Presentation is loading. Please wait.

Presentation is loading. Please wait.

V. V. Parkhomchuk, S.A. Rastigeev BINP, Novosibirsk, Russia. ION SELECTION IN ACCELERATOR MASS SPECTROMETER BINP SB RAS.

Similar presentations


Presentation on theme: "V. V. Parkhomchuk, S.A. Rastigeev BINP, Novosibirsk, Russia. ION SELECTION IN ACCELERATOR MASS SPECTROMETER BINP SB RAS."— Presentation transcript:

1 V. V. Parkhomchuk, S.A. Rastigeev BINP, Novosibirsk, Russia. ION SELECTION IN ACCELERATOR MASS SPECTROMETER BINP SB RAS

2 The BINP AMS is mainly dedicated for dating of archaeological and geological samples by measurements of the ratio between carbon isotopes. AMS can be used for many others applications.

3 isotopic abundance ratio in carbon samples 13 C/ 14 C ~10 10 The amount of 14 C for dead samples decreases through decay with a half-life of 5730 years. 12 C/ 14 C ~10 12 For modern carbon

4 Atomic and molecular isobars of radiocarbon 14 N m/dm=84000 13 CH, 12 CH 2 m/dm ~1000 (About 10 8 molecular isobars for each negative radiocarbon ion in modern samples)

5 Mass spectrum of the modern sample low energy spectrum at the exit of AMS facility 11 orders of magnitude

6 Electrostatic filterE/q Magnetic filter ME/q 2 M/q Problems: The scattering and charge exchange processes allow the unwanted particles to pass through electrostatic and magnetic filters. The ions can interact with molecules of residual gas and parts of vacuum chamber.

7 The ion extraction from the sample The rejection of the primary isotopes The beam acceleration The rejection of the isobaric ions The rare isotope counting AMS method is based on the direct rare isotope counting negative 14 N ions not stable stripping destroys molecules

8 BINP AMS facility

9 Basic features of BINP AMS facility The ion energy selection just after molecular destruction  effective filtration of the molecular fragments, because energy of fragments always less then ion energy (at this moment). The magnesium vapor target as a molecule destroyer  localized molecular destruction 2D time of flight detector  accurate recognition of each ion 1 - pressure tank, 2 - accelerator tube, 3 - cascade generator, 4 - middle energy electrostatic filter, 5 - magnesium vapors stripper, 6 - ion source, 7 - low-energy magnetic analyzer, 8- high-energy magnetic analyzer

10 recharging in accelerator tubes

11 time-of-flight detector

12 ToF spectrum at the exit of AMS a)modern sample (carbon fabric), b)“dead” sample (graphite MPG) 14 C

13 2D ToF spectrum at the exit of AMS a)modern sample (carbon fabric), b)“dead” sample (graphite MPG)

14 a) 16 O background, b) 16 O 16 O background

15 carbon background a) 13 C background, b) 12 C background

16 Without tandem terminal filter: With tandem terminal filter: The 14 N and 14 C ions energy have the same values at the exit of accelerator only after five steps recharging process. 14 N background Moreover, the magnesium vapors stripper had no the observable influence on vacuum condition

17 14 N background a)14N background for BINP AMS, b)14N background

18 SUMMARY The effective suppression of 14N background in BINP AMS is demonstrated. Shown that the influence of ion background in the measured radiocarbon concentration of 14C/12C ~ 2 * 10 -15 (graphite MPG) is insignificant.

19 Modern sample 14 C/ 12 C~10 -12 “dead” sample (graphite MPG) 14 C/ 12 C~2*10 -15 2D TOF spectrum


Download ppt "V. V. Parkhomchuk, S.A. Rastigeev BINP, Novosibirsk, Russia. ION SELECTION IN ACCELERATOR MASS SPECTROMETER BINP SB RAS."

Similar presentations


Ads by Google