Groupoid isomorphism vs. group isomorphism

Assume that $\Gamma$ is a group with neutral element $e$. We associate to $\Gamma$ the following groupoid $G$:

$G=\Gamma \times \Gamma,\;\;\;G^{(0)}=\Gamma \times \{0\},\;\;s(a,b)=(a,e),\;\;\; r(a,b)=(ba, e)$

If $\phi:\Gamma_{1}\to \Gamma_{2}$ is a group isomorphism, then $\tilde{\phi}:G_{1} \to G_{2}$ with $\tilde{\phi}(a,b)=(\phi(a), \phi(b))$ is a groupoid isomorphism. So isomorphism groups give us isomorphic groupoids. Now we ask the converse:

Are there two non isomorphic groups $\Gamma_{1}, \Gamma_{2}$ such that the corresponding groupoids $G_{1}, G_{2}$ are isomorphic.

Note that a groupoid isomorphism between $G_{1}, G_{2}$ does not necessarily come from a group isomorphism between $\Gamma_{1}, \Gamma_{2}$, as constructed above. An easy example can be provided by $\Gamma_{1}=\Gamma_{2}=\mathbb{Z}/2\mathbb{Z}$.

This situation is a motivation for the above question.

• Your groupoid is the action groupoid of $G$ acting on itself by left multiplication, and accordingly it is contractible: that is, it's equivalent to the terminal groupoid $1$. (Do you really want to ask for an isomorphism rather than an equivalence of groupoids? It's not a particularly natural condition.) – Qiaochu Yuan Jan 22 '16 at 19:04
• @QiaochuYuan yes I mean "isomorphism between groupoids". – Ali Taghavi Jan 22 '16 at 19:06

Look at the group $Aut(x)$ where $x$ is an object of the groupoid. You find that this group is trivial. Therefore your groupoid is THE groupoid with trivial automorphism groups and its isomorphy class only depends on the cardinality of the set of objects. Hence any two groups of the same cardinality will give isomorphic groupoids
• Than you for your answer.I do not understand why such groupoid has no non identity automorphism. For example put $\Gamma=\mathbb{Z}/2\mathbb{Z}$ then $G=\Gamma \times \Gamma$ has non identity automorphism $\phi(0,0)=(1,0),\;\phi(1,0)=(0,0), \phi(1,1)=(0,1),\; \phi(0.1)=(1,1)$. Am I missing some thing? – Ali Taghavi Jan 22 '16 at 19:53
• What Anton means is the set of automorphisms of a single object in your groupoid. This will always be a group, for trivial reasons. In a given connected component all objects have isomorphic automorphism groups (again for trivial reasons). Furthermore, the $hom(x,y)$ sets for distinct $x,y$ in a connected components are $Aut(x)$-torsors, i.e. copies of $Aut(x)$ without a distinct identity element. Since the action groupoid of a group acting on itself is connected and has trivial $Aut(x)$, the groupoid is completely determined up to isomorphism by its cardinality. – Georg Lehner Jan 22 '16 at 22:03