In situ coherent diffractive imaging

Coherent diffractive imaging (CDI) has been widely applied in the physical and biological sciences using synchrotron radiation, X-ray free electron lasers, high harmonic generation, electrons and optical lasers. However, although a limited number of dynamic studies have been reported, most CDI experiments have been focused on static systems. Here, we report the development of a general in situ CDI method for real time imaging of dynamic processes in solution. By introducing a time-invariant overlapping region as a powerful real-space constraint, we show that in situ CDI can simultaneously reconstruct a time series of complex exit waves of dynamic processes with robust and fast convergence. We demonstrate the method's validity with numerical simulations and by performing proof-of-principle experiments on materials science and biological samples. Using advanced synchrotron radiation and high harmonic generation, we expect in situ CDI can be broadly applied to probe dynamic phenomena at high spatiotemporal resolution, ranging from electrochemistry, phase transitions, charge transfer, transport, nucleation, melting and fluid dynamics to live cell imaging.