In this thesis, we focus on the investigation of fundamentals in complex oxide (metal ferrite) regarding the growth behaviors and correlation between structure and physical properties. There are three parts as discussed below. One is the investigation of growth behavior of spinel magnetite with dendritic architecture in solution and corresponding phase transition during the formation procedure. The second part is the study of phase transition and corresponding pyroeleteic response with thermal stimuli in strained BiFeO3 thin film; the third part is the study of phase transition with electrical stimuli and the correlated potential multilevel ferroelctric resistive switching in BiFeO3 with MPBs features. In first part, dendritic mineral growth, recognized as a paradigm of non-equilibrium process, is commonly found in nature, but fundamental understanding of branching kinetics and formation mechanism is still limited due to the lack of real-time imaging capability during growth. Here, by using in situ transmission electron microscopy (TEM), we study the nucleation and growth of dendritic magnetite nanostructures from solution. Growth kinetics of magnetite, from particle to dendrite, show the reaction like limited kinetics model along with distinct fractal dimensions, in contrast with classical model. Overall tip splitting kinetics are determined by the competition between the adjacent branches to the precursors with Turing-like instability mechanism. We also demonstrate the coexistence of direct and indirect crystallization pathways, as explained through the thermodynamic consideration. Our findings provide new insights into the understanding of dendritic magnetite branching and crystallization mechanism, which we believe is applicable to general mineral dendrite systems in nature. In second part, great attention is paid to that stimulus response of materials, which is a prerequisite for energy harvesting applications. Driven by advances in nanotechnology, the atomic motions, involved in phase transitions and associated with stimulus responses, require detailed investigation on the nanoscale. Recently, strain engineering of BiFeO3 has become the subject of broad research interest due to its promising potential in energy conversion applications, such as piezoelectric, pyroelectric and shape memory effect (SME) devices. In this study, an excellent pyroelectric response is associated with reversible phase transitions in mixed-phase BiFeO3 films using thermal stimuli. Using an in situ high-resolution (HRTEM), we observed that phase transition between rhombohedral-like (R-like) and tetragonal-like (T-like) BiFeO3 involved the migration of the phase boundary, which is a prerequisite for the growth of the T-like phase and requires an intermediate phase. Moreover, the origin of the phase transition is attributed to competition between thermodynamic stability and substrate-induced strain, as suggested by phase-field simulations. The results provide a fundamental understanding of the atomic processes that underlie the stimulus response of the strained BiFeO3 films and demonstrate the potential of this extraordinary material for novel energy harvesting applications. In third part, recent quest for non-volatile memories has attracted tremendous attention, especially in mature ferroelectric random access memory (FeRAM) with properties of high read/write speed and low power consumption. Despite its promise, some scientific issues are still encountered. Strain engineering of BiFeO3 has recently become the subject of broad research interest because of its intriguing properties. In this study, we demonstrate the switchable diode characteristics in highly strained BFO thin films. Using a unique in situ TEM, we verify the correlation between ferroelectric resistive switching with possible multilevel states and polarization reversal. Structural investigation confirms the phase transition from mixed phase to pure T-like phase by external bias, which is the origin of the multilevel states. The switchable diode with resistive switching can be explained in terms of the variation of the barrier height, controlled by ferroelectric polarization and polarity of the external bias. This research model, i.e., engineering of the room inside, may offer an approach toward high-density memories.