Long-period (LP) events, which are observed commonly in shallow parts at active volcanoes, are interpreted as the oscillations of a fluid-filled crack. Their waveforms are characterized by clear damped oscillations with the oscillation frequency (f), quality factor (Q), and seismic moment (M₀), which depend on source properties of the crack. The observed values of f, Q, and M₀ often show temporal variations. Taguchi et al. (2018) suggested that LP events at Kusatsu-Shirane volcano were generated by resonances of a crack filled with misty gas, which were triggered by volumetric changes associated with water condensation from vapor derived from magma degassing. Temporal variations in f, Q, and M₀ may be related to magma degassing, but its relation remains unknown. To clarify this relation, we developed an efficient method to estimate M₀, which has not been systematically determined in previous studies, and estimated the mass of vapor intruded into the crack from f, Q, and M₀. We analyzed 202 LP events observed in 1990−1993 at Kusatsu-Shirane volcano, and investigated the LP source processes related to magmatic degassing at this volcano.
We used f and Q values of the lowest frequency peaks in the individual LP waveforms. We performed inversion using mean amplitudes of LP waveforms band-pass filtered around the lowest peaks to estimate M₀ values of the individual events. Although full-waveform inversion was only applicable to low-frequency waveforms up to around 1 Hz due to the difficulty to fit waveforms including phases, which are more strongly affected by heterogenous structures than amplitudes, our inversion approach provided stable results using high-frequency waveforms up to 6 Hz. Furthermore, we developed a new method to estimate crack size and acoustic properties of misty gas in the crack from f, Q, and M₀ by using the analytical and empirical formulas for f (Maeda and Kumagai, 2017) and Q (Taguchi et al., 2021) of crack resonances, respectively, under the assumption that crack length L is proportional to aperture d and its change Δd. We then estimated the mass of H₂O of misty gas (m_H2O) in the crack for the individual LP events.
We found that f ^-1 was positively correlated with m_H2O. If vapor intruded into the crack was derived from magmatic degassing, m_H2O is proportional to the mass of degassed magma. The observed temporal variations in f in 1990−1993 were divided into two phases: short-term fluctuations in 1990 and systematic decreasing and increasing trends in 1991 and 1992−1993. Based on our estimated relation of f to m_H2O, we interpreted magma degassing in these periods as follows. In 1991 and 1992−1993, the degassed magma gradually increased and decreased, but it rapidly fluctuated in 1990, suggesting that magma supply style was different in these periods. In this way, we can infer magma activity from observed temporal variations in f of LP events, which can be easily determined by spectral analysis compared to Q and M₀. Although there was no eruption in 1990−1993, provision of larger amount of vapor into the crack may have led to a phreatic eruption. To monitor f of LP events is thus useful to infer magmatic activity and to assess the risk of eruptions.