This project focuses on the study of qualitative reconstruction methods for nondestructive testing in thin elastic plates. Nondestructive testing is ubiquitous in engineering applications and medical imaging, and scattering in thin elastic plates has significant applications in the area of detecting geomagnetic anomalies and medical imaging of the brain. In recent years, qualitative reconstruction methods have been shown to provide quick and accurate reconstructions when applied to acoustic and electromagnetic scattering. Therefore, the primary goal of this project is to study the applicability of these methods to the thin elastic plate model. This would allow for computationally simple yet analytically rigorous algorithms for recovering defects in thin elastic materials. This project will also involve the training of graduate students who will contribute to this project. The proposed research has two main components. The first component aims to study the direct and inverse scattering problems of a thin elastic plate. This is given by a biharmonic wave equation that is derived from the Kirchhoff-Love infinite plate problem in an infinite domain, which will be studied in the frequency domain. Questions such as the well-posedness of many direct scattering problems will be addressed and well-known qualitative reconstruction methods, such as the linear sampling and factorization methods, will be applied to these scattering problems. These methods are advantageous for shape re