The scaling relations and star formation laws for molecular cloud complexes (MCCs) in the Milky Way are investigated. MCCs are mostly large (R > 50 pc), massive (∼106 M⊙) gravitationally unbound cloud structures. We compare their masses Mgas, mass surface densities σ Mgas, radii R, velocity dispersions σ, star formation rates (SFRs), and SFR densities σSFR with those of structures ranging from cores, clumps, and giant molecular clouds, to MCCs, and galaxies, spanning eight orders of magnitudes in size and 13 orders of magnitudes in mass. This results in the following universal relations: σ ∼ R0.5, Mgas ∼ R2, σsfr ∼ σ1.5Mgas, SFR ∼ Mgas0.9 and SFR ∼ σ2.7. Variations in the slopes and coefficients of these relations are found at individual scales, signifying different physics acting at different scales. Additionally, there are breaks at the MCC scale in the σ-R relation and between starburst and normal star-forming objects in the SFR-Mgas and σSFR-σMgas relations. Therefore, we propose to use the Schmidt-Kennicutt diagram to distinguish starburst from normal star-forming structures by applying a σMgas threshold of ∼100 M⊙ pc-2 and a σSFR threshold of 1 M⊙ yr-1 kpc-2. Mini-starburst complexes are gravitationally unbound MCCs that have enhanced σSFR (>1 M⊙ yr-1 kpc-2), probably caused by dynamic events such as radiation pressure, colliding flows, or spiral arm gravitational instability. Because of dynamical evolution, gravitational boundedness does not play a significant role in regulating the star formation activity of MCCs, especially the mini-starburst complexes, which leads to the dynamical formation of massive stars and clusters. We emphasize the importance of understanding mini-starbursts in investigating the physics of starburst galaxies.
