Cryogenic fiber-coupled electro-optic characterization platform for high-speed photodiodes

TL;DR

This paper introduces a cryogenic fiber-coupled platform for ultrafast photodiode characterization, enabling high-frequency response analysis at various temperatures, crucial for quantum technology applications.

Contribution

The development of a fully fiber-coupled, cryogenic-compatible electro-optic sampling system for ultrafast photodiodes with high temporal and frequency resolution.

Findings

Characterized photodiodes up to 250 GHz frequency response.

Demonstrated temperature-dependent changes in ultrafast response.

System operates effectively across a wide temperature range, including 4 K.

Abstract

We have developed a cryogenic characterization platform for ultrafast photodiodes, whose time domain responses are extracted by electro-optic sampling using femtosecond laser pulses in a pump-probe configuration. The excitation of the photodiodes with the pump beam and the electro-optic sampling crystals with the probe beam are realized in a fully fiber-coupled manner. This allows us to place the characterization platform in almost any temperature environment. As application example, we characterize the time-domain response of commercial p-i-n photodiodes with a nominal bandwidth of 20 GHz and 60 GHz at temperatures of 4 K and 300 K and in a large parameter range of photocurrent and reverse bias. For these photodiodes, we detect frequency components up to approximately 250 GHz, while the theoretical bandwidth of our sampling method exceeds 1 THz. Our measurements demonstrate a significant excitation power and temperature dependence of the photodiodes' ultrafast time responses, reflecting, most likely, changes in carrier mobilities and electric field screening. Since our system is an ideal tool to characterize and optimize the response of fast photodiodes at cryogenic temperatures, it has direct impact on applications in superconducting quantum technology such as the enhancement of optical links to superconducting qubits and quantum-accurate waveform generators.