Semiconductor Today published research progress of SEU team

The DBHT material was grown on 3-inch InP substrate using molecular beam epitaxy (MBE) – see Figure 1. The material was fabricated into single-finger DHBTs, using a 0.5μm process. Wet etching was used to define three stacked mesas for the DHBT, using self-aligned techniques to define the base contact. The emitter/collector metals were titanium/platinum/gold, and the base was platinum/titanium/platinum/gold. Further steps included device isolation, planarization/passivation with benzocyclobutene, reactive-ion etch to expose metal terminal posts, and pad deposition.

The transfer to flexible substrate involved temporary adhesion to sapphire carrier to enable removal/thinning of the InP substrate using mechanical lapping, followed by selective wet etching with a solution based on hydrochloric acid. The indium gallium arsenide (InGaAs) stop layer was removed with a solution based onorthophosphoric acid. The 2μm-thick device was then permanently bonded to the flexible substrate, and the sapphire carrier was removed.

DC measurements showed some degradation in performance in terms of collector current relative to devices not transferred to flexible substrates. The researchers attribute the degradation to poor thermal conductivity of the flexible substrate, about a factor of three lower than for InP. Self-heating can severely impact transistor performance. The maximum gain of 31 was only slightly impaired relative to the non-flexible devices.

The frequency performance was measured up to 40GHz. A conventional DHBT achieved an extrapolated fT of 385GHZ with an fMAX of 570GHz. The DHBT on flexible substrate registered an fT of 337GHz and an fMAX of 485GHz. The researcher compared their work with other reports (Figure 2).

The process yield was around 73%, with most failed devices being on the periphery of the wafer (Figure 3). The failure was attributed to local defects. The frequency performance of the resulting devices varied only slightly.