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Nimrod (dynamic penetrometer) measurements of a sandbar at Raglan, New Zealand in 2009 (2013)

Stark, Nina ; Kopf, Achim J

PANGAEA

In: Supplement to: Stark, Nina; Kopf, Achim J (2013): In-situ geotechnical investigation of sediment remobilitzation processes utilizing geotechnical measurement techniques to detect, quantify and describe sediment erosion and deposition. Sea Technology, 54

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Publication Date: 2023-03-03

Description: Dynamic penetrometer data obtained with the Nimrod penetrometer (MARUM). Data is presented as (i) penetration depth (including for different layers if present), (ii) measured deceleration and (iv) estimated quasi-static bearing capacity including range of uncertainty due to the processing method. Lat/Long coordinates are given.

Keywords: Center for Marine Environmental Sciences; Deceleration; Event label; Latitude of event; Layer number; Longitude of event; MARUM; NIM; NIMROD; Number; Penetration depth; Quasi-static bearing capacity; Raglan_1; Raglan_10; Raglan_11; Raglan_13; Raglan_15; Raglan_16; Raglan_17; Raglan_18; Raglan_19; Raglan_2; Raglan_20; Raglan_21; Raglan_3; Raglan_4; Raglan_5; Raglan_6; Raglan_7; Raglan_8; Raglan_9; Raglan, New Zealand; Uncertainty

Type: Dataset

Format: text/tab-separated-values, 178 data points

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Penetration velocity and deceleration of penetrometer stations N1 to N97 during cruise Senckenberg_11_2008 (2010)

Stark, Nina ; Hanff, Hendrik ; Svenson, C ; [et al.]

PANGAEA

In: Supplement to: Stark, Nina; Hanff, Hendrik; Svenson, C; Ernstsen, Verner Brandbyge; Lefebvre, Alice; Winter, Christian; Kopf, Achim J (2011): Coupled penetrometer, MBES and ADCP assessments of tidal variations in surface sediment layer characteristics along active subaqueous dunes, Danish Wadden Sea. Geo-Marine Letters, 31(4), 249-258, https://doi.org/10.1007/s00367-011-0230-6

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Publication Date: 2023-04-20

Description: In-situ geotechnical measurements of surface sediments were carried out along large subaqueous dunes in the Knudedyb tidal inlet channel in the Danish Wadden Sea using a small free-falling penetrometer. Vertical profiles showed a typical stratification pattern with a resolution of ~1 cm depicting a thin surface layer of low sediment strength and a stiffer substratum below (quasi-static bearing capacity equivalent: 1–3 kPa in the top layer, 20–140 kPa in the underlying sediment; thickness of the top layer ca. 5–8 cm). Observed variations in the thickness and strength of the surface layer during a tidal cycle were compared to mean current velocities (measured using an acoustic Doppler current profiler, ADCP), high-resolution bathymetry (based on multibeam echo sounding, MBES) and qualitative estimates of suspended sediment distributions in the water column (estimated from ADCP backscatter intensity). The results revealed an ebb dominance in sediment remobilization, and a general accretion of the bed towards low water. A loose top layer occurred throughout the tidal cycle, likely influenced by bedload transport and small events of suspended sediment resettlement (thickness: 6 +-2 cm). Furthermore, this layer showed a significant increase in thickness (e.g. from 8 cm to 16 cm) related to periods of overall deposition. These findings imply that dynamic penetrometers can conveniently serve to (1) quantify potentially mobile sediments by determining the thickness of a loose sediment surface layer, (2) unravel sediment strength development in potentially mobile sediments and (3) identify sediment accumulation. Such data are an important complement and add a new geotechnical perspective during investigations of sediment remobilization processes in highly dynamic coastal environments.

Keywords: Center for Marine Environmental Sciences; Deceleration; Event label; Free fall penetrometer, NIMROD; Knudedyb, Denmark; MARUM; N1; N10; N11; N12; N13; N14; N15; N16; N17; N18; N19; N2; N20; N21; N22; N23; N24; N25; N26; N27; N28; N29; N3; N30; N31; N32; N33; N34; N35; N36; N37; N38; N39; N4; N40; N41; N42; N43; N44; N45; N46; N47; N48; N49; N5; N50; N51; N52; N53; N54; N55; N56; N57; N58; N59; N6; N60; N61; N62; N63; N64; N65; N66; N67; N68; N69; N7; N70; N71; N72; N73; N74; N75; N76; N77; N78; N79; N8; N80; N81; N82; N83; N88; N89; N9; N90; N91; N92; N94; N95; N96; N97; NIM; NIMROD; Penetration depth; Penetration velocity; Senckenberg; Senckenberg_11_2008; Senckenberg_11_2008_N1; Senckenberg_11_2008_N10; Senckenberg_11_2008_N11; Senckenberg_11_2008_N12; Senckenberg_11_2008_N13; Senckenberg_11_2008_N14; Senckenberg_11_2008_N15; Senckenberg_11_2008_N16; Senckenberg_11_2008_N17; Senckenberg_11_2008_N18; Senckenberg_11_2008_N19; Senckenberg_11_2008_N2; Senckenberg_11_2008_N20; Senckenberg_11_2008_N21; Senckenberg_11_2008_N22; Senckenberg_11_2008_N23; Senckenberg_11_2008_N24; Senckenberg_11_2008_N25; Senckenberg_11_2008_N26; Senckenberg_11_2008_N27; Senckenberg_11_2008_N28; Senckenberg_11_2008_N29; Senckenberg_11_2008_N3; Senckenberg_11_2008_N30; Senckenberg_11_2008_N31; Senckenberg_11_2008_N32; Senckenberg_11_2008_N33; Senckenberg_11_2008_N34; Senckenberg_11_2008_N35; Senckenberg_11_2008_N36; Senckenberg_11_2008_N37; Senckenberg_11_2008_N38; Senckenberg_11_2008_N39; Senckenberg_11_2008_N4; Senckenberg_11_2008_N40; Senckenberg_11_2008_N41; Senckenberg_11_2008_N42; Senckenberg_11_2008_N43; Senckenberg_11_2008_N44; Senckenberg_11_2008_N45; Senckenberg_11_2008_N46; Senckenberg_11_2008_N47; Senckenberg_11_2008_N48; Senckenberg_11_2008_N49; Senckenberg_11_2008_N5; Senckenberg_11_2008_N50; Senckenberg_11_2008_N51; Senckenberg_11_2008_N52; Senckenberg_11_2008_N53; Senckenberg_11_2008_N54; Senckenberg_11_2008_N55; Senckenberg_11_2008_N56; Senckenberg_11_2008_N57; Senckenberg_11_2008_N58; Senckenberg_11_2008_N59; Senckenberg_11_2008_N6; Senckenberg_11_2008_N60; Senckenberg_11_2008_N61; Senckenberg_11_2008_N62; Senckenberg_11_2008_N63; Senckenberg_11_2008_N64; Senckenberg_11_2008_N65; Senckenberg_11_2008_N66; Senckenberg_11_2008_N67; Senckenberg_11_2008_N68; Senckenberg_11_2008_N69; Senckenberg_11_2008_N7; Senckenberg_11_2008_N70; Senckenberg_11_2008_N71; Senckenberg_11_2008_N72; Senckenberg_11_2008_N73; Senckenberg_11_2008_N74; Senckenberg_11_2008_N75; Senckenberg_11_2008_N76; Senckenberg_11_2008_N77; Senckenberg_11_2008_N78; Senckenberg_11_2008_N79; Senckenberg_11_2008_N8; Senckenberg_11_2008_N80; Senckenberg_11_2008_N81; Senckenberg_11_2008_N82; Senckenberg_11_2008_N83; Senckenberg_11_2008_N88; Senckenberg_11_2008_N89; Senckenberg_11_2008_N9; Senckenberg_11_2008_N90; Senckenberg_11_2008_N91; Senckenberg_11_2008_N92; Senckenberg_11_2008_N94; Senckenberg_11_2008_N95; Senckenberg_11_2008_N96; Senckenberg_11_2008_N97

Type: Dataset

Format: text/tab-separated-values, 13134 data points

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In-situ geotechnical measurements with the dynamic penetrometer Nimrod on the continental shelf off the Coromandel Peninsula, New Zealand (2012)

Stark, Nina ; Coco, Giovanni ; Bryan, Karin R ; [et al.]

PANGAEA

In: Supplement to: Stark, Nina; Coco, Giovanni; Bryan, Karin R; Kopf, Achim J (2012): In-situ geotechnical characterization of mixed-grain-size bedforms using a dynamic penetrometer. Journal of Sedimentary Research, 82(7-8), 540-544, https://doi.org/10.2110/jsr.2012.45

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Publication Date: 2023-07-11

Description: We tested the ability of a small dynamic penetrometer, Nimrod, to infer geotechnical properties of sediment mixtures in the inner shelf. The penetrometer is light and easy to operate, and its operation by scuba divers ensures a greater degree of precision than ship-based penetrometer deployments. We have studied selected positions along a sorted bedform (~ 100 m wide) on the continental shelf off the Coromandel Peninsula close to Tairua, North Island of New Zealand, and additionally took sediment samples at the exact positions of penetrometer impact, also by scuba divers. The derived dynamic penetrometer signatures (i) measured deceleration of the probe and estimated quasi-static bearing capacity as a measure of sediment strength, (ii) reflected changes in grain-size distribution ranging from very fine to very coarse sands, and (iii) revealed the uppermost seafloor stratification (top layer 2-6 cm) potentially being an indicator for sediment dynamics. In this manner, the device proved to be suitable for spatially fine-scaled surveys using divers' support and might deliver complementary information about sediment dynamics, in this case sorted-bedform maintenance.

Keywords: Calculated; Center for Marine Environmental Sciences; Comment; Deceleration; Distance; Event label; Layer thickness; MARUM; NIM; NIMROD; Number; Penetration depth; Penetration velocity; Quasi-static bearing capacity; Sediment type; Site; Size fraction; Tairua_T1_M; Tairua_T1_S; Tairua_T10_M; Tairua_T10_S; Tairua_T11_M; Tairua_T11_N; Tairua_T12_M; Tairua_T12_N; Tairua_T13_M; Tairua_T13_N; Tairua_T14_M; Tairua_T14_N; Tairua_T15_M; Tairua_T15_N; Tairua_T16_M; Tairua_T16_N; Tairua_T17_M; Tairua_T17_N; Tairua_T18_M; Tairua_T18_N; Tairua_T19_M; Tairua_T19_N; Tairua_T2_M; Tairua_T2_S; Tairua_T20_M; Tairua_T20_N; Tairua_T3_M; Tairua_T3_S; Tairua_T4_M; Tairua_T4_S; Tairua_T5_M; Tairua_T5_S; Tairua_T6_M; Tairua_T6_S; Tairua_T7_M; Tairua_T7_S; Tairua_T8_M; Tairua_T8_S; Tairua_T9_M; Tairua_T9_S; Tairua Beach

Type: Dataset

Format: text/tab-separated-values, 412 data points

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Application of a portable free-fall penetrometer for the geotechnical investigation of the Arctic nearshore zone (2016)

Stark, Nina ; Radosavljevic, Boris ; Quinn, Brandon ; [et al.]

In: EPIC3Canadian Geotechnical Journal

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Publication Date: 2016-10-10

Description: The Arctic is currently undergoing rapid changes with regard to sea ice extent, permafrost thaw and coastal erosion. In addition to hydrodynamic processes, the sediments in the Arctic nearshore zone are affected by freeze-thaw cycles, as well as an increase of abundant suspended sediment introduced by permafrost-induced mass movements, such as retrogressive thaw slumps, and increased river discharge. During the YUKON14 expedition to Herschel Island, Yukon, in-situ geotechnical testing of nearshore zone sediments was conducted using a portable free fall penetrometer. Approximately 200 sites were tested, and four different geotechnical signatures identified and grouped. Most locations were characterized by a soft sediment top layer that exhibited a noticeably lower sediment strength than the underlying sediment. In some cases, multiple layers of different sediment strength were detected in the upper meter of the seabed surface. The results were correlated to existing sediment grain size records and backscatter information from a phase measuring bathymetric sonar. Strong spatial variations in sediment type and stiffness were observed, as well as in abundance and thickness of a top layer of very soft and loose sediment. The geotechnical signatures were correlated to site-specific hydrodynamic conditions, morphology, and vicinity to thaw slumps.

Repository Name: EPIC Alfred Wegener Institut

Type: Article , peerRev

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Geotechnical investigations of coastal sediments at the arctic permafrost edge: preliminary results from an expedition to Herschel Island (2015)

Stark, Nina ; Quinn, Brandon ; Lantuit, Hugues ; [et al.]

World Scientific

In: EPIC3World Scientific, ISBN: 978-981-4689-97-9

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Publication Date: 2016-01-26

Repository Name: EPIC Alfred Wegener Institut

Type: Book , peerRev

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Geotechnical Investigation of Pore Pressure Behavior of Muddy Seafloor Sediments in an Arctic Permafrost Environment (2015)

Stark, Nina ; Quinn, Brandon ; Ziotopoulou, Katerina ; [et al.]

In: EPIC3ASME 2015 34th International Conference on Ocean, Offshore and Arctic Engineering, Volume, pp. 1-10

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Publication Date: 2015-12-02

Description: Herschel Island, Yukon, Canada, is made of ice-rich permafrost and is affected by high rates of coastal erosion, likely to increase with decreasing summer sea ice extent. During an interdisciplinary expedition to Herschel Island in July 2014, geotechnical investigations were carried out in shallow water environments of up to 20 m water depth and at different beaches. The free-fall penetrometer BlueDrop was deployed at 299 positions. Apart from obtaining vertical profiles of sediment strength and the pore pressure response upon impact, the pore pressure evolution over a period of one hour after deployment was investigated. The focus area for these tests was Pauline Cove, located at the south-eastern side of the island, being sheltered by a spit from the open Beaufort Sea and affected by a number of old and young retrogressive thaw slumps, delivering large amounts of mud. The sediment resistance profiles revealed up to three distinct layers of sediment strength, expressing different consolidation states, or possibly changes in sediment composition. This stratification was supported by the pore pressure results, including pore pressure evolution “on-the-flight” during penetrometer penetration as well as pore pressure evolution at maximum penetration depth with the penetrometer being at rest. The sediment surface layer 1 was characterized by a thickness of 5–20 cm depending on the respective location, low sediment resistance and predominantly hydrostatic pressure. It most likely has frequently been reworked by wave action, and exhibited similar geotechnical signatures as fluid mud. Layer 2 reached sediment depths of 30–60 cm, showed an increase in sediment resistance and distinct subhydrostatic pore pressures during penetration, while pore pressures increased in an asymptotic manner to suprahydrostatic (160–180% of hydrostatic pressure) over an observation period of 30–50 minutes. Based on comparison to other examples from the literature, it was hypothesized that layer 2 was composed of overconsolidated mud. Layer 3 featured a significant increase in sediment resistance as well as pore pressure during penetration. As soon as the probe came to rest, the pressure decreased significantly to subhydrostatic conditions, before swinging back to being suprahydrostatic and then slowly dissipating. A similar behavior has been associated to silty sands and high bulk densities. Here, it may suggest a change in sediment composition, likely influenced by coarser nearshore and beach sediments, representing also a denser sediment matrix. The pore pressure results will complement the geological and geotechnical characterization of the coastal zone of Hershel Island, and contribute to the investigation of erosion and deposition processes. Copyright © 2015 by ASME

Repository Name: EPIC Alfred Wegener Institut

Type: Article , peerRev

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