Fireball characteristics derivable from acoustic data

TL;DR

This paper introduces BAM, a computer code that estimates fireball trajectories and energetics from acoustic data, including a new method for measuring fragmentation energy, with application to the Stubenberg fireball.

Contribution

The paper presents a novel integrated approach and software for deriving fireball characteristics and energetics solely from acoustic measurements, including fragmentation energy estimation.

Findings

Estimated fireball energy: ~5×10^{10}J from acoustic data, aligning with optical estimates.

Fragmentation energy: approximately one third of total energy, derived from acoustic signals.

Velocity measurement from acoustic data alone is challenging but feasible for certain fireballs.

Abstract

Near field acoustical signals from fireballs (ranges<200 km), when detected by dense ground networks, may be used to estimate the orientation of the trajectory of a fireball (Pujol et al., 2005) as well as fragmentation locations (Kalenda et al., 2014; Edwards and Hildebrand, 2004). Distinguishing ballistic arrivals (from the cylindrical shock of the fireball)from fragmentation generated signals (quasi-spherical sources) remains a challenge, but are obtainable through analysis of the acoustic path and the timing observed at ground instruments. Here we describe an integrated computer code, termed the Bolide Acoustic Modelling program or BAM, to estimate fireball trajectories and energetics. We develop a new methodology for measuring energy release from bolide fragmentation episodes solely from acoustic measurements and incorporate this into BAM. We also explore the sensitivity of seismo-acoustic fireball solutions and energy estimates to uncertainty in the underlying atmospheric model. Applying BAM to the Stubenberg meteorite producing fireball, we find the total fireball energy from ballistic arrivals to be approximately $5 \times 10^{10}$J which compares favorably to the optical estimate of $4.36 \times 10^{10}$J. The combined fragmentation energy of the Stubenberg event from acoustic data was found to be $1.47^{+0.28}_{-0.12} \times 10^{10}$J, roughly one third of the ballistic or optical total energy. We also show that measuring fireball velocities from acoustic data alone is very challenging but may be possible for slow, deeply penetrating fireballs with shallow entry angles occurring over dense seismic/infrasound networks.