{"@context":{"content":"http:\/\/purl.org\/rss\/1.0\/modules\/content\/","dc":"http:\/\/purl.org\/dc\/terms\/","foaf":"http:\/\/xmlns.com\/foaf\/0.1\/","og":"http:\/\/ogp.me\/ns#","rdfs":"http:\/\/www.w3.org\/2000\/01\/rdf-schema#","sioc":"http:\/\/rdfs.org\/sioc\/ns#","sioct":"http:\/\/rdfs.org\/sioc\/types#","skos":"http:\/\/www.w3.org\/2004\/02\/skos\/core#","xsd":"http:\/\/www.w3.org\/2001\/XMLSchema#","owl":"http:\/\/www.w3.org\/2002\/07\/owl#","rdf":"http:\/\/www.w3.org\/1999\/02\/22-rdf-syntax-ns#","rss":"http:\/\/purl.org\/rss\/1.0\/","site":"https:\/\/www.bco-dmo.org\/ns#","odo":"http:\/\/ocean-data.org\/schema\/","emo":"http:\/\/ocean-data.org\/schema\/entity-matching#","bibo":"http:\/\/purl.org\/ontology\/bibo\/","crypto":"http:\/\/id.loc.gov\/vocabulary\/preservation\/cryptographicHashFunctions\/","bcodmo":"http:\/\/lod.bco-dmo.org\/id\/","tw":"http:\/\/tw.rpi.edu\/schema\/","dcat":"http:\/\/www.w3.org\/ns\/dcat#","time":"http:\/\/www.w3.org\/2006\/time#","geo":"http:\/\/www.w3.org\/2003\/01\/geo\/wgs84_pos#","geosparql":"http:\/\/www.opengis.net\/ont\/geosparql#","sf":"http:\/\/www.opengis.net\/ont\/sf#","void":"http:\/\/rdfs.org\/ns\/void#","sd":"http:\/\/www.w3.org\/ns\/sparql-service-description#","dctype":"http:\/\/purl.org\/dc\/dcmitype\/","prov":"http:\/\/www.w3.org\/ns\/prov#","schema":"http:\/\/schema.org\/","geolink":"http:\/\/schema.geolink.org\/1.0\/base\/main#","spdx":"http:\/\/spdx.org\/rdf\/terms#","bcodmo_vocab":"http:\/\/schema.bco-dmo.org\/"},"@id":"http:\/\/lod.bco-dmo.org\/id\/dataset\/3847#graph","@graph":[{"http:\/\/lod.bco-dmo.org\/id\/dataset\/3847":{"@id":"http:\/\/lod.bco-dmo.org\/id\/dataset\/3847","@type":["http:\/\/ocean-data.org\/schema\/DeploymentDatasetCollection","http:\/\/www.w3.org\/ns\/dcat#Dataset","http:\/\/ocean-data.org\/schema\/Dataset"],"http:\/\/ocean-data.org\/schema\/hasAcquisitionDescription":[{"@value":"
Sampling Methodology:\u00a0<\/strong><\/p>\n Dissolved data<\/strong>:<\/p>\n Water samples were collected with a Sea-Bird Electronics CTD carousel fitted with<\/p>\n 12 30-liter PVC Niskin bottles, maintained and operated by the Ocean Data Facility of Scripps Institution of Oceangraphy. The carousel was lowered from the ship with steel wire. Niskin bottles were equipped with nylon-coated closure springs and Viton O-rings. After collection seawater was drained with Teflon-lined TygonTM<\/sup> tubing and filtered through Pall AcropakTM<\/sup> 500 filters on deck (gravity filtration, 0.8\/0.45 \u03bcm pore size) into Fisher I-Chem series 300 LDPE cubitainers. Approximately 4-5 L was collected per desired depth. Prior to the cruise, the tubing, filters and cubitainers were cleaned by immersion in 1.2 M HCl (Fisher Scientific Trace Metal Grade) for 4-5 days. Once filtered, samples were adjusted to a pH ~2 with ultra-clean 6 M HCl (Fisher Scientific OPTIMA grade), double-bagged, stored in pallet boxes on-deck until the end of the cruise and then at room temperature once shipped to the participating laboratories for analysis.<\/p>\n Particulate data:<\/strong><\/p>\n Size-fractionated particles were collected using McLane Research in-situ pumps (WTS-LV) that had been modified to accommodate two flowpaths (Lam and Morris Patent pending).\u00a0\u00a0 The wire-out was used to target depths during deployment, and a self-recording Seabird 19plus CTD deployed at the end of the line and RBR data loggers attached to three of the eight pumps were used to correct for actual depths during pumping.<\/p>\n Filter holders used were 142 mm-diameter \u201cmini-MULVFS\u201d style filter holders with two stages for two size fractions and multiple baffle systems designed to ensure even particle distribution and prevent particle loss (Bishop et al. 2012).\u00a0 One of two filter holder\/flowpaths was loaded with a 51\u00b5m Sefar polyester mesh prefilter followed by paired 0.8 \u00b5m Pall Supor800 polyethersulfone filters.\u00a0 Each cast also had \u201cdipped blank\u201d filters deployed.\u00a0 These were the full filters sets (prefilter followed by paired Supor filters) sandwiched within a 1 \u00b5m polyester mesh filter, loaded into perforated polypropylene containers, attached with plastic cable ties to a pump frame, and deployed.\u00a0 Dipped blank filters were exposed to seawater for the length of the deployment and processed and analyzed as regular samples, and thus functioned as full seawater process blanks.\u00a0 We analyzed half portions of the top and bottom filters from the \u201cdipped\u201d blank from 1 or more depths for 7 stations.<\/p>\n All filters and filter holders were acid leached prior to use according to methods recommended in the GEOTRACES sample and sample-handling Protocols (Geotraces 2010).<\/p>\n Analytical methods for dissolved radionuclides:<\/strong><\/p>\n LDEO:<\/strong><\/p>\n In the on-shore laboratory, samples were weighed to determine sample size, taking into account the weight of the cubitainer and of the acid added at sea. Then weighed aliquots of the artificial isotope yield monitors 229<\/sup>Th (20 pg) and 233<\/sup>Pa (0.5 pg) and 15 mg dissolved Fe were added to each sample. After allowing 1 day for spike equilibration, the pH of each sample was raised to 8-8.5 by adding ~10 mL of concentrated NH4<\/sub>OH (Fisher Scientific OPTIMA grade) which caused iron (oxy)hydroxide precipitates to form. This precipitate was allowed to settle for 1-2 days before the overlaying seawater was siphoned off. The Fe precipitate was transferred to centrifuge tubes for centrifugation and rinsing with Milli-Q H2<\/sub>O (>18 M\u03a9) to remove the major seawater ions. The precipitate was then dissolved in 16 M HNO3<\/sub> (Fisher Scientific OPTIMA grade) and transferred to a Teflon beaker for a high-temperature (180-200\u00b0C) digestion with HClO4<\/sub> and HF (Fisher Scientific OPTIMA grade) on a hotplate in a HEPA-filtered laminar flow hood. After total dissolution of the sample, another precipitation of iron (oxy)hydroxide followed and the precipitate was washed with Mill-Q H2<\/sub>O, centrifuged, and dissolved in 12 M HCl for a series of anion-exchange chromatography using 6 mL polypropylene columns each containing a 1 mL bed of Bio-rad resin (AG1-X8, 100-200 mesh size) and a 45 \u03bcm porous polyethylene frit (Anderson et al. 2012). The final column elutions were dried down at 180\u00b0C in the presence of 2 drops of HClO4<\/sub> and taken up in approximately 1 mL of 0.16 M HNO3<\/sub>\/0.026 M HF for mass spectrometric analysis.\u00a0<\/p>\n \u00a0\u00a0Concentrations of 232<\/sup>Th, 230<\/sup>Th and 231<\/sup>Pa were calculated by isotope dilution using nuclide ratios determined on a VG Elemental AXIOM Single Collector Magnetic Sector ICP-MS with a Resolving Power of ~400 to ensure the highest sensitivity. All measurements were done using a peak jumping routine in ion counting mode. A solution of SRM129, a natural U standard, was run to determine\u00a0the mass bias correction (assuming that the mass fractionation for Th and Pa are the same as for U). Each sample measurement was bracketed by measurement of an aliquot of the run solution,\u00a0used to correct for the instrument background count rates on the masses measured. To correct for potential tailing of 232<\/sup>Th into the minor Th and Pa isotopes, beam intensities were measured at the half masses above and below each mass for 230<\/sup>Th, 231<\/sup>Pa, and 233<\/sup>Pa. Tailing under each minor isotope was estimated as the log mean intensity of the half masses on either side of each minor isotope.<\/p>\n Water samples were analyzed in batches of 10-12. Procedural blanks were determined by processing 4-5 L of Milli-Q water in an acid-cleaned cubitainer acidified to pH ~2 with 6 M HCl as a sample in each batch. An aliquot of an intercalibrated working standard solution of 232<\/sup>Th, 230<\/sup>Th and 231<\/sup>Pa, SW STD 2010-1 referred to by Anderson et al. (2012), was added to a separate cubitainer with 5 L of Milli-Q water (acidified to pH 2) and also processed like a sample in each batch. Total procedural blanks for 232<\/sup>Th, 230<\/sup>Th, and 231<\/sup>Pa ranged from 4.2-20.9 pg, 0.8-2.2 fg, and 0-0.85 fg, respectively.\u00a0<\/p>\n UMN:<\/strong><\/p>\n In the on-shore laboratory, samples were weighed to determine sample size, taking into account the weight of the cubitainer and of the acid added at sea. Then weighed aliquots of the artificial isotope yield monitors 229<\/sup>Th and 233<\/sup>Pa and several milligrams dissolved Fe were added to each sample. After allowing 3 day for spike equilibration (at a temperature of about 40o<\/sup>C, the pH of each sample was raised to 8-8.5 by adding concentrated NH4<\/sub>OH which caused iron (oxy)hydroxide precipitates to form. This precipitate was allowed to settle for 1-2 days before the overlaying seawater was siphoned off. The Fe precipitate was transferred to centrifuge tubes for centrifugation and rinsing with deionized H2<\/sub>O (>18 M\u03a9) to remove the major seawater ions. The precipitate was then dissolved in 14 M HNO3<\/sub> and transferred to a Teflon beaker. It was then dried down and taken up in 7N HNO3<\/sub> for anion-exchange chromatography using AG1-X8, 100-200 mesh size resin and polyethylene frit. Initial separation was done on Teflon columns with a 0.75 ml column volume (CV).\u00a0 The sample was loaded in one CV of 7N HNO3<\/sub>, followed by 1.5 CV of 7N HNO3<\/sub>, 3 CV of 8N HCl (collect Th fraction), and 3 CV of 8N HCl combined with 0.015N HF (collect Pa fraction).\u00a0 The Pa and Th fractions were then dried down and taken up in 7N HNO3<\/sub>.\u00a0 They were each passed through second and third columns (each with 0.5 ml column volumes) using similar elution schemes.\u00a0 The final Pa and Th fractions were then dried down and dissolved in weak nitric acid for analysis on the mass spectrometer.\u00a0\u00a0<\/p>\n Concentrations of 232<\/sup>Th, 230<\/sup>Th and 231<\/sup>Pa were calculated by isotope dilution using nuclide ratios determined on a Thermo-Finnigan Neptune mass spectrometer. All measurements were done using a peak jumping routine in ion counting mode on the discreet dynode multiplier behind the retarding potential quadrupole.\u00a0 A solution of 233<\/sup>U-236<\/sup>U tracer was run to determine the mass bias correction (assuming that the mass fractionation for Th and Pa are the same as for U). Each sample measurement was bracketed by measurement of an aliquot of the run solution used to correct for the instrument background count rates on the masses measured.<\/p>\n Procedural blanks for chemical and mass spectrometric analyses at Minnesota are about 700 fg for 232<\/sup>Th, 15 ag for 230<\/sup>Th, and 20 ag for 231<\/sup>Pa.\u00a0\u00a0\u00a0\u00a0\u00a0<\/p>\n Further details on Pa and Th analysis at the U. Minnesota laboratory are given in Shen et al. (2002, 2003, 2012) and Cheng et al. (2000).\u00a0\u00a0<\/p>\n WHOI:<\/strong><\/p>\n In the on-shore laboratory, the analytical procedures followed the protocols described in Auro et al. (2012). Briefly, samples were weighed to determine sample size, taking into account the weight of the cubitainer. Then weighed aliquots of the artificial isotope yield monitors 229<\/sup>Th and 233<\/sup>Pa and ~100 mg dissolved Fe were added to each sample. After allowing 1 day for spike equilibration, the pH of each sample was raised to 7.5-8 by adding ~10 mL of concentrated NH4<\/sub>OH (Fisher Scientific OPTIMA grade) which caused iron (oxy)hydroxide precipitates to form. This precipitate was allowed to settle for 5-7 days before the overlaying water was siphoned off. The Fe precipitate and remaining water was transferred to polypropylene centrifuge tubes for centrifugation and rinsing with pH 8 Milli-Q H2<\/sub>O (>18 M\u03a9) to remove the major seawater ions. The precipitate was then transferred into Teflon centrifuge tubes, re-rinsed and dissolved in 12 M HCl (Fisher Scientific OPTIMA grade) for a series of anion-exchange chromatography using 10 mL polypropylene columns each containing a 0.5 mL bed of Eichrom Technologies pre-filter resin in addition to 5 mL Anion Exchange Resin (1x8, 100-200 mesh; Eichrom Technologies) for Th elution and 1.5 mL Anion Exchange Resin for Pa. A 236<\/sup>U tracer was added to the Th fraction to assist in monitoring signal intensity changes during mass spectrometry. The final column elutions were dried down at 150\u00b0C in the presence of 1 mL of 16 M HNO3<\/sub> (Fisher Scienntific OPTIMA grade) and taken up in 1 mL of 0.8 M HNO3<\/sub>\/0.13 M HF for mass spectrometric analysis.\u00a0\u00a0\u00a0<\/p>\n Concentrations of 232<\/sup>Th, 230<\/sup>Th and 231<\/sup>Pa were calculated by isotope dilution using nuclide ratios determined on a Neptune Multi Collector ICP-MS (Auro et al. 2012). Thorium isotopes were measured using a peak jumping routine with 229<\/sup>Th and 230<\/sup>Th analyzed on the central Secondary Electron Multiplier (SEM) and 232<\/sup>Th and 236<\/sup>U measured concurrently on Faraday collectors. Mass bias and ion counter yields were corrected for using an in-house thorium standard. Peak tails were calculated from the 232<\/sup>Th intensity using the pre-determined size of the tail at 2 and 3 amu for 230<\/sup>Th and 229<\/sup>Th respectively. Accuracy was assessed using a secondary consistency standard made at WHOI.\u00a0 231<\/sup>Pa and 233<\/sup>Pa were analyzed simultaneously on ion counting channels. A solution of CRM145, a natural U standard, was run to determine the mass bias (assuming that the mass fractionation for Th and Pa are the same as for U) and ion counter yields. Sample measurements were bracketed by measurement of an aliquot of the run solution, used to correct for the instrument background count rates on the masses measured. To correct for potential tailing onto the Pa isotopes, beam intensities were measured at the half masses.<\/p>\n Water samples were analyzed in batches of 10-12. Procedural blanks were determined by processing 4-5 L of Milli-Q water in an acid-cleaned cubitainer acidified to pH ~2 with 12 M HCl as a sample in each batch. One or two aliquots of an intercalibrated working standard solution of 232<\/sup>Th, 230<\/sup>Th and 231<\/sup>Pa, SW STD 2010-1 referred to by Anderson et al. (2012), was added to a separate cubitainer with 5 L of Milli-Q water (acidified to pH 2) and also processed like a sample with each batch. Total procedural blanks for 232<\/sup>Th, 230<\/sup>Th, and 231<\/sup>Pa (with the exception of one batch described below) ranged from 3-15 pg, 0.1- 0.9 fg, and 0.1-1.1 fg respectively. One batch had an anomalously high 232<\/sup>Th blank of >2500pg (with 230<\/sup>Th and 231<\/sup>Pa of 4.4 and 0.3 fg respectively) which was found to be due to a batch of contaminated acid. The 232<\/sup>Th concentrations for that batch are not reported.<\/p>\n Further details on sampling and analysis are given by Anderson et al. (2012).<\/p>\n Analytical Methods for particulate radionuclides:<\/strong><\/p>\n The Supor filters were subsampled in an on-shore laboratory at the Woods Hole Oceanographic Institution and shipped to the participating labs for Pa\/Th analysis. Twenty-five to 50% of the paired Supor filters, representing 55-350 L of seawater, were used for Pa\/Th analysis. Analyses were similar but differed slightly for the Lamont-Doherty Earth Observatory, WHOI and the University of Minnesota. Details of each groups methodologies can be found in reports by Anderson et al. (2012), Auro et al. (2012) and Shen et al. (2002, 2003, 2012), respectively. Below we give a typical procedure used at LDEO for illustrative purposes.<\/p>\n LDEO procedures:<\/strong><\/p>\n Filters were folded into 60 mL Teflon jars and weighed aliquots of the artificial isotope yield monitors 229<\/sup>Th (1 pg) and 233<\/sup>Pa (0.3-0.4 pg) and 7-8 mg dissolved Fe were added to each sample. Filters were first heated in ~5 mL 8 N HNO3<\/sub> for 1-2 hours at 150\u00b0C, then 4-5 mL HClO4<\/sub> was added and heat was increased to 200\u00b0C until dense white fumes appeared for ~10-20 min. The heat was then reduced to 180\u00b0C and the samples were covered with a Teflon watch cover. After 1-4 hrs, oxidation of the Supor material accelerated, sometimes producing a foam. A foamed sample would be allowed to cool, and re-heated after the beaker walls and watch cover were washed with small amounts of HNO3<\/sub> or Milli-Q water. When the Supor material was largely broken down, the watch covers were removed and HF was added in 2 aliquots of ~10-15 drops in between reheating until attaining dense HClO4<\/sub> fumes for at least 10 min.<\/p>\n After total dissolution of the sample, the sample-HClO4<\/sub> residue was taken up in dilute HCl, and transferred to 50 mL centrifuge tubes with water rinses. Ten to 20 drops of NH4<\/sub>OH were added to raise pH to 8-8.5 when iron (oxy)hydroxide precipitated. This precipitate was then centrifuged, decanted, washed with Milli-Q H2<\/sub>O, centrifuged, and dissolved in 12 M HCl for a series of anion-exchange chromatography using 6 mL polypropylene columns each containing a 1 mL bed of Bio-rad resin (AG1-X8, 100-200 mesh size) and a 45 \u03bcm porous polyethylene frit (Anderson et al. 2012). The final column elutions were dried down at 180\u00b0C in the presence of 2 drops of HClO4<\/sub> and taken up in approximately 1 mL of 0.16 M HNO3<\/sub>\/0.026 M HF for mass spectrometric analysis. All acids and bases used were Fisher Chemical OPTIMA grade.<\/p>\n Concentrations of 232<\/sup>Th, 230<\/sup>Th and 231<\/sup>Pa were calculated by isotope dilution using nuclide ratios determined on a Thermo Scientific Element XR Inductively-couple plasma mass spectrometer (ICP-MS) in low resolution. All measurements were done using a peak jumping routine in ion counting mode. A solution of SRM129, a natural U standard, was run to determine the mass bias correction (assuming that the mass fractionation for Th and Pa are the same as for U). Each sample measurement was bracketed by measurement of an aliquot of the run solution, used to correct for the instrument background count rates on the masses measured. To correct for potential tailing of 232<\/sup>Th into the minor Th and Pa isotopes, beam intensities were measured at the half masses above and below each mass for 230<\/sup>Th, 231<\/sup>Pa, and 233<\/sup>Pa. Tailing under each minor isotope was estimated as the log mean intensity of the half masses on either side of each minor isotope.<\/p>\n In addition to laboratory procedural blanks (reagents\/labware blanks) and periodic measurements of an intercalibrated working standard solution of 232<\/sup>Th, 230<\/sup>Th and 231<\/sup>Pa, SW STD 2010-1 referred to by Anderson et al. (2012), the participating labs also analyzed a number (n = 23) of \u201cdipped blank\u201d filters, mentioned above, to determine the total blank, associated with the sample collection and handling in addition to the laboratory procedure.<\/p>\n For better statistics, we pooled all procedural blank corrected \u201cdipped\u201d blanks (n = 23) to determine filter blank corrections. \u201cDipped\u201d filter blanks for 232<\/sup>Th, 230<\/sup>Th, and 231<\/sup>Pa were from 156 \u00b1 57 pg, 5.8 \u00b1 2.0 fg, and 0.12 \u00b1 0.04 fg, respectively. Total blanks were < 10% of the measured isotope amounts, except shallower than 200 m water depth, where blanks could be on the order of 50% of the measured 230<\/sup>Th and 231<\/sup>Pa.\u00a0\u00a0\u00a0<\/p>\n We define the limit of detection as 3 times the standard deviation in the measured \u201cdipped\u201d blanks (170 pg 232<\/sup>Th, 6.0 fg 230<\/sup>Th, and 0.13 fg 231<\/sup>Pa). There were 5 samples for which 231<\/sup>Pa was considered below detection, and all other samples were above the cited limits.<\/p>\n Further details on analysis of seawater particulate radionuclides are given by Anderson et al. (2012).<\/p>\n UMN Procedures:<\/strong><\/p>\n Filters were folded into 30 mL Teflon beaker and weighed aliquots of the artificial isotope yield monitors 229<\/sup>Th and 233<\/sup>Pa were added. Filters were first completely submerged in 7N HNO3<\/sub> acid combined with 10 drops HF, tightly covered with a Teflon threaded cap and heated for 10 hours at 200\u00b0F so that the particulate sample was dissolved\/leached under pressure. The leach solution was then transferred to a second acid-cleaned Teflon beaker separate from the residual filter.\u00a0 5 drops of HClO4<\/sub> were then added to the leach solution in the second beaker.\u00a0 The original beaker walls and caps were washed with small amounts of weak HNO3<\/sub> and the resulting solution added to the second beaker. The solution was then dried down and was taken up in 2N HCl, and transferred to 15ml centrifuge tubes along with a 2N HCl rinse. One drop of dissolved Fe and six to nine drops of NH4<\/sub>OH were added to raise pH to 8-8.5 at which time iron (oxy)hydroxide precipitated.\u00a0 This precipitate was then centrifuged, decanted, washed with deionized H2<\/sub>O (>18 M\u03a9), centrifuged, and dissolved in 14M HNO3<\/sub> and transferred to a Teflon beaker. It was then dried down and taken up in 7N HNO3<\/sub> for anion-exchange chromatography using AG1-X8, 100-200 mesh resin and a polyethylene frit. Initial separation was done on Teflon columns (internal diameter ~ 0.35cm) with a ~0.55 ml column volume (CV).\u00a0 The sample was loaded in one CV of 7N HNO3<\/sub>, followed by 1.5 CV of 7N HNO3<\/sub>, 3 CV of 8N HCl (collect Th fraction), and 3 CV of 8N HCl combined with 0.015N HF (collect Pa fraction).\u00a0 The Pa and Th fractions were then dried down in the presence of 2 drops of HClO4<\/sub> and taken up in 7N HNO3<\/sub>.\u00a0 They were each passed through second and third columns (each with ~0.55 ml column volumes) using similar elution schemes.\u00a0 The final Pa and Th fractions were then dried down in the presence of 2 drops of HClO4<\/sub> and dissolved in weak nitric acid for analysis on the mass spectrometer.<\/p>\n Concentrations of 232<\/sup>Th, 230<\/sup>Th and 231<\/sup>Pa were calculated by isotope dilution using nuclide ratios determined on a Thermo-Finnigan Neptune mass spectrometer. All measurements were done using a peak jumping routine in ion counting mode on the discreet dynode multiplier behind the retarding potential quadrupole.\u00a0 A solution of 233<\/sup>U-236<\/sup>U tracer was run to determine the mass bias correction (assuming that the mass fractionation for Th and Pa are the same as for U). Each sample measurement was bracketed by measurement of an aliquot of a wash solution, used to correct for the instrument background count rates on the masses measured.\u00a0<\/p>\n Particulate samples were analyzed in batches of 37 to 39.\u00a0 An aliquot of an intercalibrated working standard solution of 232<\/sup>Th, 230<\/sup>Th and 231<\/sup>Pa, SW STD 2010-1, was added to a separate acid-cleaned Teflon beaker along with weighed aliquots of 229<\/sup>Th spike and 233<\/sup>Pa spike. Spike and Standard were equilibrated for 3 days. The solution was then dried down and taken up in 7N HNO3<\/sub> for anion-exchange chromatography using AG1-X8, 100-200 mesh resin and a polyethylene frit, and processed like a sample. In addition to laboratory procedural blanks (reagents\/labware blanks), a number of \u201cdipped blank\u201d filters were also processed like samples, to determine the total blank, associated with the sample collection and handling, in addition to the laboratory procedure.<\/p>\n WHOI procedures (Microwave-assisted acid digestion):<\/strong><\/p>\n Sample digestions were accomplished by microwave-assisted acid digestion performed in a Multiwave 3000 (Anton Paar GmbH, Graz, Austria) instrument. Each sample (1\/2 filter) were cut into two quarter filters, and put into two pre-cleaned microwave PFA vessels with 12 mL of Aqua Regia (HCl : HNO3<\/sub>= 3:1) and 0.3 mL of HF for the sample digestion. The microwave procedure consisted of three main steps: (1) a 20 min power increasing ramp; (2) the power was electronically adjusted to maintain the internal temperature (600W) at 200\u00b0C for 90 min, and (3) a 20 min power decreasing ramp. During the session, the temperature ranged from 190\u00b0C and 230\u00b0C from one vessel to the other.<\/p>\n The two digested quarter filters were combined into one full sample (1\/2 filter). Each sample was transferred to 50mL teflon centrifuge tubes with milliQ water rinses. Purified Fe was added to each sample, which was then spiked with 229<\/sup>Th, 233<\/sup>Pa and 236<\/sup>U (Auro et al 2012), and allowed to equilibrate for at least one day. Ten to 20 drops of NH4<\/sub>OH were added to raise pH to 7.5-8.0 when iron (oxy)hydroxide precipitated. This precipitate was centrifuged, the supernatant decanted, and the remaining precipitate rinsed with pH 8 Milli-Q H2<\/sub>O, centrifuged, and dissolved in concentrated HCl. The sample was purified and separated using a series of anion-exchange chromatography steps (Auro et al 2012) using 7 mL polypropylene columns each containing Eichrom resin (AG1-X8, 200-400 mesh) and Eichrom pre-filter resin (100-150 \u03bcm). The final column elutions were dried down at 180\u00b0C and re-dissolved in one drop of concentrated HNO3<\/sub>. Dried down and taken up in approximately 1 mL of 5% HNO3+0.13N HF and 1 drop of concentrated HNO3 for mass spectrometric analysis. All acids and bases used were Fisher Chemical OPTIMA grade.<\/p>\n Concentrations of 232<\/sup>Th, 230<\/sup>Th and 231<\/sup>Pa were calculated by isotope dilution (229<\/sup>Th-233<\/sup>Pa spikes) using isotopic ratios determined on a Thermo Scientific Neptune Multi-Collector Inductively-couple plasma mass spectrometer (MC-ICP-MS) coupled to Cetac Aridus I in Low-Resolution mode (Auro et al 2012). For the Th isotopes, measurements on 229<\/sup>Th and 230<\/sup>Th were done using a \u201cpeak-hopping\u201d method where 229<\/sup>Th and 230<\/sup>Th were each analyzed on the central SEM. The 232<\/sup>Th beam was analyzed in both steps on Faraday Cup, allowing direct determinations of 232<\/sup>Th\/230<\/sup>Th and 232<\/sup>Th\/229<\/sup>Th. Mass bias correction was assessed using the uranium standard of CRM-145 (assuming that the mass fractionation for Th and Pa are the same as for U), and the accuracy of the method was evaluated by two in-house standards (ThSGS and ThB, Robinson et al., 2005; Auro et al., 2012). For the Pa isotopes, 231<\/sup>Pa and 233<\/sup>Pa were analyzed on the Multi-Ion Counts (MICs) simultaneously. The yield for each ion counters was checked using the mass bias corrected 234<\/sup>U\/238<\/sup>U ratio of CRM-145 uranium standard. To correct for potential tailing of 232<\/sup>Th into the minor Th and Pa isotopes, beam intensities were measured at the half masses above and below each mass for 230<\/sup>Th, 231<\/sup>Pa, and 233<\/sup>Pa. Tailing under each minor isotope was estimated as the log mean intensity of the half masses on either side of each minor isotope.<\/p>\n Parameter names, definitions and units notes:<\/strong><\/p>\n Radionuclide concentrations are given as micro-Becquerel (10-6 Bq, \u00b5Bq or micro-Bq) per kg seawater for 230Th and 231Pa, and pmol (10-12 mol) per kg seawater for 232Th. A Becquerel is the SI unit for radioactivity and is defined as 1 disintegration per second. These units are recommended by the GEOTRACES community.\u00a0<\/p>\n \u201cDissolved\u201d (D) here refers to that which passed through a 0.45 \u00b5m AcropakTM 500 filter capsule sampled from conventional Niskin bottles. This is true for all dissolved samples except for a select number that came from a towed pumping system designed to collect uncontaminated water at 2-3 m depth, indicated by FISH or Stn-GeoF in the sample bottle type. Surface Fish samples were filtered by a 0.2 \u00b5m Osmonics filter capsule, unlike Niskin samples.\u00a0<\/p>\n The \u201csmall particulate\u201d (SP) data refers to the particle size class 0.8-51 \u00b5m and is sometimes also called the \u201csuspended\u201d size fraction. The \u201clarge particulate\u201d (LP) data refers to particles greater than 51 \u00b5m and sometimes referred to as the \u201csinking\u201d size fraction. The particulate samples were collected by in-situ pumping over paired 0.8mm Pall Supor800 polyethersulfone filters behind a 51 mm Sefar polyester mesh prefilter (See Lam et al. 2015 for particulate sampling methodology). Analysis of the paired Supor filters represents a particle size class approximating 0.45-51 \u00b5m (Bishop et al. 2012), while the top filter alone represents 0.8-51 \u00b5m and it is this size class referred to here as the small particulate fraction. We measured a select number of top and bottom filters separately for radionuclides and found that the bottom filters had radionuclide levels that were indistinguishable from clean filter process blanks. Therefore whether or not samples were analyzed as top and bottom paired, or the top filter alone, we infer the small particulate data to represent 0.8-51 \u00b5m particles. The large particulate data is based on analysis of the 51 \u00b5m Sefar polyester mesh prefilter. Only a small selection of large particle samples (16) were analyzed at the University of Minnesota.\u00a0<\/p>\n For dissolved, seawater was weighed directly in the laboratory to determine sample size, taking into account acid added at sea. For particulates, sample size was measured by volume (liters) of seawater pumped by mass flow controllers on the in-situ pumps, but we converted seawater volume to seawater mass using a fixed seawater density of 1.025 kg\/L. Concentrations below detection are listed as \u201cbdl\u201d. The abbreviation \u201cnd\u201d refers to no data available.\u00a0<\/p>\n Parameter names in the form such as \u201cTh_232_D_CONC_BOTTLE\u201d are adopted based on a recommendation from the GEOTRACES community (http:\/\/www.egeotraces.org\/Parameter_Naming_Conventions.html<\/a>).\u00a0<\/p>\n This is compiled data produced by three laboratories with the following associations: Lamont-Doherty Earth Observatory of Columbia University (LDEO), Woods Hole Oceanographic Institution (WHOI) and the University of Minnesota (UMN).\u00a0<\/p>\n The primary reference for the dissolved data is Hayes et al. (2015, Deep-Sea Research Part II) and for the particulate data, Hayes et al. (2015, Marine Chemistry).<\/p>\n