Laboratory study of the properties of frazil ice particles and flocs in water of different salinities

Schneck, Christopher C.; Ghobrial, Tadros; Loewen, Mark

doi:10.5194/tc-13-2751-2019

Cited by 17 publications

(37 citation statements)

References 39 publications

(81 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Newly formed anchor ice accumulations likely have higher porosities because they often do not maintain their structural integrity when sampling is attempted. The porosity of frazil ice flocs has been estimated to be approximately 0.80 (Schneck et al, 2019) and this may represent a reasonable upper limit for the porosity of newly deposited anchor ice. Values for the accretion rate γ in the literature range from approximately 10 -6 to 10 -3 (Malenchak, 2011) and measurements of the volumetric concentration of frazil Cv reported in the literature vary from 10 -6 to 10 -2 (McFarlane et al, 2019).…”

Section: Discussionmentioning

confidence: 95%

Continuous in situ measurements of anchor ice formation, growth and release

Ghobrial¹,

Loewen²

2020

Preprint

Self Cite

View full text Add to dashboard Cite

Abstract. In northern rivers, turbulent water becomes supercooled (i.e. cooled to slightly below 0 °C) when exposed to freezing air temperatures. In supercooled water, frazil (small ice disks) crystals are generated in the water column and anchor ice starts to form on the bed. Two anchor ice formation mechanisms have been reported in the literature: either by the accumulation of suspended frazil particles, which are adhesive (sticky) in nature, on the river bed; or by in situ growth of ice crystals on the bed material. Once anchor ice has formed on the bed, the accumulation typically continues to grow (either due to further frazil accumulation and/or crystal growth) until release occurs due to mechanical (shear force by the flow or buoyancy of the accumulation) or thermal (warming of the water column which weakens the ice-substrate bond) forcing or a combination of the two. Although detailed laboratory experiments have been reported to study anchor ice, but very few field measurements of anchor ice processes have been reported. These measurements have relied on either sampling anchor ice accumulations from the river bed, or qualitatively describing the observed formation and release. In this study, a custom-built imaging system (camera and lighting) was developed to capture high-resolution digital images of anchor ice formation and release on the river bed. A total of six anchor ice events were successfully captured in the time-lapse images and for the first time, the different initiation, growth and release mechanisms were measured in the field. Four stages of the anchor ice cycle were identified, namely: Stage 1: initiation by in situ crystal growth, Stage 2: transitional phase, Stage 3: linear growth, and Stage 4: release phase. Anchor ice initiation due to in situ growth was observed in three events and in the remainder the accumulation appeared to be initiated by frazil deposition. The Stage 1 growth rates ranged from 1.3 to 2.0 cm/hr and the Stage 2 and 3 growth rates varied from 0.3 to 0.9 cm/hr. Anchor ice was observed releasing from the bed in three modes referred to as lifting, shearing and rapid.

show abstract

Section: Discussionmentioning

confidence: 95%

Continuous in situ measurements of anchor ice formation, growth and release

Ghobrial¹,

Loewen²

2020

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…where N is the number density of scatterers and g is the probability distribution of scatterers' diameter. Following and and supported by recent observations (McFarlane et al, 2015(McFarlane et al, , 2017(McFarlane et al, , 2019Schneck et al, 2019) and theoretical considerations (Crow & Shimizu, 1988), we choose a log-normal distribution, g ∼ Λ( , ). We associate Σ th bs ( ) with the measured backscattering cross section Σ obs bs ( ).…”

Section: Instrumentation and Data Processingmentioning

confidence: 99%

“…Only Schneck et al (2019) have made laboratory measurements of frazil size distributions in salt water and shown they again follow a log-normal distribution. The ice crystal diameters are ∼13% smaller than in fresh water, with a mean diameter of 0.45 mm, standard deviation 0.31 mm, while flocs have a mean of 1.47 mm and standard deviation of 1.28 mm (Schneck et al, 2019). McFarlane et al (2017McFarlane et al ( , 2019 also summarize the methods of detection of suspended frazil in laboratory and river studies.…”

Section: Research Lettermentioning

confidence: 99%

“…Suspended frazil ice crystals form in turbulent fresh or salt water that is colder than its salinity‐ and pressure‐dependent freezing temperature, a state referred to as in situ supercooled (e.g., Daly, 1984; Martin, 1981; Schneck et al, 2019; Tsang & Hanley, 1985). In natural water bodies in situ supercooling can be generated in numerous ways (Martin, 1981), but two are of particular importance in the Southern Ocean.…”

Section: Introductionmentioning

confidence: 99%

“…Quantitative observations of the shape and size of individual frazil ice particles in salt water of ocean salinity are sparse, with suspended ice crystal diameters ranging 1–3 mm in laboratory experiments (e.g., Martin, 1981; Schneck et al, 2019; Smedsrud, 2001) and an upper bound of 10–25 mm in the ocean (Dieckmann et al, 1986; Gough et al, 2012; Penrose et al, 1994). Only Schneck et al (2019) have made laboratory measurements of frazil size distributions in salt water and shown they again follow a log‐normal distribution. The ice crystal diameters are ∼13% smaller than in fresh water, with a mean diameter of 0.45 mm, standard deviation 0.31 mm, while flocs have a mean of 1.47 mm and standard deviation of 1.28 mm (Schneck et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Observations of the Size Distribution of Frazil Ice in an Ice Shelf Water Plume

Frazer

Langhorne

Leonard

et al. 2020

Geophysical Research Letters

View full text Add to dashboard Cite

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 below mean sea level was monitored over 3 weeks in November of 2016 and 2017. At 15 m below sea level the mean frazil crystal diameter was ∼1 mm. Fractional ice volume, derived from frazil crystal size and number density, correlates with in situ supercooling (up to 50 mK at 15 m below sea level). The data presented here provide valuable input for model initiation and evaluation. Plain Language Summary For the first time we have observed the number and sizes of tiny, disc-like, crystals that appear beneath the springtime sea ice of McMurdo Sound, Antarctica. They are generated by melting at the base of gigantic floating glaciers that surround the Antarctic continent, and are carried out beneath the sea ice in water that is just below its freezing point. From sonar measurements we have found that at 15 m below sea level, there is about one disc-shaped ice crystal with an average diameter of approximately 1 mm in each 10 cm 3 of sea water. Previously, there have been no observed sizes of these ice crystals to guide modeling of the interaction between glaciers and the ocean, and our new results provide valuable input for model initiation and evaluation.

show abstract

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

Frazer

Langhorne

Leonard

et al. 2020

Preprint

View full text Add to dashboard Cite

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 below mean sea level was monitored over 3 weeks in November of 2016 and 2017. At 15 m below sea level the mean frazil crystal diameter was ∼1 mm. Fractional ice volume, derived from frazil crystal size and number density, correlates with in situ supercooling (up to 50 mK at 15 m below sea level). The data presented here provide valuable input for model initiation and evaluation.Plain Language Summary For the first time we have observed the number and sizes of tiny, disc-like, crystals that appear beneath the springtime sea ice of McMurdo Sound, Antarctica. They are generated by melting at the base of gigantic floating glaciers that surround the Antarctic continent, and are carried out beneath the sea ice in water that is just below its freezing point. From sonar measurements we have found that at 15 m below sea level, there is about one disc-shaped ice crystal with an average diameter of approximately 1 mm in each 10 cm 3 of sea water. Previously, there have been no observed sizes of these ice crystals to guide modeling of the interaction between glaciers and the ocean, and our new results provide valuable input for model initiation and evaluation.

show abstract

Laboratory study of the properties of frazil ice particles and flocs in water of different salinities

Cited by 17 publications

References 39 publications

Continuous in situ measurements of anchor ice formation, growth and release

Continuous in situ measurements of anchor ice formation, growth and release

Observations of the Size Distribution of Frazil Ice in an Ice Shelf Water Plume

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

Contact Info

Product

Resources

About