In a dense star cluster core, a tidal disruption event (TDE) of a white dwarf (WD) can occur if the WD passes within the tidal radius of an intermediate-mass black hole (IMBH). Very close encounters cause extreme tidal compression in the WD, raising temperatures enough to induce runaway fusion and produce a thermonuclear supernova (SN). Using the hydrodynamics code augmented with a 55-isotope nuclear reaction network, we performed high-resolution simulations of the TDE of a 0.6 C/O WD by a 500 IMBH for different values of the scaled impact parameter b (i.e., the ratio of periapsis distance to tidal radius). Closer encounters produce combined TDE+SN events, with a partial burning of ţwelve and into heavier isotopes -- the ∋fs fractions of the disrupted WD material vary from 1% at b = 0.19 to 82% at b = 0.10, while wider ones (b ≳ 0.20) lead to standard TDEs. In all cases, the material away from the denser regions remains unburnt, spanning a wide range of radial velocities. Such WD TDEs also exhibit a central cavity, wherein little material is found below a radial velocity of several 1000 ̨msinv. We also performed 1D and 2D radiative-transfer calculations for these WD-TDEs using the codes ̧mfgen and łongpol, respectively, covering epochs from a few days to one hundred days. We recover the typical rise times and peak luminosities of SNe Ia, but with an extremely strong viewing-angle dependence of both light curves and spectra. At nebular times, isolated strong emission lines such as ̧aiidoub may appear both displaced and skewed by many 1000 ̨msinv -- such extreme offsets are harder to identify at earlier times due to optical depth effects and line overlap. WD TDEs may produce a diverse set of transients with extreme asymmetry and peculiar composition.
Vynatheya et al. (Fri,) studied this question.