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Measurement Overview

Measurement Overview. Units of Measure Sampling Methods Measurement Duration “What the Lab Sees”. Units of Measurement. Radon is measured in pCi/L. Radon Decay Products are measured in working levels (WL) .

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Measurement Overview

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  1. Measurement Overview • Units of Measure • Sampling Methods • Measurement Duration • “What the Lab Sees”

  2. Units of Measurement • Radon is measured in pCi/L. • Radon Decay Products are measured in working levels (WL) . • 100 pCi/L of radon gas, in equilibrium with its decay products, produces 1 WL of radon decay products.

  3. pCi/L or Working Level?Depends on Sampling Mechanics • Insert Slide #4

  4. Uranium - 238 Decay Series • Insert Slide #5

  5. What does the Lab look When measuring radon gas?

  6. Radon • Radon (with all RDPs from room filtered out) • Gamma radiation from RDPs of radon collected. • Alphas from radon and/or RDPs from radon collected. • Ionization from radon and RDPs from radon collected. • Damage to material from alphas from radon, and RDPs from radon collected. • Alphas and betas from radon, and RDPs from radon collected.

  7. What does the Lab look for when measuring RDP’s?

  8. Radon Decay Products (WL) • Radon decay products are collected on a filter using a carefully calibrated air pump. • The lab “looks” at alpha particles released from radon decay products trapped on filter.

  9. Thoron (Radon 220) Gas Measurement Interference • Can be incorrectly measured along with radon 222. This can occur with some radon measurement devices. The device may interpret the energy released from the short half-life of thoron with the energy released from radon gas. • Thoron’s short half-life means that sniffing measurements can be affected if measured immediately on site. • Passive devices usually not affected. • Thoron interference can be corrected for.

  10. Time Characteristics ofSampling Methods

  11. Passive Integrating Radon Devices • Insert slide #9 • Activated Charcoal Device • Electret Ion Chamber • Alpha Track Detector • Liquid Scintillation

  12. Activated Charcoal Devices (AC) • Measure radon. • Different devices have different optimal deployment periods. • Used by both professionals & homeowners. • Require no power to operate. • Cannot be read in field must be read at laboratory.

  13. Activated Charcoal Device Examples

  14. Deployment

  15. Activated Charcoal DevicesSamples Radon, Results in pCi/L

  16. Open Face vs. Diffusion Barrier

  17. What does the Lab see?

  18. Activated Charcoal

  19. How Lab Analyzes Activated Charcoal Devices • Device emits gamma from RDPs from radon. • Detected by scintillation detector coupled with photo-multiplier tube.

  20. Practical Concerns About Activated Charcoal Devices • Open faced canisters are biased towards last 12 to 24 hours of measurement. Since the radon is adsorbed onto the charcoal it is possible for radon to escape before the device is sealed to be sent to the lab. • Diffusion barrier devices biased to last 2 to 3 days. • Reduce moisture in-take (diffusion barrier) or compensate for moisture in calibration. • Sensitive to air flow. • Sensitive to temperature extremes.

  21. Advantages ofActivated Charcoal Devices • Convenient and economical • Can be used for 48 hour test • Can be easily mailed to lab for analysis • Unobtrusive and make no noise • Passive, does not require power • Results can be provided very quickly

  22. Disadvantages ofActivated Charcoal Devices • Limited to short-term sampling. • Because of bias towards latter portion of sampling period, they are not true integrating devices if radon peaks and valleys are dramatic. • Provide no indication of changes in radon during measurement. Therefore, tampering detection by measurement alone is difficult.

  23. Insert slide #13

  24. Alpha Track Detectors • Records alpha particle damage from radon and radon decay products from the radon that diffuses through filter. • Lab counts damage tracks on plastic.

  25. What does the Lab see?Insert slide#22

  26. Alpha Track Detectors

  27. Types of Alpha Track Devices • Filtered (AT) • RDPs from room are filtered out. Only radon can enter chamber. Results in pCi/L. • Unfiltered (UT) This device is not commonly used in the United States. • Radon and RDPs from room enter chamber. Results are in pCi/L after E.R. is factored into calculation (usually E.R. of 0.5 is assumed.)

  28. Alpha Track DevicesMeasure Radon, Results in pCi/L • AT device: RDPs in room are filtered out. • UT device: RDPs in room are allowed in • Tracks are chemically enhanced and counted under microscope (manually or by computer). • Normal integration period: 3 months to 1 year. • Designed for long-term measurements.

  29. Characteristics ofAlpha Track Detectors • Relatively low sensitivity. • Will over-respond if exposed in turbulent air or breeze (because it is a passive device). • Alpha Tracks create a permanent record and are true integrating devices.

  30. Advantages of Alpha Track Devices • Relatively low cost • Convenient • Distributed by mail • Unobtrusive • Needs no external power • Can measure long-term characteristics

  31. Disadvantages ofAlpha Track Detectors • Long measurement period necessary • Precision errors, especially at low concentrations, if small area of chip is counted

  32. Electret Ion Chamber (EC) • Radon in device causes ionization. Ions cause electret to lose voltage.

  33. Insert slide 31 & 34

  34. Theory of EC Operation • Radon decays into RDPs, releasing alpha and gamma radiation. • RDPs from radon inside chamber continue to decay, releasing alpha, beta, and gamma radiation. • All alpha, beta, and majority of gamma radiation cause some ionization of air in chamber.

  35. Theory of EC Operation (continued…) • Electrons released during ionization process collect on electret surface, thereby reducing its positive voltage. • Resultant change in voltage is calibrated to average radon concentration for the duration of exposure.

  36. Measuring Electret Voltages • Electret voltages are measured before and after deployment. • Reported radon is a function of: • Voltage drop. • Duration of deployment. • Calibration curves used to calculate (Approx. 2 volts drop per day in room at 1 pCi/L). • Same orientation, temperature & at controlled humidity.

  37. Electret Ion Chamber-Measurement Periods • Normal integration period is 2 days to 1 year depending upon configuration, type of disk used, and anticipated radon concentration. • Can be used for short-term and long-term measurements. • Measures radon; results are in pCi/L

  38. Types of Electret Ion Chambers • Insert slide #36 • ES • Used for short-term measurements • EL • Used for long-term measurements

  39. Characteristics of ECs • Sensitive to turbulence and breezes (because it is a passive device). • Slight performance difference at higher elevations. • Affected by external gamma radiation.

  40. Advantages of ECs • Can be used for short-term and long-term measurements. • Electret can be re-used until voltage falls below the desired operating voltage for the device used.

  41. Disadvantages of ECs • Are sensitive to external gamma radiation, which should be corrected for. • Are sensitive to altitude changes, which should be corrected for. • Touching surface, surface contamination or impact can damage electret. • Measure pre/post voltages at same temperature.

  42. Charcoal Liquid Scintillation (LS) Description • Plastic or glass vial with a few grams of charcoal. • Radon diffuses through filter in cap, is absorbed onto charcoal. • Normal integration period is 2 to 7 days. • Designed for short-term measurements only. • Insert slide #41 • Measures radon; results in pCi/L.

  43. Theory of LS Operation • Radon is trapped on charcoal. • Charcoal is removed from vial and added to a second vial, which contains a liquid scintillate. • After 4 hours, alphas and betas from radon and its RDPs cause scintillate to release visible light. • Visible light pulses are counted with a PMT.

  44. Characteristics of LS Devices • The relatively low sampling rate is compensated for by the high efficiency (90%) of the counting apparatus. • Small possibility of over-response from turbulence or breezes.

  45. Advantages of LS Devices • Same as other activated charcoal devices, i.e., • Relatively low cost • Unobtrusive • Methodology can be used to measure radon in water also.

  46. Disadvantages of LS Devices • Same as for other activated charcoal devices • Limited to short-term sampling • Biased towards latter periods of exposure • Does not provide indication of changes in radon concentrations during the measurement period

  47. Grab and/or Sniffing Radon Devices • Grab sample with a scintillation cell and PMT (GS) • Continuous Radon Monitor (CR) put into sniffing mode

  48. “Sniffing” • Sniffing is when a grab sample is taken, but rather than waiting 4 hours for the collected radon to come to equilibrium with its short-lived RDPs, it is measured right after sampling. • Used as a diagnostic tool for finding entry routes. • Provides quick measurement to identify relative differences between multiple measurements.

  49. Radon Sniffing Devices • Continuous Radon Monitors (CR) can be used as sniffers. • This will be discussed in the next section.

  50. Radon Sniffing Devices-continued • It is important to note that any test lasting less than 48 hours cannot be used as a basis to determine it a mitigation system should be installed

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