Abstract: A method of detecting a geometrical phase change of an intrinsic property of a molecular isomerization includes a series of steps, such as simulating molecular isomerization of the molecule through application of a single shaped pulse to generate a molecular polarization. The steps include separating the real and imaginary parts of a nonlinear susceptibility in a detected molecular signal by controlling a phase of a reference field. The steps include assigning a phase function to obtain separation of the real and imaginary parts. Furthermore, a broadened vibrational lineshape is calculated. The step of identifying conical intersections also occurs. Various pathways of a wave packet in an excited state potential energy surface is discussed and may include multiple laser pulses and methods of detection. The spectral phase may be used to create interference of the wave packet in the excited state to identify and control a wavepacket's pathway and control photoisomerization.

Abstract: A method of detecting a geometrical phase change of an intrinsic property of a molecular isomerization includes a series of steps, such as simulating molecular isomerization of the molecule through application of a single shaped pulse to generate a molecular polarization. The steps include separating the real and imaginary parts of a nonlinear susceptibility in a detected molecular signal by controlling a phase of a reference field. The steps include assigning a phase function to obtain separation of the real and imaginary parts. Furthermore, a broadened vibrational lineshape is calculated. The step of identifying conical intersections also occurs. Various pathways of a wave packet in an excited state potential energy surface is discussed and may include multiple laser pulses and methods of detection. The spectral phase may be used to create interference of the wave packet in the excited state to identify and control a wavepacket's pathway and control photoisomerization.