Time-lag between disk and corona radiation leads to hysteresis effect observed in black-hole X-ray binary MAXI J1348-630

Accretion is an essential physical process in black-hole X-ray binaries (BHXRBs) and active galactic nuclei. The properties of accretion flows and their radiation are generally considered to be uniquely determined by the mass accretion rate of the disk; however, the "hysteresis effect" observed during outbursts of nearly all BHXRBs seriously challenges this paradigm. The hysteresis effect is referred to that apparently similar spectral state transitions take place at very different luminosities during an outburst cycle. Phenomenologically, this effect is also represented as the so-called "q"-shaped hardness-intensity diagram (HID), which has been proposed as a unified scene for BHXRBs. However, even with the high cadence pointing observations, the distinctly important rapid-rise stage has been caught to date in only a few BHXRB outbursts, and it is still limited to narrow energy/wavelength bands. As a result, there is still lack of a quantitative theoretical interpretation and observational understanding on the "q"-diagram. Here, we present a detailed time-lag analysis on Insight-HXMT's intensive monitoring data of a newly found BHXRB, MAXI J1348-630, over a broad energy band (1--150 keV). We find the first observational evidence that the observed time-lag between radiations of the accretion disk and the corona leads naturally to the hysteresis effect and the "q"-diagram. Moreover, complemented by the quasi-simultaneous Swift data, we achieve a panorama of the accretion flow: the hard X-rays from the corona heat the outer disk and induce the corresponding optical brightening; thereafter, the enhanced accretion rate in the outer disk propagates inwards to the vicinity of the central black-hole, generating the soft X-rays in the inner disk region, at a viscous timescale of $\sim 8-12$ days.