Abstract
Imaging with ultrashort exposure times is generally achieved with a crossed-beam geometry. In the usual arrangement, an off-axis gating pulse induces birefringence in a medium exhibiting a strong Kerr response (commonly carbon disulfide) which is followed by a polarizer aligned to fully attenuate the on-axis imaging beam. By properly timing the gate pulse, imaging light experiences a polarization change allowing time-dependent transmission through the polarizer to form an ultrashort image. The crossed-beam system is effective in generating short gate times, however, signal transmission through the system is complicated by the crossing angle of the gate and imaging beams. This work presents a robust ultrafast time-gated imaging scheme based on a combination of type-I frequency doubling and a collinear optical arrangement in carbon disulfide. We discuss spatial effects arising from crossed-beam Kerr gating, and examine the imaging spatial resolution and transmission timing affected by collinear activation of the Kerr medium, which eliminates crossing angle spatial effects and produces gate times on the order of 1 ps. In addition, the collinear, two-color system is applied to image structure in an optical fiber and a gasoline fuel spray, in order to demonstrate image formation utilizing ballistic or refracted light, selected on the basis of its transmission time.
Highlights
The non-intrusive nature of optical diagnostics make them essential tools for the study of physical systems, which are often perturbed
Imaging with ultrashort exposure times is generally achieved with a crossed-beam geometry
An off-axis gating pulse induces birefringence in a medium exhibiting a strong Kerr response which is followed by a polarizer aligned to fully attenuate the on-axis imaging beam
Summary
The non-intrusive nature of optical diagnostics make them essential tools for the study of physical systems, which are often perturbed. Informative optical diagnostics in such media require detailed understanding of the light source, propagation and scattering in the measurement volume, and a detection arrangement tailored to select the meaningful parts of the transmitted light signal. To this end, ultrafast time-gating can provide an effective means of segregating high integrity portions of the collected signal from light disturbed by scattering interactions. Time gating (timebased filtering) allows selection of the optical signal within a short temporal window and can be applied to separate the light that is scrambled due to multiple interactions from the optical signal that retains high-fidelity information of the object characteristics [5].
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