CNS CVD Diamond S. Michimasa. Properties of diamond Extreme mechanical hardness and extreme high thermal conductivity Broad optical transparency in region.

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Presentation transcript:

CNS CVD Diamond S. Michimasa

Properties of diamond Extreme mechanical hardness and extreme high thermal conductivity Broad optical transparency in region from IR to UV Insensitive for visible light Diamond is a semiconductor (band gap = 5.47eV) and very high resistivity at room temperature (10 16  cm) No cooling and No p-n junction ⇒ Easy operation High charge carrier mobility (e: 2200/h: 1600 cm 2 /Vs) Fast rise time of detector signal High energy needed to remove carbon atom from the lattice (80 eV) Radiation hardness

Accessibility for diamond detector Diamonds materials (commercially) Single-crystal CVD diamond plate Maximum size: 5×5 mm 2, d=50,100,200,300  m (commercially) Polycrystalline CVD diamond plate Maximum size: 50×50 mm 2, d=50,100,200,300  m (commercially) Development of large size of Polycrystalline CVD DD Beam spot size : typically 20×20 mm 2 at the BigrRIPS-F3 achromatic focus ⇒ pCVD diamond can cover achromatic beam spots of BigRIPS. Signal size is determined by energy loss in the detector: ⇒ dE/dx ～ 100 keV/  m ～ 10 5 e-h/  m ( 12 N 250A MeV) Sufficient number of e-h pair can generate a clear pulse signal. ⇒ Heavier ions are more promising.

CNS diamond detectors Signals for 32-MeV 4 He beam = Energy loss equivalent for 250-MeV/u 14 N Side A Side B Side B (another side of blue) Specification Effective Area:28 mm□ Thickness: 200um Number3 pieces Time resolution30 ps (  ) Ref: S.Michimasa NIM B 317 (2013) 710.

Typical electric circuit Circuit is very simple. Care about high-frequency cables and circuits For High-rate capability, following changes will be efficient. TDC → Multi-hit TDC. QDC → Time-over-Threshold + Multi-hit TDC. inverter

Preliminary result for Xe beam (1) Detector Setup (at HIMAC) Beam Condition: 124 Xe at 95A MeV, 1M-3M ppp ※ Preamplifier is the same for light ions ( 14 N) E loss in Dia.: 124 Xe/ 14 N = /18.5 = 113 Outputs (by Oscilloscope) Dias #1 and #2 are almost completely coincidence. ⇒ Efficiency for Xe beam are almost 100%. Preamp output is frequently saturated but logic signals are correctly generated. ⇒ Beam intensity up to a few MHz will be countable. 20ns

Preliminary result for Xe beam (2) Irradiation test of 1 Mppp Detector Setup (at HIMAC) Period : 5 hours Beam intensity: 1M-3M ppp (count by Plastic) Plastic scintillator: Pulse height is reduced 1/2 - 1/3 from the initial status. Surely underestimate left-shown beam intensity. Burnt spot by beam. Diamond Detectors: Pulse height is not changed from the initial status. Leak current was increasing with irradiation (up to 15 uA). (Leak current without beam was 15nA. We do not know how much is limit for operation…)

Next step and target experiment Longer-time irradiation (at least 1 day) Simulation of BigRIPS condition. Atomic number, Beam size, Beam energy, Intensity CNS develops diamond detector for the 132 Sn(d,d’) experiment (Spokes person: S.Ota).

If You hope further information on a CNS diamond detector. Contact to S. Michimasa