While primarily recognized for its utility in peptide synthesis, Fmoc-D-3-(3-Thienyl)-Alanine (CAS 220497-90-5) is increasingly finding its niche in the innovative field of material science, particularly in the development of advanced organic electronics. The compound's structure, featuring an Fmoc-protected amino acid with a thiophene side chain, endows it with properties that are highly sought after in the creation of functional materials.

The thiophene ring is a well-established building block in organic electronics due to its π-electron-rich structure, which facilitates charge transport. When incorporated into larger molecular architectures, thiophene derivatives can form conductive polymers and small molecules suitable for applications in organic field-effect transistors (OFETs), organic photovoltaics (OPVs), and organic light-emitting diodes (OLEDs). The presence of the amino acid and Fmoc protecting group provides additional handles for functionalization and integration into supramolecular assemblies or polymer backbones, allowing for tailored material properties.

Researchers looking to explore these advanced applications require a consistent and high-purity source of Fmoc-D-3-(3-Thienyl)-Alanine. Sourcing this specialty chemical from reputable manufacturers and suppliers is crucial. The purity, typically 97% or higher, ensures predictable performance in material synthesis, minimizing defects and optimizing device efficiency. For material scientists and procurement specialists, understanding the specifications and benefits of this compound is key to successful material design.

When seeking to buy Fmoc-D-3-(3-Thienyl)-Alanine for material science applications, consider suppliers known for their commitment to quality and technical support. Many manufacturers in China offer competitive pricing and are capable of fulfilling both small research quantities and larger bulk orders. Engaging with these suppliers allows for access to essential raw materials that can drive innovation in organic electronics and beyond. The unique combination of peptide chemistry functionality and electronic properties makes Fmoc-D-3-(3-Thienyl)-Alanine a versatile molecule for cutting-edge material development.