Write $R(T)$ for the rank of an order-$3$ tensor $T \in \mathbb C^{m \times n \times p}$ over the complex numbers. If $T' \in \mathbb {C}^{m' \times n' \times p'}$ is another such tensor then let $T \otimes T' \in \mathbb{C}^{mm' \times nn' \times pp'}$ denote their tensor product (aka Kronecker product). It is straightforward to verify that $R(T \otimes T') \le R(T) R(T')$, and from this it follows that the sequence $R(T^k)^{1/k}$ converges to its infimum. The *asymptotic rank of $T$* is
$$\tilde R(T) = \lim_{k \to \infty} R(T^k)^{1/k} = \inf_{k \ge 1} R(T^k)^{1/k}.$$
For example, if $T = m_2$ is the structure tensor for $2 \times 2$ matrix multiplication then $\tilde R(T) = 2^\omega$ where $\omega$ is the exponent of matrix multiplication. It would therefore be putting it mildly to say that $\tilde R(T)$ is not easy to calculate.
My question is actually about the *border rank* of tensors. The literature agrees universally that this is denoted $\underline R(T)$, but seems to vary wildly on what it's actual definition is. Here are some possibilities:
1. According to some sources, including [Wikipedia][1], border rank is the minimal $r$ such that $T$ is a limit of tensors of rank at most $r$. Let's call this $\underline R^\text{naive}$. Wikipedia has a basic example of a tensor with $R(T) = 3$ but $\underline R^\text{naive}(T) = 2$.
2. That cannot possibly be the "right" definition for an arbitrary field since there is no natural topology in general. I have seen at least one source therefore define border rank to be the least $r$ such that $T$ is in the Zariski closure of the set of tensors of rank at most $r$. Call this $\underline{R}^\text{Zariski}$.
3. Most of the literature that actually carefully defines and proves things (such as the book Algebraic Complexity Theory, Chapter 15) defines border rank in terms of algebraic expressions over $\mathbb C[\epsilon]$ of the type $\epsilon^d T + O(\epsilon^{d+1}) = (\text{rank-$r$ tensor})$ for some integer $d$. Let's call this definition $\underline R^\text{original}(T)$.
Note that $\underline R^\text{Zariski} \le \underline R^\text{naive} \le \underline R^\text{original}$.
> Question 1: Are these things really different? What are good examples?
Anyway, the crucial inequality relating border rank (at least in its original definition) to asymptotic rank is $\tilde R(T) \le \underline R^\text{original}(T)$. However, it seems to be implicit in some of the more recent literature that this holds for $R^\text{naive}$ (see for example the intro to https://arxiv.org/abs/1112.6007). Is this true?
> Question 2: Is it true that $\tilde R \le \underline R^\text{naive}$?
Of course, we could ask the same question for $\underline R^\text{Zariski}$, which would be even better.
[1]: https://en.wikipedia.org/wiki/Tensor_rank_decomposition#Border_rank