dorsal/arxiv
View SchemaNumerical Studies on Locally Damped Structures
| Authors | Z. Li, N. T. Folwell, T. O. Raubenheimer |
|---|---|
| Categories | |
| ArXiv ID | physics/0009039 |
| URL | https://arxiv.org/abs/physics/0009039 |
| Journal | eConf C000821 (2000) TUA05 |
Abstract
In the JLC/NLC X-band linear collider, it is essential to reduce the long-range dipole wakefields in the accelerator structure to prevent beam break up (BBU) and emittance degradation. The two methods of reducing the long-range wakefields are detuning and damping. Detuning reduces the wakefields rapidly as the dipole modes de-cohere but, with a finite number of modes, the wakefield will grow again as the modes re-cohere. In contrast, damping suppresses the wakefields at a longer distance. There are two principal damping schemes: synchronous damping using HOM manifolds such as that used in the RDDS1 structure and local damping similar to that used in the CLIC structure. In a locally damped scheme, one can obtain almost any Q value, however, the damping can have significant effects on the accelerating mode. In this paper, we present a medium local-damping scheme where the wakefields are controlled to meet the BBU requirement while minimizing the degradations of the fundamental rf parameters. We will address the load design and pulse heating issues associated with the medium damping scheme.
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"abstract": "In the JLC/NLC X-band linear collider, it is essential to reduce the\nlong-range dipole wakefields in the accelerator structure to prevent beam break\nup (BBU) and emittance degradation. The two methods of reducing the long-range\nwakefields are detuning and damping. Detuning reduces the wakefields rapidly as\nthe dipole modes de-cohere but, with a finite number of modes, the wakefield\nwill grow again as the modes re-cohere. In contrast, damping suppresses the\nwakefields at a longer distance. There are two principal damping schemes:\nsynchronous damping using HOM manifolds such as that used in the RDDS1\nstructure and local damping similar to that used in the CLIC structure. In a\nlocally damped scheme, one can obtain almost any Q value, however, the damping\ncan have significant effects on the accelerating mode. In this paper, we\npresent a medium local-damping scheme where the wakefields are controlled to\nmeet the BBU requirement while minimizing the degradations of the fundamental\nrf parameters. We will address the load design and pulse heating issues\nassociated with the medium damping scheme.",
"arxiv_id": "physics/0009039",
"authors": [
"Z. Li",
"N. T. Folwell",
"T. O. Raubenheimer"
],
"categories": [
"physics.acc-ph"
],
"journal_ref": "eConf C000821 (2000) TUA05",
"title": "Numerical Studies on Locally Damped Structures",
"url": "https://arxiv.org/abs/physics/0009039"
},
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