Low radioactivity argon from underground sources Henning O. Back – Princeton University LIDINE 2013.

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Presentation transcript:

Low radioactivity argon from underground sources Henning O. Back – Princeton University LIDINE 2013

Atmospheric argon limits Argon-39 – Beta emitter (q = 565 keV, t 1/2 = 269 years) – Produced in the atmosphere through cosmic ray interactions (eg, 40 Ar(n, 2n)  39 Ar) – Atmospheric abundance 39 Ar/ 40 Ar is 8× (0.8 ppq) Specific activity = 1 Bq/kg – Is the limiting factor in size and sensitivity for argon detectors Limits detector size due to 39 Ar event pile-up One ton detector – Electron drift time across 1 ton detector (1m)= order 500μs (minimum time between events, equivalent to 2kHz) – Atmospheric 39 Ar decay rate = 1kHz/ton 5/29/21013 LIDINE 20132

Terrestrial argon sources As I understand them 40 Ar comes from 40 K decay Atmosphere – 39 Ar produced by cosmic ray neutrons Crust – No cosmic ray – Neutrons from U and Th Mantle – Very low U and Th – Lowest 39 Ar levels 5/29/21013 LIDINE Mantle Low U and Th (lowest 39 Ar)

CO 2 well is SW Colorado There are geological formations that trap gases underground We found CO 2 well in SW Colorado (near Cortez) Contains 600 ppm Argon 39 Ar activity < 0.65% of atmospheric argon (arXiv: ) 5/29/21013 LIDINE 20134

Getting to the argon Extraction – In Colorado we extract a crude argon gas mixture (Ar, N 2, and He) Purification – The gas from Cortez is then sent to Fermilab for further purification 5/29/21013 LIDINE 20135

Absorption of CO2 on 4A zeolite 5/29/21013 LIDINE Siriwardane et al., Energy & Fuels, Vol. 17, No. 3, 2003 VPSA range bar

Vacuum Pressure Swing Absorption (VPSA) Capitalize on pressure dependence of absorption Absorb CO 2 under pressure Regenerate column under vacuum Use 2 columns for (near) continuous operation 5/29/21013 LIDINE He, Ar, N 2 mixture Gas from well Absorbed gas returned to company Zeolite column Gas flows through one column under pressure. CO 2, O 2, H 2 O and CH 4 are absorbed on zeolite Simultaneously the other column is pumped on to remove the trapped gases

Our plant 5/29/21013 LIDINE Gas heaters First stageSecond stage Warms gas to avoid liquefaction by to Joule- Thomson cooling (total ΔP > 750 psi) Absorbs CO 2 and other unwanted gases Allows Ar, He, and N 2 to pass Reduces N 2 content

VPSA plant 5/29/21013 LIDINE Operated locally by technician Chris Condon – Managed by H. Back

5/29/21013 LIDINE Ar 36 Ar 28 N 40 Ar 28 N RGA limit

Production 2010 – Output 2.5% argon 70% nitrogen 27.5% helium – Production 23kg argon 2011 – Output ~5% argon – Production 53kg argon Continuous operation: May-June & July - October 2012 – Output 5-7% argon – Production 67kg argon Duty factor – 57% 2013 – Output 5-7% argon – Production (to date) ~30kg argon Duty factor – 65% 5/29/21013 LIDINE Total underground argon collected to date ~ 173kg

Purification at Fermilab The Cryogenic Distillation Column Column is filled with high surface area material Boiling and condensation happens on the surface of column packing material Controlling temperature and gas/liquid flows allows for continuous purification 5/29/21013 LIDINE Inject liquefied Ar/N 2 into column Waste gas (He and N 2 ) Product (pure Argon) Lower boiling point gas preferentially moves up column Higher boiling point liquid preferentially moves down column Packed column Temperature gradient 5.5 cm Column packing material

Distillation Column 2 – 600W cryocoolers – Balanced with 700W heaters for temperature control Reboiler cooled by liquid from column – Temperature controlled with 700W heater Active PID temperature control Active mass flow control Pressure and temperature monitoring throughout Multiple input RGA measures gas at three points – Input – Waste – Product 5/29/21013 LIDINE

5/29/21013 LIDINE

5/29/21013 LIDINE NOTE: Uncorrected pressures Nitrogen/Argon = 4.3×10 -4

5/29/21013 LIDINE Argon peaks Nitrogen H 2 O background Other backgrounds Input gas: 5% Ar 40% N 2 55% He

5/29/21013 LIDINE Consumed test gas 6 days from start 8.5 days from start Argon purity = 99.9%

5/29/21013 LIDINE

Tested gas samples Sample #1 Our RGA measurement: – N 2 = 1000 ppm Atlantic Analytical: – N 2 = 700 ppm – O 2 = 40 ppm Pacific Northwest National Lab – N 2 = 920 ppm – O 2 < 10 ppm Sample #2 Our RGA measurement: – N 2 < 500 ppm Atlantic Analytical: – N 2 = 4100 ppm – O 2 = 810 ppm Pacific Northwest National Lab (2 runs) – N 2 = 4250 and 4000 ppm – O 2 = 430 and 600 ppm We believe there was air contamination 5/29/21013 LIDINE

Argon recovery efficiency Consumed 24 high pressure cylinders with 262 scf of gas each (7419 liters) – 662g of Argon / cylinder – 14.9 kg of Argon total in 24 cylinders Accumulated mass (rough estimate) – Mass lost through product line – 50scc/m for ~10days = 1.2kg – Mass from liquid level 16 cm of liquid = 10.8 kg Total = = 12 kg – Mass from measuring flow out of reboiler during warm up Integral volume out of product – 5521liters = 9.3 kg Total = = 10.5kg Collection efficiency – During continuous distillation = 80% – Residual loss during cool down, tuning, etc. – Overall 70-80% 5/29/21013 LIDINE

First Underground Argon purification Processed 0.5M standard liters of gas Reached 99.7% pure argon Issues – Gas flow abruptly stopped - CLOGGING – Distillation stalled with different gas mixture – HIGH He CONTENT 5/29/21013 LIDINE

Solidifying impurities Residual impurities solidified in the Column Impurities are below the sensitivity of the VPSA RGA Need to remove impurities before reaching the column 5/29/21013 LIDINE ContaminantConcentration (v/v) After 500,000 standard liter of gas contaminantsgas vol.Liq./solid vol. H2OH2O25 ppm 61.2 ppm30.6 L >30 mL CO 2 30 ppm CH ppm Isopentane (C 5 H 12 ) 3.0 ppm N-pentane (C 5 H 12 ) 1.8 ppm

CDF cold traps Originally used to remove alcohol from argon/ethane mix Repurposed to remove our residual contaminants 5/29/21013 LIDINE

Condenser Booster Helium Separator Pressurize Booster with Ar-He-N 2 mixture Cool with LN 2 Ar and N2 condense Remaining pressure is He, which is then vented Pumping on LN 2 drives down temperature below 77K 5/29/21013 LIDINE

Argon collection efficiency Condenser booster pressurized to 2600 psi (175 bar) = ~3500 stp Operation at 77K – Ar vapor press. at 77K = 0.3 bar – Ar concentration in 175 bar He at 77K = 0.17% – Input gas = 5% argon – Argon lost = 3.4% Operation at 65K (subatmospheric LN2 jacket) – Ar vapor 65K =.035bar – Ar concentration in 175 bar He at 65K = 0.02% – Input gas = 5% Ar – Ar lost = 0.4% 5/29/21013 LIDINE

Recovering Ar in waste streams Argon is lost in the waste streams of the Condenser Booster and the Distillation Column Argon traps readily on charcoal at LAr temps Pass exhaust from Condenser Booster and Distillation Column to recover argon 5/29/21013 LIDINE

Complete argon purification plants at Fermilab 5/29/21013 LIDINE

Argon purification process 5/29/21013 LIDINE Waste Condenser Booster Helium Separator (CB) Condenser Booster Helium Separator (CB) Input Product Waste CB Charcoal Trap (CBCT) CB Charcoal Trap (CBCT) Input Product Waste CDF Organics Cold Traps Input Product Waste CDC Charcoal Trap CDC Charcoal Trap Product Input Waste Cryogenic Distillation Column (CDC) Input Product CDC Charcoal Trap CDC Charcoal Trap Input Waste Product Heated Getter Product Vent outside pumped out FROM COLORADO He 80-90% Ar 5-7% N % + contaminants (CO 2, CH 4, C 4 H 10, C 5 H 12, etc.) Buffer Volume CB Product He – 0% Ar – 30-40% N 2 – 60-70% + contaminants (CO 2, CH 4, C 4 H 10, C 5 H 12, etc.) CB Waste He >99% Ar – trace N 2 - trace CB-CT He – 0% Ar – 100% N 2 – 0% CDF Product He – 0% Ar – 30-40% N 2 – 60-70% CH 4 <1% CDC-CT Ar – 100% N 2 – 0% CDC-Waste N % Ar – 1% CDC Product Ar – 100% N 2 < 0.25% CH 4 ~ 2% CDC-CT Ar – 100% N 2 < 0.25% CH 4 – 0% FINAL Product Ar – 100% N 2 < 10 ppm CH 4 – 0% Transportation cylinder racks Same Charcoal Trap performing both operations Booster

Conclusions and recap Argon purification plants are complete and commissioning on going Underground argon purification begins shortly (2 weeks) VPSA plant has collected better than 170 kg of argon in Ar/He/N 2 mix Distillation column performed very well with ideal gas mixture Residual contaminants and high helium concentration required addition of new plants for their removal Unfortunately I am not available for the discussion section – I am here for most of the workshop – Contact info: or 5/29/21013 LIDINE