Depleted A rgon F rom Underground Sources
1
Depleted Argon From Underground Sources A. Alton 1 , H. O. Back 2 , C. Galbiati 2 , A. Goretti 2 , C. Kendziora 3 , B. Loer 2 , D. Montanari 2 , P. Mosteiro 2 , S. Pordes 3 1) Augustana College 2) Princeton University 3) Fermi National Accelerator Laboratory As a strong scintillator argon is an ideal medium for Dark Matter detection. However, a limiting contamination in atmospheric argon is the beta emitter 39 Ar ( 39 Ar 39 K + e - +`ν e (Q = 535 keV)). It is possible to reject beta events through pulse shape analysis, but 39 Ar limits the size of a detector due to event pile-up. 39 Ar is produced in the upper atmosphere in 40 Ar(n,2n) reactions, and is found in the atmosphere at a level of 8.1×10 -16 39 Ar/ 40 Ar; corresponding to more than 1 Bq/ton of atmospheric argon. A place to search for argon gas deplete in 39 Ar is deep underground where the cosmic ray flux is highly suppressed and therefore 39 Ar production rate is significantly reduced. We have identified a CO 2 well in southwestern Colorado that contains argon. The 39 Ar concentration in this argon has been measured to be reduced by more than a factor of 25. However, the argon must be extracted from the CO 2 and further purified in order to be used in a detector. Chromatographic Gas Separation Getting the argon Continuous Distillation Gas Separation Purifying the argon He, Ar, N 2 mixture Gas from well Absorbed gas returned to company Z e o l i t e c o l u m n Z e o l i t e c o l u m n 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 Gas composition from the CO 2 well: • 96% - CO 2 • 2.4% - N 2 • 5,700 ppm - CH 4 • 4,300 ppm - He • 2,100 ppm - Other hydrocarbons • 1,000 ppm - H 2 O • 600 ppm - Ar • Below sensitivity - O It is possible to trap gases on an absorptive media, while allowing other gases to pass. The absorptive media will eventually become saturated with the trapped gases, but the absorption efficiency is proportional to the pressure. We therefore absorb gases under pressure, and force the release of the gases by pumping a vacuum on the media. The media is then regenerated for further absorption. Outside of Cortez Colorado we have built such a vacuum-pressure swing absorption unit to extract the depleted argon from a CO 2 well. Our unit consist of 2 stages, of 2 columns each. The first stage traps CO 2 , O 2, and other unwanted gases on zeolite under pressure. Still under pressure the second stage continues to remove these gases as well as some of the nitrogen. When a column is nearly saturated, the gas is allowed to flow through another column and a vacuum is pumped on the first column to regenerate the media. The CO 2 and other gases are then returned to Collected output gas: N 2 – 70% He – 27.5% Ar –2.5% 26Kg of argon collected to date The difference in boiling points of a multi component liquid allows us to perform separation through distillation. Distillation can be done continuously in a column packed with a high surface area material, and a temperature gradient. The liquid will boil and the gas recondenses continuously on the packing material. Gases rise and recondense, while liquids sink and reboil. The component with the lower boiling point rises preferentially and the component with the higher boiling point drops down to the lower volume. By maintaining a constant temperature gradient and a constant flow of liquid into the column, an equilibrium is set up, and very pure material can be extracted from the column. Inject liquefied Ar/N 2 into column Waste gas (He and N 2 ) Product gas (pure Argon) Lower boiling point gas preferentially moves up column Higher boiling point liquid preferentially moves down column P a c k e d c o l u m n T e m p e r a t u r e g r a d i e n t 5.5 cm Column packing material At Fermilab a cryogenic distillation column is being constructed. This column is 320 cm tall and 2 cm in diameter. The custom packing material make this column equivalent to 40 theoretical stages. Expected Performance: Purity – 99.9999% pure argon Production rate – 5kg/day Vacuum-Pressure Swing Absorption (VPSA) unit in Colorado Cryogenic distillation column located at Fermilab
-
Upload
clayton-morin -
Category
Documents
-
view
20 -
download
0
description
Depleted A rgon F rom Underground Sources. A. Alton 1 , H . O. Back 2 , C. Galbiati 2 , A. Goretti 2 , C. Kendziora 3 , B. Loer 2 , D. Montanari 2 , P. Mosteiro 2 , S. Pordes 3 Augustana College Princeton University Fermi National Accelerator Laboratory. - PowerPoint PPT Presentation
Transcript of Depleted A rgon F rom Underground Sources
Depleted Argon From Underground SourcesA. Alton1, H. O. Back2, C. Galbiati2, A. Goretti2, C. Kendziora3, B. Loer2, D. Montanari2, P. Mosteiro2, S. Pordes3
1) Augustana College2) Princeton University
3) Fermi National Accelerator Laboratory
As a strong scintillator argon is an ideal medium for Dark Matter detection. However, a limiting contamination in atmospheric argon is the beta emitter 39Ar (39Ar 39K + e- +`νe (Q = 535 keV)). It is possible to reject beta events through pulse shape analysis, but 39Ar limits the size of a detector due to event pile-up. 39Ar is produced in the upper atmosphere in 40Ar(n,2n) reactions, and is found in the atmosphere at a level of 8.1×10-16 39Ar/40Ar; corresponding to more than 1 Bq/ton of atmospheric argon. A place to search for argon gas deplete in 39Ar is deep underground where the cosmic ray flux is highly suppressed and therefore 39Ar production rate is significantly reduced. We have identified a CO2 well in southwestern Colorado that contains argon. The 39Ar concentration in this argon has been measured to be reduced by more than a factor of 25. However, the argon must be extracted from the CO2 and further purified in order to be used in a detector.
Chromatographic Gas SeparationGetting the argon
Continuous Distillation Gas SeparationPurifying the argonHe, Ar, N2
mixture
Gas from well
Absorbed gas returned to company
Zeolite column
Zeolite column
Gas flows through one column under pressure. CO2, O2, H2O and CH4 are absorbed on zeolite
Simultaneously the other column is pumped on to remove the trapped gases
Gas composition from the CO2 well:• 96% - CO2
• 2.4% - N2
• 5,700 ppm - CH4
• 4,300 ppm - He• 2,100 ppm - Other hydrocarbons• 1,000 ppm - H2O• 600 ppm - Ar• Below sensitivity - O2
It is possible to trap gases on an absorptive media, while allowing other gases to pass. The absorptive media will eventually become saturated with the trapped gases, but the absorption efficiency is proportional to the pressure. We therefore absorb gases under pressure, and force the release of the gases by pumping a vacuum on the media. The media is then regenerated for further absorption.
Outside of Cortez Colorado we have built such a vacuum-pressure swing absorption unit to extract the depleted argon from a CO2 well. Our unit consist of 2 stages, of 2 columns each. The first stage traps CO2, O2, and other unwanted gases on zeolite under pressure. Still under pressure the second stage continues to remove these gases as well as some of the nitrogen.When a column is nearly saturated, the gas is allowed to flow through another column and a vacuum is pumped on the first column to regenerate the media. The CO2 and other gases are then returned to the company.
Collected output gas: N2 – 70% He – 27.5% Ar –2.5%
26Kg of argon collected to date
The difference in boiling points of a multi component liquid allows us to perform separation through distillation.Distillation can be done continuously in a column packed with a high surface area material, and a temperature gradient. The liquid will boil and the gas recondenses continuously on the packing material. Gases rise and recondense, while liquids sink and reboil. The component with the lower boiling point rises preferentially and the component with the higher boiling point drops down to the lower volume. By maintaining a constant temperature gradient and a constant flow of liquid into the column, an equilibrium is set up, and very pure material can be extracted from the column.
Inject liquefied Ar/N2into column
Waste gas (He and N2)
Product gas (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
At Fermilab a cryogenic distillation column is being constructed. This column is 320 cm tall and 2 cm in diameter. The custom packing material make this column equivalent to 40 theoretical stages.
Expected Performance: Purity – 99.9999% pure argonProduction rate – 5kg/day
Vacuum-Pressure Swing Absorption (VPSA) unit in Colorado
Cryogenic distillation column located at Fermilab
