Preliminary results on simulation of fast-ion instability at 3 km LBNL damping ring 21 April 2005 Pohang Accelerator Laboratory Eun-San Kim.

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Presentation transcript:

Preliminary results on simulation of fast-ion instability at 3 km LBNL damping ring 21 April 2005 Pohang Accelerator Laboratory Eun-San Kim

Main parameters of the damping ring Energy : 5 GeV Circumference : 3043 m RF voltage : MV RF frequency : 650 MHz Harmonic number : 6598 Natural emittance : nm Horizontal/vertical damping time : 19 ms/19ms Longitudianl damping time : 9.5 ms Natural bunch length : 6 mm

Beam parameters Particels per bunch : 2 x Number of bunches : 2820 Bunch spacing : 3 ns Bunches per train : 94 Bunches per gap : 16 Number of bunch trains : 30 Average current : 890 mA Ion density at bunch train : 1200/m

One cell lattice for LBNL 3km damping ring ( A. Wolski ) The lattice consists of 28 DBA cells. By SAD version

Simulation method (1)  Weak-Strong model - A weak beam of ions is expressed by macroparticles. - Only barycenter motion of strong electron beam is considered.  No effect of magnetic field. Interaction between a bunch and ions by Bassetti-Erskine formula. =30m hhh  One ionization point is considered in the ring.  All bunches are initially set to zero displacement.  New macro-ions are generated at the transverse position (x,x’,y,y’) of the bunch with a Gaussian distribution.  Incoherent motions of ions can be obtained.  Incoherent motions of electron beam can, such as emittance growth, cannot be computed.

Simulation method (2) 1 train includes 94 bunches and 16 empty buckets. 30 trains exist in the designed ring and harmonic number is Only 1 train and harmonic number of 6598 / 30 are used in our simulation. for fast simulation

Amplitude of last (94 th ) bunch in train

Exponential growth time vs vacuum pressure

Maximum amplitude of the bunches

Summary  We performed weak-strong simulations to show aspects of fast-ion instability in the 3 km LBNL DR.  Preliminary results show that we need to consider bunch by bunch feedback system to suppress the beam instability in the vacuum pressure of 0.1 nT.  Further simulations need to be performed and strong-strong simulation will be also performed to predict blow-up of beam emittance.