Drake, Jeremy J.Ness, Jan-UwePage, Kim L.Luna, G. J. M.Beardmore, Andrew P.Orio, MarinaOsborne, Julian P.2023-10-192023-10-1920212041-82052041-8213https://doi.org/10.3847/2041-8213/ac34fdhttps://hdl.handle.net/20.500.12469/5295Nova Her 2021 (V1674 Her), which erupted on 2021 June 12, reached naked-eye brightness and has been detected from radio to gamma-rays. An extremely fast optical decline of 2 magnitudes in 1.2 days and strong Ne lines imply a high-mass white dwarf. The optical pre-outburst detection of a 501.42 s oscillation suggests a magnetic white dwarf. This is the first time that an oscillation of this magnitude has been detected in a classical nova prior to outburst. We report X-ray outburst observations from Swift and Chandra that uniquely show (1) a very strong modulation of supersoft X-rays at a different period from reported optical periods, (2) strong pulse profile variations and the possible presence of period variations of the order of 0.1-0.3 s, and (3) rich grating spectra that vary with modulation phase and show P Cygni-type emission lines with two dominant blueshifted absorption components at similar to 3000 and 9000 km s(-1) indicating expansion velocities up to 11,000 km s(-1). X-ray oscillations most likely arise from inhomogeneous photospheric emission related to the magnetic field. Period differences between reported pre- and post-outburst optical observations, if not due to other period drift mechanisms, suggest a large ejected mass for such a fast nova, in the range 2 x 10(-5)-2 x 10(-4) M (circle dot). A difference between the period found in the Chandra data and a reported contemporaneous post-outburst optical period, as well as the presence of period drifts, could be due to weakly nonrigid photospheric rotation.eninfo:eu-repo/semantics/openAccessRay Light-CurveOscillationsCarbonHotRay Light-CurveOscillationsCarbonHotArticle2922WOS:00072585940000110.3847/2041-8213/ac34fd2-s2.0-85120706970Q1Q110