Observations of the size distribution of frazil ice in an Ice Shelf Water plume

Abstract: The size distribution of frazil ice is currently unconstrained in ice shelf cavity modeling.Here we observe the time-dependent behavior of the number and size of frazil ice particles in an Ice Shelf Water plume. A novel acoustic scattering inversion was used to infer frazil ice crystal diameters, assuming a log-normal distribution. Observation sites were on land-fast sea ice approximately 13 and 33 km from the front of the McMurdo Ice Shelf, Antarctica. The water column from the ice-water interface to 30 m bel… Show more

“…In earlier measurements, Purdie (2012) found likely frazil ice concentration in McMurdo Sound from acoustic backscatter to be between ∼2.2 × 10 −7 m 3 m −3 to 2.2 × 10 −5 m 3 m −3 (0.2 g m −3 to 20 g m −3 ), another one to three orders of magnitude lower than the concentrations from Frazer et al. (2020).…”

“…Only the most extreme frazil concentration values result in overestimates of supercooling higher than the highest observed level of supercooling in some publications. This shows how important it is to be able to quantify particle concentrations precisely (e.g., Frazer et al., 2020) in order to be able to quantify any possible effects of frazil on conductivity measurements. Our values for the maximum freezing point offset to be expected from naturally occurring frazil ice concentrations are lower than the supercooling threshold of 10 mK derived by Skogseth et al.…”

“…The release of latent heat by ice formation decreases supercooling and at the same time removes freshwater in the form of ice formed on surfaces including on scientific equipment (anchor ice; e.g., Mager et al., 2013; Robinson et al., 2020), or “fine spicules or plates of ice, suspended in water” (JCOMM Expert Team on Sea Ice, 2015), frazil ice (see Daly, 1984, 1994, for reviews on frazil ice properties). Frazil crystals have been observed during episodes of supercooling in studies using both conductivity, temperature, depth (CTD) and acoustic sensors (e.g., Drucker et al., 2003; Frazer et al., 2020; Ito et al., 2015; Leonard et al., 2006).…”

“…A large body of literature exists on field measurements of frazil‐ice properties in fresh water (e.g., Ghobrial et al., 2013; Gosink & Osterkamp, 1983; Marko & Jasek, 2010; Marko et al., 2015; McFarlane et al., 2015, 2017, 2019; Morse & Richard, 2009), mainly due to the engineering challenges to infrastructure such as hydro dams (e.g., Gebre et al., 2013). Field measurements of frazil‐ice properties in seawater are less common (e.g., Frazer et al., 2020; Ito et al., 2015; Pegau et al., 1996; Penrose et al., 1994; Purdie, 2012).…”

“…Frazer et al. (2020) assumed a log‐normal distribution of particle sizes in the surface ocean of McMurdo Sound, Antarctica, and used an inverted backscattering model to derive ice volume fraction from acoustic backscattering of a four‐frequency acoustic profiler. Results suggest an average frazil diameter of 1 mm and an ice volume fraction of ∼1 × 10 −6 m 3 m −3 to 1 × 10 −4 m 3 m −3 , at least an order of magnitude smaller than the maximum frazil volume fraction observed in laboratory experiments (Schneck et al., 2019).…”

The Effect of Pseudofrazil Particle Entrainment on Salinity Measurements

“…In earlier measurements, Purdie (2012) found likely frazil ice concentration in McMurdo Sound from acoustic backscatter to be between ∼2.2 × 10 −7 m 3 m −3 to 2.2 × 10 −5 m 3 m −3 (0.2 g m −3 to 20 g m −3 ), another one to three orders of magnitude lower than the concentrations from Frazer et al. (2020).…”

“…Only the most extreme frazil concentration values result in overestimates of supercooling higher than the highest observed level of supercooling in some publications. This shows how important it is to be able to quantify particle concentrations precisely (e.g., Frazer et al., 2020) in order to be able to quantify any possible effects of frazil on conductivity measurements. Our values for the maximum freezing point offset to be expected from naturally occurring frazil ice concentrations are lower than the supercooling threshold of 10 mK derived by Skogseth et al.…”

“…The release of latent heat by ice formation decreases supercooling and at the same time removes freshwater in the form of ice formed on surfaces including on scientific equipment (anchor ice; e.g., Mager et al., 2013; Robinson et al., 2020), or “fine spicules or plates of ice, suspended in water” (JCOMM Expert Team on Sea Ice, 2015), frazil ice (see Daly, 1984, 1994, for reviews on frazil ice properties). Frazil crystals have been observed during episodes of supercooling in studies using both conductivity, temperature, depth (CTD) and acoustic sensors (e.g., Drucker et al., 2003; Frazer et al., 2020; Ito et al., 2015; Leonard et al., 2006).…”

“…A large body of literature exists on field measurements of frazil‐ice properties in fresh water (e.g., Ghobrial et al., 2013; Gosink & Osterkamp, 1983; Marko & Jasek, 2010; Marko et al., 2015; McFarlane et al., 2015, 2017, 2019; Morse & Richard, 2009), mainly due to the engineering challenges to infrastructure such as hydro dams (e.g., Gebre et al., 2013). Field measurements of frazil‐ice properties in seawater are less common (e.g., Frazer et al., 2020; Ito et al., 2015; Pegau et al., 1996; Penrose et al., 1994; Purdie, 2012).…”

“…Frazer et al. (2020) assumed a log‐normal distribution of particle sizes in the surface ocean of McMurdo Sound, Antarctica, and used an inverted backscattering model to derive ice volume fraction from acoustic backscattering of a four‐frequency acoustic profiler. Results suggest an average frazil diameter of 1 mm and an ice volume fraction of ∼1 × 10 −6 m 3 m −3 to 1 × 10 −4 m 3 m −3 , at least an order of magnitude smaller than the maximum frazil volume fraction observed in laboratory experiments (Schneck et al., 2019).…”

The Effect of Pseudofrazil Particle Entrainment on Salinity Measurements