Eubliastes spp

4.2. Acoustics of Eubliastes spp .

The song of E. viridicorpus is classic for members of the Cocconotini , showing discrete pure tone pulses with a similar envelope structure to other pseudophyllines ( Baker et al., 2019; Stumpner et al., 2013) peaks at 23.4 kHz and is most similar to that of E. aethiops , which is also comprised of two syllables at a similar peak frequency (23.9 kHz, Fig. A1 View Fig ). However in E. aethiops the frequency spectrum has a wider bandwidth of 11.9 kHz (20 dB below the peak) compared to 2.2 kHz in E. viridicorpus , and does not show the additional frequency component towards 12 kHz as seen in E. viridicorpus . This song peak frequency range seems to be characteristic of the genus with E. chlorodictyon and E. pollonerae singing at and 25.4 and 25.5 kHz respectively ( Figs. A2 View Fig ,A 3 View Fig ; Montealegre-Z and Morris, 1999; ter Hofstede et al., 2020).The same could be said of the two syllable temporal pattern of the song, but more recordings of other extant species (acoustic data is currently only available for four species) would be beneficial for future comparisons. The song of E. viridicorpus is also interesting in that the high amplitude component is at the start of each syllable rather than the end. This is similar to the song structure of E. chlorodictyon ( Montealegre-Z and Morris, 1999), but differs from E. aethiops ( Fig. A1 View Fig ) and E. pollonerae ( ter Hofstede et al., 2020) . This difference is not due to differences in stridulatory file anatomy, but instead indicates that the pattern of wing motion during stridulation differs, as the loudest component of the signal is produced during wing closure (Montealegre-Z., 2005; Montealegre-Z et al., 2006; Nielsen and Dreisig, 1970). Although tremulation was observed in the field, we were not able to record tremulatory signals in the laboratory. We hypothesise that E. viridicorpus utilises wing velocity to generate the lower peak of the song spectrum, but with a mirror tuned to the higher frequency peak of the spectrum (the first order harmonic) to optimise energy use.