Abstract

Context. The two giant protoplanets directly detected in the dust-depleted cavity of PDS 70 offer a unique opportunity to study the processes of ongoing planet formation. The planets have been detected both in IR thermal light and in the H? line, indicating that they are actively accreting material from their surroundings. Aims. We calibrated and analysed archival Atacama Large Millimeter/subMillimeter Array (ALMA) band 6 and 7 observations of PDS 70 to detect circumplanetary material in independent datasets taken at different epochs in 2019, 2021, and 2023 and assess its possible motion. Methods. We performed 2D visibility modelling of the high-resolution ALMA band 6 (~0.11"× 0.08") and band 7 (~0.05"× 0.05") dust continuum emission of the outer disc. After subtracting the model from the data, we imaged the dust continuum emission in the cavity of PDS 70 at multiple epochs. Results. We re-detect the compact dust emission around PDS 70 c in all our datasets in band 6 and 7, with a more than 3.8? significance, and tentatively detect compact emission around PDS 70 b at ~3? in the band 6 datasets, with a peak emission of 59 ± 17 ?Jy/beam and 46 ± 14 ?Jy/beam. We find the astrometric relative position of the compact emission around PDS 70 c to be consistent with the expected position of the planet in the 2019-2023 time range. We measure a peak flux difference of up to 64 ± 34 ?Jy/beam at a 1? confidence level for the continuum emission coming from the region around PDS 70 c and perform a Bayesian test on our measurements, finding that they are not consistent with significant variable emission. We find no evidence of flux variability in the inner disc. We measure the dust mass of the material co-located with PDS 70 c and the inner disc to be in the range of 0.008-0.063 M? and 0.04-0.31 M?, respectively, consistent with previous measurements. Additionally, we obtain band 6-7 spectral indices of 2.5 ± 1.2 and 3.2 ± 0.5 for the dust emission around PDS 70 c and in the inner disc, respectively, suggesting the inner disc emission is dominated by optically thin dust. © The Authors 2025.