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Technical and engineering provision of operating 100 MeV linac LUE-40 and beam testing of dielectric materials Arrangement of installation at electron.

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Presentation on theme: "Technical and engineering provision of operating 100 MeV linac LUE-40 and beam testing of dielectric materials Arrangement of installation at electron."— Presentation transcript:

1 Technical and engineering provision of operating 100 MeV linac LUE-40 and beam testing of dielectric materials Arrangement of installation at electron linac on energy 100MeV for beam testing of some dielectric patterns enhancement of the accelerator to improve the parameters of the electron beam (energy spectrum, stability, emittance) development of special devices for testing dielectrics Beam testing of dielectrics to study the induced activity of zirconia ceramic to study the effect of electron irradiation on  and tg  Volodymyr Kushnir

2 Main parameters of the beam : - energy of electrons up to 95 MeV; - width of energy spectrum for 70% particles 2- 3 %; - length of beam pulse 1.5  s; - pulse repetition rate up to 50 Hz; - pulse current up to 70 mA; - average current up to 6 µA; - minimum beam size at the output 3 mm A linear S-band accelerator LUE-40 consists of electron gun, injector system, two accelerating sections and ancillaries (waveguide system, water cooling system, focusing system, control and timing system, vacuum system, system of diagnostics of beam parameters etc.). RF power of linac is supplied from two S-band klystrons with maximal pulse power to 16 MW. ELECTRON LINAC LUE-40

3 The samples of nanoceramics of ZrO 2 +4%MgO and ZrO 2 +8%Y 2 O 3 have been irradiated with high energy electrons (up to 100 MeV) 2  10 16 e Gamma-spectrum of ceramic samples after irradiation ZrO 2 +8%Y 2 O 3 ZrO 2 +4%MgO 43 MeV 45 MeV 96 MeV 89 MeV

4 ZrO 2 +4%MgO or ZrO 2 +8%Y 2 O 3 ???? ZrO 2 +8%Y 2 O 3 ZrO 2 +4%MgO The use of nanoceramics ZrO 2, alloyed by MgO, results in diminishing of its activity as compared to nanoceramics, alloyed by Y 2 O 3 for considerable time (more than 20-30 days) of the radiation cooling in 2 -3 times !!! calculation experiment

5 45 MeV 89 MeV 89 Zr (Т 1/2 =3.27 days) 88 Zr (Т 1/2 =93,4 days), 95 Zr (Т 1/2 =64,02 days), 88 Y (Т 1/2 =106.65 days)

6 *We conducted preliminary experiments to detect changes in permittivity of ceramic after irradiation with electrons. We used the method of cylindrical RF cavity partially filled with dielectric. Because of the low accuracy of measurements (error to 10%) the data obtained do not allow to draw a definite conclusion about the influence of irradiation by the electrons with energy 40 -90 MeV and general charge of particles about 30  A hour (  7  10 17 electrons) on the value of permittivity. *Therefore, we decided to use most accurate resonance method for measuring with the complete filling of the resonator with dielectric. In this case determination of permittivity and tangent of the angle of dielectric losses are carried out by exact analytical expressions. Change  and tg  by electron irradiation

7 We have developed a method of coating the sample with silver. D=20 mm, h = 3mm If  =21, f 0 = 2500MHz  f 0 /   = 40 MHz

8 CuAg Coaxial RF probe ZrO 2 +4% MgO Microwave measurements non-irradiated samples were carried out. Values of the permittivity and dielectric loss tangent​​ were determined.  =25.2±0.1 tg  = (2.6±0.1)  10 -3 HP 8753C f 0 Q 0  tg 

9 To date conducted irradiation two silver coated samples by electrons with an energy of 41 MeV. The total charge on each sample is 80 µA  hour (1.8  10 18 electrons). After the "cooling" of the samples will be carried out RF measurements which give information about the effects of electron radiation on the permittivity and loss tangent.

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