinder over $S^k$.

(a) Then there exist non-isotopic embeddings of $N$ into $\mathbb R^{2k+1}$.

(b) Then for each $a\in\mathbb Z$ there exist an embedding $f\colon N\to\mathbb R^{2k+1}$ such that $\mathrm{lk}(f(S^k\times 0), f(S^k\times 1))=a$.

(c) Then $l\colon \mathrm{Emb}^{2k+1}N\to\mathbb Z$ defined by the formula $l([f]) = \mathrm{lk}(f(S^k\times 0), f(S^k\times 1))$ is well-defined and is a bijection for $k\geqslant2$.

Proof. Proof of part (b). Informally speaking by twisting a ribbon one can obtain arbitrary value of linking coefficient. Let $h\colon S^k\to S^k$ be a map of degree $a$. (To prove part (a) it is sufficient to take as $h$ the identity map of $S^k$ as a map of degree one and the constant map as a map of degree zero.) Define $g\colon S^k\times [0, 1] \to D^{k+1}\times S^k$ by the formula $g(x, t) = (x, h(x)t)$.

Let $f=\mathrm i\circ g$, where $\mathrm i = \mathrm i_{2k+1, k}\colon D^{k+1}\times S^k \to \mathbb R^{2k+1}$ is the standard embedding.Thus $\mathrm{lk}(f(S^k\times0), f(S^k\times1)) = a$.

Proof of part (c). Clearly $l$ is well-defined. By (b) $l$ is surjective. Now take any two embeddings $f_1, f_2$ such that $l([f_1]) = l([f_2])$. Each embedding of a cylinder gives an embedding of a sphere with a normal field. Moreover, isotopic embeddings of cylinders gives isotopic embeddings of spheres with normal fields.

$\square$

Example 4.2. Let $N=S^k\times S^1$. Assume $k>2$. Then there exists a bijection $l\colon\mathrm{Emb}^{2k+1}N_0\to\mathbb Z$ defined by the formula $l([f])=\mathrm{lk}(S^k\times1_1, S^k\times-1_1)$.

Example 4.3. Let $N=S^k_a\times S^1 \# S^k_b\times S^1$ be the connected sum of two tori. Then there exists a surjection $l\colon\mathrm{Emb}^{2k+1}N_0\to\mathbb Z$ defined by the formula $l([f])=\mathrm{lk}(f(S^k_a\times1_1), f(S^k_b\times1_1))$.

Example 4.4. (a) Let $N_0$ be the punctured 2-torus containing the meridian $x$ and the parallel $y$ of the torus. For each embedding $f\colon N_0\to\mathbb R^3$ denote by $s$ the normal field of $\epsilon$-length vectors to $f(N_0)$ defined by orientation on $N_0$ (see figure (b)). Then there exists a surjection $l\colon\mathrm{Emb}^3 N_0\to\mathbb Z$ defined by the formula $l([f])=\mathrm{lk}(f(x), s(y))$.

(b) Let $f_1,f_2\colon N_0\to\R^3$ be two embeddings shown on figure (a). Figure (c) shows that $l(f_1)=1$ and $l(f_2)=0$ which proves the intuitive fact that $f_1$ and $f_2$ are not isotopic. (Notice that the restrictions of $f_1$ and $f_2$ on $x\cup y$ are isotopic!) If we use the opposite normal vector field $s'=-s$, the values of $l(f_1)$ and $l(f_2)$ will change but will still be different (see figure (d)).

Lemma 5.1. There exists a nowhere vanishing normal vector field to $f(N_0)$.

Lemma 5.2 ($L$ is well-defined). The integer $L(f)(x, y)$:

• is well-defined, i.e., does not change when $s$ is replaced by $s'$,
• does not change when $x$ or $y$ are changed to homologous cycles and,
• does not change when $f$ is changed to an isotopic embedding.

Lemma 5.3. For every $X, Y \in H_{n-1}(N_0)$ the following equality holds:

$$\displaystyle \rho_2L(f)(X, Y) = \mathrm{PD}\bar w_{n-2}(N_0)\cap\rho_2X\cap\rho_2Y.$$

Definition 6.1. For each even $n$ define an invariant $W\Lambda\colon\mathrm{Emb}^{2n-1}N_0\to H_1(N;\mathbb Z_2)$. For each embedding $f\colon N_0\to\mathbb R^{2n-1}$ construct any PL embedding $g\colon N\to\mathbb R^{2n}$ by adding a cone over $f(\partial N_0)$. Now let $W\Lambda([f]) = W(g)$, where $W$ is Whitney invariant, [Skopenkov2016e, $\S$5].

Lemma 6.2. The invariant $W\Lambda$ is well-defined for $n\ge4$.

Proof. Note that Unknotting Spheres Theorem implies that $\partial N_0$ unknots in $\mathbb R^{2n}$. Thus $f|_{\partial N_0}$ can be extended to embedding of an $n$-ball $B^n$ into $\mathbb R^{2n}$. Unknotting Spheres Theorem implies that $n$-sphere unknots in $\mathbb R^{2n}$. Thus all extensions of $f$ are isotopic in PL category. Note also that if $f$ and $g$ are isotopic then their extensions are isotopic as well. And Whitney invariant $W$ is invariant for PL embeddings.

$\square$

Definition 6.3 of $G:\mathrm{Emb}^{2n-1}N_0\to B_n^*H_{n-1}(N)$ if $n$ is even and $H_1(N)$ is torsion-free. Take a collection $\{f_z\}_{z\in H_1(N;\Z_{(n-1)})}\subset \mathrm{Emb}^{2n-1} N_0$ such that $W\Lambda(f_z)=z$. For each $f$ such that $W\Lambda(f)=z$ define

$$\displaystyle G(f)(x,y):=\frac{1}{2}\left(L(f)(x,y)-L(f_z)(x,y)\right)$$

where $x,y\in H_{n-1}(N_0)$.

Theorem 6.4. Let $N$ be a closed connected orientable $n$-manifold with $H_1(N)$ torsion-free, $n\ge 4$, $n$ even. The map

$$\displaystyle G\times W\Lambda:\ \mathrm{Emb}^{2n-1}N_0\to B_n^* H_{n-1}(N) \times H_1(N;\Z_{2}),$$

is one-to-one.

Lemma 6.5. For each even $n\in H_{n-1}(N)$ and each $x$ the following equality holds: $W\Lambda(f)\cap \rho_2(x) = \rho_2\left(\frac{1}{2}L(f)(x, x) - \frac{1}{2}L(f_0)(x, x)\right)$.

Theorem 6.6. Let $N$ be a closed connected orientable $n$-manifold with $H_1(N)$ torsion-free, $n\ge 4$, $n$ even. Then

(a) The map $L: \mathrm{Emb}^{2n-1}N_0\to B_n^*H_{n-1}(N)$ is an injection.

(b) The image of $L$ consists of all symmetric bilinear forms $\phi:H_{n-1}(N)\times H_{n-1}(N)\to \Z$ such that $\rho_2\phi(x,y)= \bar w_2(N_0)\cap\rho_2(x\cap y)$. Here $\bar w_2(N_0)$ is the normal Stiefel-Whitney class.

Theorem 7.1. Assume that $N$ is a closed $k$-connected $n$-manifold.

(a) If $n\geq 2k+3$, then $N$ embeds into $\mathbb R^{2n-k}$.

(b) If $n\geq 2k+2$ and $k\geq0$, then $N_0$ embeds into $\mathbb R^{2n-k-1}$.

Theorem 7.2. Assume that $N$ is a closed $k$-connected $n$-manifold.

(a) If $m \ge 2n - k + 1$ and $n\ge2k + 2$, then any two embeddings of $N$ into $\mathbb R^m$ are isotopic.

(b) If $m \ge 2n - k$ and $n\ge k + 3$ and $(n, k) \notin \{(5, 2), (4, 1)\}$ then any two embeddings of $N_0$ into $\mathbb R^m$ are isotopic.

Conjecture 7.3. Assume that $N$ is a closed $1$-connected $4$-manifold. Then any two embeddings of $N_0$ in $\mathbb R^7$ are isotopic.

Theorem 7.4. Assume $N$ is a closed $k$-connected $n$-manifold. Then for each $k\ge1$ there exists a bijection

$$\displaystyle W_0'\colon \mathrm{Emb}^{2n-k-1}(N_0)\to H_{k+1}(N;\mathbb Z_{(n-k-1)}),$$

where $\mathbb Z_{(s)}$ denote $\mathbb Z$ for $s$ even and $\mathbb Z_2$ for $s$ odd.

Theorem 8.1. Assume that $N$ is a compact $k$-connected $n$-manifold, $\partial N\neq\emptyset$, $(N, \partial N)$ is $k$-connected and $k< n - 3$. Then $N$ embeds into $\mathbb R^{2n-k-1}$.

Theorem 8.2. Assume that $N$ is a $n$-manifold. If $N$ has $(n-k-1)$-dimensional spine, $\partial N \neq \emptyset$, $m \ge 2n - k$, then any two embeddings of $N$ into $\mathbb R^m$ are isotopic.

Theorem 8.3. Every compact connected $n$-manifold $N$ with boundary for which $(N, \partial N)$ is $k$-connected, $\pi_1(\partial N)=0$, $k + 3 \le n$ and $(n, k) \notin \{(5, 2), (4, 1)\}$, has an $(n − k − 1)$-dimensional spine.

Theorem 9.1.[Smale-Hirsch; [Hirsch1959] and [Haefliger&Poenaru1964]] The space of immersions of a manifold in $\R^m$ is homotopy equivalent to the space of linear monomorphisms from $TM$ to $\R^m$.

Theorem 9.2.[[Hirsch1959, Theorem 6.4]] If $N$ is immersible in $\R^{m+r}$ with a normal $r$-field, then $N$ is immersible in $\R^m$.

Theorem 9.3. Every $n$-manifold $N$ with non-empty boundary is immersible in $\R^{2n-1}$.

Theorem 9.4.[Whitney; [Hirsch1961a, Theorem 6.6]] Every $n$-manifold $N$ is immersible in $\R^{2n-1}$.

Theorem 9.5. Suppose $N$ is a $n$-manifold with non-empty boudary, $(N,\partial N)$ is $k$-connected. Then $N$ is immersible in $\R^m$ for each $m\geq2n-k-1$.

Proof. It suffices to show that exists an immersion of $N$ in $\mathbb R^{2n-k-1}$. It suffices to show that exists a linear monomorphism from $TM$ to $\mathbb R^{2n-k-1}$. Let us construct such a linear monomorphism by skeleta of $N$. It is clear that a linear monomorphism exists on $0$-skeleton of $N$.

The obstruction to extend the linear monomorphism from $(r-1)$-skeleton to $r$-skeleton lies in $H_{n-r}(N, \partial N; \pi_{r-1}(V_{2n-k-1,n}))$.

For $r=1,\ldots,n-k-1$ we know $\pi_{r-1}(V_{2n-k-1, n}) = 0$. For $r=n-k,\ldots, n$ we have $H_{n-r}(N, \partial N; *) = 0$ since $(N, \partial N)$ is $k$-connected and has non-empty boundary.

Thus the obstruction is always zero and such linear monomorphism exists.

$\square$

Theorem 9.6. Suppose $N$ is a connected $n$-manifold with non-empty boudary, $(N, \partial N)$ is $k$-connected and $m\geq2n-k$. Then every two immersions of $N$ in $\R^m$ are regulary homotopic.

Proof. It suffies to show that exists homomotphism of any two linear monomorphisms from $TM$ to $\mathbb R^{2n-k}$. Lets cunstruct such homotopy on each $r$-skeleton of $N$. It is clear that homotopy exists on $0$-skeleton of $N$.

The obstruction to extend the homotopy from $(r-1)$-skeleton to $r$-skeleton lies in $H_{n-r}(N, \partial N; \pi_r(V_{2n-k, n}))$.

For $r=1,\ldots,n-k-1$ we know $\pi_r(V_{2n-k, n}) = 0$. For $r=n-k,\ldots, n$ we have $H_{n-r}(N, \partial N; *) = 0$ since $(N, \partial N)$ is $k$-connected and $N$ has non-empty boundary.

Thus the obstruction is always zero and such homotopy of linear monomorphisms exists.

$\square$

Theorem 2.1. Assume that $N$ is a compact connected $n$-manifold.

(a) Then $N$ embeds into $\mathbb R^{2n}$.

(b) If $N$ has non-empty boundary, then $N$ embeds into $\mathbb R^{2n-1}$.

Theorem 2.2. Assume that $N$ is a compact connected $n$-manifold and either

(a) $m \ge 2n+1 \ge 5$ or

(b) $N$ has non-empty boundary and $m\geq 2n$.

Then any two embeddings of $N$ into $\mathbb R^m$ are isotopic.

Lemma 3.1. [Wall1966] Assume that $N$ is a closed connected $n$-manifold. Then $N_0$ have handle decomposition with indices of attaching maps at most $n-1$.

Lemma 3.2. Assume that $U$ is a compact $n$-manifold, $\phi:\partial D^i\times D^{n-i}\to \partial U$ is an embedding with $i\leq n-1$, and $f:U \to \mathbb R^{m}$ is an embedding.

$(a)$ If $m=2n-1$, then there is an extension of $f$ to an embedding of $U\cup_{\phi} D^i\times D^{n-i}$.

$(b)$ Assume also that there is an embedding $g : D^i\times 0 \to \mathbb R^m$ such that $f\phi = g$ on $\partial D^i \times 0$. Suppose that on $g(D^i\times 0)$ there is a field of $n-i$ linear independed normal vectors whose restriction to $f(\partial D^i\times 0)$ is tangent to $f(U)$. Then $f\cup g$ extends to a embedding $U \cup_{\phi} D^i\times D^{n-i} \to\ \mathbb R^m$.

Denote by $A$ the $(n-i)\times n$ matrix whose rightmost $(n-i)\times (n-i)$ block is the identity matrix, and whose other elements are zeros. Denote by $v$ the field of $n-i$ normal vectors on $\partial D^i\times 0\subset D^i\times D^{n-i}$ such that the $k$-th vector has coordinates equal to the $k$-th row in $A$. Then the vector field $d\phi (v)= (d\phi (v_1),\ldots , d\phi (v_{n-i}))$ is tangent to $\partial U$. For $x\in g_1(\partial D^i\times 0)$ denote by $v'(x)$ the projection of $df(d\phi(v(x)))$ to the intersection of normal space to $g_1(\partial D^i\times 0)$ at $x$, and tangent space to $f(\partial U)$ at $x$. Since $i-1<2n-1 - (n-i)$, it follows that $\pi_{i-1}(V_{2n-1, n-i})=0$. Hence there is an extension of $v'$ to an linearly independent field of vectors normal to $g_1(D^i\times 0)$. Then by Lemma 3.2.(b) there is an extension of $f\cup g_1$ to an embedding of $U \cup_{\phi} D^i\times D^{n-i}$.

$\square$

Lemma 3.3. Assume that $U$ is a compact $n$-manifold, $\phi:\partial D^i\times D^{n-i}\to \partial U$ is an embedding with $i\leq n-1$, $f_0, f_1: U\cup_{\phi} D^i\times D^{n-i}\to \mathbb{R}^m$ are embeddings and $F:U\times [0, 1]\to \mathbb{R}^m\times [0, 1]$ is a concordance between $f_0|_U$ and $f_1|_U$.

$(a)$ If $m\geq 2n$, then there is an extension of $F$ to a concordance between $f_0$ and $f_1$.

$$\displaystyle F(U\times [0, 1])\quad\text{to}\quad f_0(D^i\times D^{n-i})\times 0,\quad\text{and to}\quad f_1(D^i\times D^{n-i})\times 1,$$

$$\displaystyle \bar{\phi}:\partial (D^i\times [0, 1])\times D^{n-i}\to \partial U\times[0, 1]\cup_{\phi\times 0} D^i\times D^{n-i}\times 0 \cup_{\phi\times 1} D^i\times D^{n-i}\times 1$$

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$$\displaystyle \dim(D^i\times 0\times [0, 1]) + \dim (U\times [0, 1])\leq (i+1)+(n+1)\quad\text{and}\quad 2\dim(D^i\times 0\times [0, 1])+1\leq 2n+1\leq m+1,$$

$$\displaystyle G: D^i\times 0\times [0, 1]\to \mathbb R^m\times [0, 1]$$

Denote by $A$ the $(n-i)\times (n+1)$ matrix whose rightmost $(n-i)\times (n-i)$ submatrix is the identity matrix, and whose other elements are zeroes. Denote by $v$ the field of $n-i$ normal vectors on $\partial (D^i\times 0\times [0, 1])\subset D^i\times D^{n-i}\times [0, 1]$ whose $k$-th vector has coordinates equal to the $k$-th row in $A$. Then $d\bar{\phi} (v)= (d\bar{\phi} (v_1),\ldots , d\bar{\phi} (v_{n-i}))$ is the vector field tangent to $\bar{\phi}(\partial (D^i\times [0, 1])\times D^{n-i})$. For $x\in G_1(\partial (D^i\times 0\times [0, 1])$ denote by $v'(x)$ the projection of $d(F\cup f_0\cup f_1)d\phi (v(x))$ to the intersection of normal space to $G_1(D^i\times 0\times [0, 1])$ at $x$, and tangent space to $F(\partial(U\times [0, 1]))$ at $x$. Since $i<m+1-(n-i)$, it follows that $\pi_{i}(V_{m+1, n-i})=0$. Hence there is an extension of $v'$ to a linear independent field of vectors normal to $G_1(D^i\times 0\times [0, 1])$. Then by Lemma 3.3.(b) there is an extension of $F\cup G_1$ to a concordance $(U \cup_{\phi} D^i\times D^{n-i})\times [0, 1]$.

$\square$

Example 4.1. Let $N=S^k\times [0, 1]$ be the cylinder over $S^k$.

(a) Then there exist non-isotopic embeddings of $N$ into $\mathbb R^{2k+1}$.

(b) Then for each $a\in\mathbb Z$ there exist an embedding $f\colon N\to\mathbb R^{2k+1}$ such that $\mathrm{lk}(f(S^k\times 0), f(S^k\times 1))=a$.

(c) Then $l\colon \mathrm{Emb}^{2k+1}N\to\mathbb Z$ defined by the formula $l([f]) = \mathrm{lk}(f(S^k\times 0), f(S^k\times 1))$ is well-defined and is a bijection for $k\geqslant2$.

Proof. Proof of part (b). Informally speaking by twisting a ribbon one can obtain arbitrary value of linking coefficient. Let $h\colon S^k\to S^k$ be a map of degree $a$. (To prove part (a) it is sufficient to take as $h$ the identity map of $S^k$ as a map of degree one and the constant map as a map of degree zero.) Define $g\colon S^k\times [0, 1] \to D^{k+1}\times S^k$ by the formula $g(x, t) = (x, h(x)t)$.

Let $f=\mathrm i\circ g$, where $\mathrm i = \mathrm i_{2k+1, k}\colon D^{k+1}\times S^k \to \mathbb R^{2k+1}$ is the standard embedding.Thus $\mathrm{lk}(f(S^k\times0), f(S^k\times1)) = a$.

Proof of part (c). Clearly $l$ is well-defined. By (b) $l$ is surjective. Now take any two embeddings $f_1, f_2$ such that $l([f_1]) = l([f_2])$. Each embedding of a cylinder gives an embedding of a sphere with a normal field. Moreover, isotopic embeddings of cylinders gives isotopic embeddings of spheres with normal fields.

$\square$

Example 4.2. Let $N=S^k\times S^1$. Assume $k>2$. Then there exists a bijection $l\colon\mathrm{Emb}^{2k+1}N_0\to\mathbb Z$ defined by the formula $l([f])=\mathrm{lk}(S^k\times1_1, S^k\times-1_1)$.

Example 4.3. Let $N=S^k_a\times S^1 \# S^k_b\times S^1$ be the connected sum of two tori. Then there exists a surjection $l\colon\mathrm{Emb}^{2k+1}N_0\to\mathbb Z$ defined by the formula $l([f])=\mathrm{lk}(f(S^k_a\times1_1), f(S^k_b\times1_1))$.

Example 4.4. (a) Let $N_0$ be the punctured 2-torus containing the meridian $x$ and the parallel $y$ of the torus. For each embedding $f\colon N_0\to\mathbb R^3$ denote by $s$ the normal field of $\epsilon$-length vectors to $f(N_0)$ defined by orientation on $N_0$ (see figure (b)). Then there exists a surjection $l\colon\mathrm{Emb}^3 N_0\to\mathbb Z$ defined by the formula $l([f])=\mathrm{lk}(f(x), s(y))$.

(b) Let $f_1,f_2\colon N_0\to\R^3$ be two embeddings shown on figure (a). Figure (c) shows that $l(f_1)=1$ and $l(f_2)=0$ which proves the intuitive fact that $f_1$ and $f_2$ are not isotopic. (Notice that the restrictions of $f_1$ and $f_2$ on $x\cup y$ are isotopic!) If we use the opposite normal vector field $s'=-s$, the values of $l(f_1)$ and $l(f_2)$ will change but will still be different (see figure (d)).

Lemma 5.1. There exists a nowhere vanishing normal vector field to $f(N_0)$.

Lemma 5.2 ($L$ is well-defined). The integer $L(f)(x, y)$: