Efficient free-space to on-chip coupling of THz-bandwidth pulses for biomolecule fingerprint sensing

Wide bandwidth THz pulses can be used to record the distinctive spectral fingerprints related to the vibrational or rotational modes of polycrystalline biomolecules, and can be used to resolve the time-dependent dynamics of such systems. Waveguides, owing to their tight spatial confinement of the electromagnetic fields and the longer interaction distance, are promising platforms with which to study small volumes of such systems. The efficient input of sub-ps THz pulses into waveguides is challenging owing to the wide bandwidth of the THz signal. Here, we propose a sensing chip comprised of a pair of back-to-back Vivaldi antennas feeding into, and out from, a 90 degrees bent slotline waveguide to overcome this problem. The effective operating bandwidth of the sensing chip ranges from 0.2 to 1.15 THz, and the free-space to on-chip coupling efficiency is as high as 51% at 0.44 THz. Over the entire band, the THz signal is similar to 42 dB above the noise level at room temperature, with a peak of similar to 73 dB above the noise. In order to demonstrate the use of the chip, we have measured the characteristic fingerprint of a-lactose monohydrate, and its sharp absorption peak at similar to 0.53 THz was successfully observed, demonstrating the promise of our technique. The chip has the merits of efficient in-plane coupling, ultra-wide bandwidth, ease-of-integration, and simple fabrication. It has the potential for large-scale manufacture, and can be a strong candidate for integration into other THz light-matter interaction platforms.

Automated summary

The study proposes a new sensing chip that overcomes the challenge of efficiently coupling wide bandwidth THz signals into waveguides. The chip, comprised of a pair of back-to-back Vivaldi antennas and a 90 degrees bent slotline waveguide, offers efficient in-plane coupling, ultra-wide bandwidth, ease-of-integration, and simple fabrication.