Presentation is loading. Please wait.

Presentation is loading. Please wait.

Analysis of Actinide Elements from Large Samples Henrieta Dulaiova Guebuem Kim Bill Burnett Florida State University and E. Philip Horwitz PG Research.

Published byCornelia Poole Modified over 9 years ago

Similar presentations

Presentation on theme: "Analysis of Actinide Elements from Large Samples Henrieta Dulaiova Guebuem Kim Bill Burnett Florida State University and E. Philip Horwitz PG Research."— Presentation transcript:

1 Analysis of Actinide Elements from Large Samples Henrieta Dulaiova Guebuem Kim Bill Burnett Florida State University and E. Philip Horwitz PG Research Foundation

2 Need for Large Volumes Achieve very low MDA's for environmental monitoring Specialized scientific studies often require large volumes to obtain necessary sensitivity, e.g., Am/Pu in seawater, global fallout in recent soils

3 Actinide Retention on Diphonix Resin Diphonix Resin high retention of actinides, Ln Low retention common ions Tolerate to HF

4 Elution: HEDPA Acid Dependency Curves Indicates that actinides should elute easily at concentrations ~0.5M

5 Protocol for 10  50-g Samples Dissolution/ Leaching Diphonix HEDPA oxidation Resins: TRU TEVA UTEVA Tracers, Fe scavenge 0.1M HCl-0.3M HF, AA  ~1 M HCl-0.5M HF, AA "Matrix" 0.5M HEDPA H 3 PO 4 + actinides, Ln’s { one or more Separation Am, Pu, etc. alpha spectrometry ICP-MS “Fenton’s Reagent” H 2 O 2 + Fe 2+  OH + OH - +Fe 3+ Diphonix bed volume 10  13 mL

6 Elution of Am

7 Fenton’s Reagent Oxidation finished Treatment: 40 mL 0.5M HEDPA + 1 mL HNO 3 + 40 mL H 2 O 2 + 0.17 g Fe(NH 4 ) 2 (SO 4 ) 2  6H 2 O Temperature ~90 o C H 2 O 2 + Fe 2+  OH + OH - +Fe 3+

8 Actinide Separations (10-g Samples) TRU  Resin 1 2 34 5 6 3 2 1 2.5M HNO 3 2.5M HNO 3 /0.1M NaNO 2 2.5M HNO 3 9M HCl 4M HCl 4M HCl/TiCl 3 6 5 4 4M HCl 2.5M HNO 3 2.5M HNO 3 /0.1M NaNO 2 2.5M HNO 3 9M HCl 1M HCl 0.1M Ammonium Bioxalate 1 2 34 5 6 Discard Am Pu Discard Th U Sample (3M HNO 3, 0.7M Al(NO 3 ) 3, FS, AA) Final clean-ups: Am/Ln on TEVA; U on UTEVA TRU  Resin tolerates high PO 4

9 TEVA  Resin Ln Removal TEVA  Resin 7 8 9 7 8 9 Discard (Ln) 4M NH 4 SCN/ 0.1M formic acid 1.5M NH 4 SCN/ 0.1M formic acid 2M HCl 7 8 9 Am 2* Am fraction from TRU  Resin HNO 3 + H 2 O 2 oxidation 3 drops of 10 % H 2 SO 4 Conc formic acid, 1 drop dissolved in 10mL 4M NH4SCN/0.1M formic acid

10 10-g Samples: Yields Samples (n=7): 3 EML soils 2 IAEA sediments 2 Fe-rich soils 7 samples run through entire procedure and analyzed for Am, Pu, U, and Th. 10-gram samples were leached with HNO 3 /HCl.

11 10-g Samples: Results Table 1: EML and IAEA intercomparison values.

12 Anal. Chem. Paper

13 TRU  Resin 1 2 34 5 6 3 2 1 30 mL 2.5M HNO 3 5 mL 9M HCl 30 mL 4M HCl 30 mL 4M HCl/1mLTiCl 3 6 5 4 4M HCl 2.5M HNO 3 2.5M HO 3 /0.1M NaNO 2 2.5M HNO 3 9M HCl 1M HCl 0.1M Ammonium Bioxalate 1 2 34 5 6 Discard Am Pu Discard Th U Sample (2.3 M HNO 3, 1M Al(NO 3 ) 3, 0.06 M NaNO 2 ) Final clean-up: Am/Ln on TEVA Not performed Only 3 steps for Am, Pu Actinide Separations – 50 g

14 Protocol for 50-g Samples Step10-gram*50-gram Leaching70 mL each: 6M HCl/8M HNO 3 4 hrs., 90 o C 150 mL each: 6M HCl/8M HNO 3 4 hrs., 90 o C Load Sol’n Add HF (0.5M), AA, adjust pH=1 ppt Fe(OH) 3 HCl, HF, AA, H 2 O to ~500 mL 1M HCl – 0.5M HF *Kim, Burnett, & Horwitz ( 2000)

15 Conditions - Diphonix Step10-gram50-gram Diphonix Column 1.2-cm diameter 10 mL resin same 13 mL resin Elution0.5M HEDPA 35 mL same 40 mL Oxid HEDPA* Fenton’s Reagent HNO 3 /H 2 O 2 /Fe 2+ same *Oxidation of HEDPA is done in a glass beaker on a hot plate – the reaction is complete in approx. 40 minutes

16 Conditions – Final Step10-gram50-gram TRU Column 0.6-cm dia, 5 mL ~15 mL HNO 3 - Al(NO 3 ) 3 -FS-AA 0.6-cm dia, 6 mL ~25 mL HNO 3 - Al(NO 3 ) 3 -NaNO 2 TEVA* (Am) Thiocyanate separation same Source Prep CeF 3 microprecipitation *Am fraction purified of lanthanides on TEVA column to prevent thick source; Pu is processed directly after TRU CeF 3 - more HF for Pu

17 Spike Tests (50-g Soil) Am-241 and Pu-239 spiked samples. Matrix = HNO 3 /HCl leach of 50-g soil and sediment samples.

18 Before loading… After ~20 minutesReaction with TRU Observations: 50-gram Samples

19 Observations: 50-g Samples Solutions highly colored after HEDPA oxidation What was happening on TRU Resin column? Pu co-precipitate with CeF 3 – needs more HF

20 EML 0009 (Soil) 50-g sample, leached with 6M HCl/8M HNO 3 Run through entire procedure… AnalyteYield % FSU mBq/g EML mBq/g Am-241927.0±0.18.3±0.7 Cm-24492124±3~100 Pu-239/240 61 * 16.5±0.216.8±0.3 Pu-238 61 * 18.7±0.219.1±0.2 *An additional 29% in 2 nd ppt; so total recovery through columns ~90%

21 0.020 0.017-0.021 0.028±0.005 85 * Pu-238 0.50 0.48-0.52 0.56±0.01 85 * Pu-239/240 0.19 0.16-0.22 0.20±0.0194Am-241 IAEA mBq/g# FSU mBq/g Yield % Analyte * An additional 10% in 2 nd ppt; so total recovery through columns ~95% # recommended value/range IAEA-326 (Soil) 50-g sample, leached with 6M HCl/8M HNO 3 Run through entire procedure…

22 Pu-CeF 3 Co-Precipitation

23 Table 2: EML and IAEA intercomparison values. 50-g Samples: Results

24 Comparison of Methods I 10-50 g10-15 g Fe(OH) 3 co-precipitation EvaporationMatrix reduction Leaching Fusion Soil Prep. FSUWSRCStep Sample size *Maxwell and Nichols (2000) *

25 Method Comparison II DIPHONIX 13 mL DIPHONIX 2.8 mL TRU TEVA/UTEVA Am, Pu, U, Th TEVA/UTEVA/ TRU/TEVA Am, Pu, U Chemical separation Elution with HEDPA -Fenton`s Reagent Microwave Destruction* FSUWSRCStep * Microwave destruction in closed vessel MW apparatus Oxidation of HEDPA on a hot plate Resin amount Matrix elimination

26 Summary Diphonix/HEPDA/oxidation process eliminates matrix TRU load with NaNO 2 works best Am/Pu separations work well via TRU  Resin Plutonium CeF 3 co-precipitation requires HF in proportion to am’t HCl

Download ppt "Analysis of Actinide Elements from Large Samples Henrieta Dulaiova Guebuem Kim Bill Burnett Florida State University and E. Philip Horwitz PG Research."

Similar presentations

Ra in Water using MnO2 Resin: New Developments

Ra in Water using MnO2 Resin: New Developments
Analysis of Actinide Elements from Large Environmental Samples

Analysis of Actinide Elements from Large Environmental Samples
A NALYTICAL S EPARATIONS G ROUP Megan Bennett, Ashlee Crable, Sherry Faye, Narek Gharibyan, Julie Gostic, and Chris Klug Subgroup Leader: Ralf Sudowe.

A NALYTICAL S EPARATIONS G ROUP Megan Bennett, Ashlee Crable, Sherry Faye, Narek Gharibyan, Julie Gostic, and Chris Klug Subgroup Leader: Ralf Sudowe.
The Separation of Beryllium from Spectral Interfering Elements in Inductively Coupled Plasma – Atomic Emission Spectroscopic Analysis Daniel R. McAlister.

The Separation of Beryllium from Spectral Interfering Elements in Inductively Coupled Plasma – Atomic Emission Spectroscopic Analysis Daniel R. McAlister.
Sample clean-up (MALDI)

Sample clean-up (MALDI)
UNRESTRICTED / ILLIMITÉ Alexandre Gagné, Xiongxin Dai, Sheila Kramer-Tremblay, Joel Surette, Candice Didychuk and Dominic Larivière* Atomic Energy of Canada.

UNRESTRICTED / ILLIMITÉ Alexandre Gagné, Xiongxin Dai, Sheila Kramer-Tremblay, Joel Surette, Candice Didychuk and Dominic Larivière* Atomic Energy of Canada.
Measurements of Ra Isotopes via MnO2 Resin

Measurements of Ra Isotopes via MnO2 Resin
Rapid Actinide Analysis for Large Soil Samples

Rapid Actinide Analysis for Large Soil Samples
New Applications of Rapid Column Extraction for Methods at SRS Sherrod L. Maxwell III Savannah River Site.

New Applications of Rapid Column Extraction for Methods at SRS Sherrod L. Maxwell III Savannah River Site.
New Extraction Methods for Urine and Fecal Samples

New Extraction Methods for Urine and Fecal Samples
Technical Updates on UTEVA, TEVA and TRU Resins

Technical Updates on UTEVA, TEVA and TRU Resins
Optimizing Radiochemical Methods at SRS

Optimizing Radiochemical Methods at SRS
Page 1EIChroM Users’ Group Meeting Determination of 226 Ra in Environmental and Personal Monitoring Samples Billy Lawrie Geoffrey Schofield Laboratories.

Page 1EIChroM Users’ Group Meeting Determination of 226 Ra in Environmental and Personal Monitoring Samples Billy Lawrie Geoffrey Schofield Laboratories.
Rapid Separation Methods for Bioassay Samples S. L. Maxwell, III and D. J. Fauth Westinghouse Savannah River Site.

Rapid Separation Methods for Bioassay Samples S. L. Maxwell, III and D. J. Fauth Westinghouse Savannah River Site.
Titration Chemistry Basics. Titration Lab technique commonly utilized to determine an UNKNOWN concentration of a chemical compound with a KNOWN concentration.

Titration Chemistry Basics. Titration Lab technique commonly utilized to determine an UNKNOWN concentration of a chemical compound with a KNOWN concentration.
THE MATHEMATICS IN A TITRATION CURVE (WITH A LITTLE BASE 10 AND LOGARITHM ARITHMATIC ADDED)

THE MATHEMATICS IN A TITRATION CURVE (WITH A LITTLE BASE 10 AND LOGARITHM ARITHMATIC ADDED)
Titrations. 13.1 Titrations A. Titrations – is an experimental procedure in which a standard solution is used to determine the concentration of an unknown.

Titrations Titrations A. Titrations – is an experimental procedure in which a standard solution is used to determine the concentration of an unknown.
MnO 2 Resin: Concentration of Radium Isotopes Deok-Soo Moon Bill Burnett Department of Oceanography Florida State University Tallahassee, Florida.

MnO 2 Resin: Concentration of Radium Isotopes Deok-Soo Moon Bill Burnett Department of Oceanography Florida State University Tallahassee, Florida.
Determination of Iron in Water

Determination of Iron in Water
Determination of Iron in Water

Determination of Iron in Water

Similar presentations

Ads by Google