Basic properties as well as applications in physics research of broad-area VCSELs from below to far above threshold are thoroughly investigated. Firstly, the high-resolution measurement demonstrates that over a thousand cavity modes with a narrow linewidth can be perfectly exhibited in the subthreshold emission spectra. Further analyses of the obtained spectra confirm that the subthreshold emission spectra of broad-area VCSELs can be exploited to analogously investigate the energy spectra of the 2D quantum billiards. In addition, due the analogy between Helmholtz equation and time-independent Schrödinger equation, transverse wave patterns of oxide-confined VCSELs enable us to visualize the wave functions of the 2D quantum billiards with the same lateral shapes. Therefore, typical lasing modes for VCSELs with various cavity shapes are explored. Furthermore, since paraxial wave equation and time-dependent Schrödinger equation are highly equivalent in mathematics, free space propagation of lasing modes for VCSELs can be use to analogously study diffraction in time effect which is one of the most relevant quantum transient phenomena in matter waves. Mode selection mechanism for stadium-shaped VCSELs is also experimentally studied. We then perform statistical analysis to quantitatively understand characteristics of experimental chaotic and scarred wave patterns. Finally, polarization dynamics of broad-area VCSELs far above threshold are considered. Experimental results reveal that cavity geometry plays a significant role for polarization stability of the lasing mode that has large frequency detuning.