A process flow for the heterogeneous integration of III-V epitaxial material onto a silicon host wafer using CMOS-compatible materials and methods toward the goal of forming electronic-photonic circuitry is presented. Epitaxial structures for compound-semiconductor-based transistors are assembled on a silicon carrier wafer using a commercially-available polymer and then formed into distinct patterns for scalable processing. A CMOS-compatible metallization process is performed on the back side collector terminal of the aligned epitaxial structures, followed by a metal-eutectic bonding process that transfers the wafer-scale array of III-V material onto a separate silicon host wafer allowing the fabrication of both electronic and photonic devices on a single wafer. Characterization of the epitaxial bonding and transfer is performed to ensure material alignment is maintained without additional tooling and that the interconnect layer established between III-V collector and silicon host wafer performs as an ohmic contact, thermal path, and mechanical bond compatible with back-end-of-line (BEOL) integrated circuit processing. These processes are shown for GaAs-based light-emitting transistor (LET) epitaxial material to demonstrate that subsequent photonic devices and systems may be patterned into the integrated material allowing a direct electrical interconnect to embedded CMOS-based electronic systems for new functionalities as electronic-photonic integrated circuitry. (C) The Author(s) 2018. Published by ECS.