Questions? 800-523-5874 | [email protected]
- Prepmaster™ Specimen Preparation Robot
- TEM Grids
- TEM Window Grids
- Omniprobe Nanomanipulation Systems
- K-kit Wet "Liquid" TEM Kit
- Specimen Mounts
- SEM Specimen Holders
- Index and Finder SEM Grids
- SEM for Forensics
- SEM Sample Preparation Station Materials
- Cryogenic Personal Protection Equipment
- Cryo Dewars & Flasks
- Cryogenic Grids & Accessories
- Cryogenic Vials & Racks
- Cooling Chambers & Ice Baths
- Prepmaster™ Specimen Preparation Robot
- Laboratory Microwave Ovens
- LYNX II Automated Tissue Processor
- EMS Poly III
- Microtomes
- Tissue Slicers
- Rapid Immersion Freezer
- Heaters & Chillers
- SEM Cooling Stage
- Glow Discharge Systems
- Sputter Coaters & Carbon Coaters
- Stages
- Freeze Dryers
- Critical Point Dryers
- Cryo-SEM Preparation System
- Specimen Transfer Systems
- Decontaminators
- Desiccators
- Centrifuges
- Dry Baths
- Stirrers, Hot Plates
- Vortexers & Magnetic Mixers
- Rotators & Rockers
- Ovens & Incubators
- Vibration Isolation
- Air Sampling
- Vacuum Pumps
EMS Technical Data Sheets
Uranyl Acetate
EMS Catalog #22400
Electron Microscopy Sciences Catalog
Measurements on 100 gram sample of Uranyl Acetate. All measurements have been done above an open bottle.
1a. Alpha (α)
<2 counts/sec using a 540 scintillation meter with AP-2 Probe
1b. Beta (β)
>500 Counts/sec using a 540El probe coupled to a GM Meter (this determines beta events and some low energy gamma events.
1c. Gamma dose Rate (energy field) (g)
Two measurements done
1. Mini monitor type R with GM Probe - This is more specific to Gamma due in fact to being constructed to accept a narrow energy range (discriminates against beta) field: 0.6mR/hr (Mainly gamma)
2. Ionization chamber DMM 95/0500 - 1/6 for total Beta and Gamma energy field 5mR/hr (g + b)
Please note that a high efficiency scintillation counter will measure many of these events, but it will say nothing about the energy field. The customer must use a dose rate meter. (You can see the difference between the energy events and gamma dose rate) A Geiger counter just will not do the job.
2. Our uranium is U235 depleted. Typical Isotopic Composition is:
U238 - 99.9%
U235 - 0.1%
Natural Uranium has two main Isotopes: U238 & U235
Natural Isotopic composition would be:
U238 - 99.3%
U235 - 0.7%
That is to say material supplied by us is Uranium depleted i.e., the U235 content is reduced from 0.7% to between 0.3 - 0.4%. Both natural and depleted Uranium, being a mixture of isotopes and daughters, will be expected to demonstrate alpha, beta and gamma activity.
Radioactive Material
The average number of atomic transformations occurring per second is termed the activity of the radioactive material.
The old, traditional, unit of activity is Curie(Ci), which is defined as 3.7 x 1010 atomic transformations per seconds. For smaller quantities the one-thousandth and one-millionth unit are used, namely the millicurie (mCi) and the microcurie (µCi).
However, by International agreement, the unit of activity is currently being changed. The new unit of activity is the becquerel (Bq) which is defined as one atomic transformation per second. Bequerel is an extremely small unit. Larger units are used, namely the kilobecqueral (1kBq = 103Bq), the megabecquerel ( 1 MBq = 106Bq), the gigabecquerel (1 GBq = 109Bq) and the tetrabecquerel (1 TBq = 1012Bq).
It may be noted that: 1 Ci = 3.7 x 1010Bq = 37GBq = 0.037TBq.
A material must have a specific activity greater than 74 bequerel per gram (Bq/g) (0.002µCi/g) or 74 kBq/kg in order to be regarded as a radioactive material.
Uranyl Acetate sold by ELECTRON MICROSCOPY SCIENCES has an activity of: U (depleted) .51µCi·gm-1 (µCi = microcuries)
Formula for conversion to Bq is: 1 Ci = 3.7 x 1010Bq
∴ for U (depleted) Specific Activity = 0.51 x 10-6 x 3.7 x 1010Bq·gm-1 = 1.887 x 104Bq·gm-1
Uranyl Acetate Specific Activity (U approx. 55%) = 1.04 x 104Bq·gm-1
∴ Uranyl Acetate will exhibit 10, 400 disintegrations/sec/gm.