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How to fight collective effect limitations
With the LHC operation at 6.5 TeV and with 25 ns bunch spacing after LS1, the understanding and control of beam instabilities in 2015 has become at least as challenging as during Run 1 and a crucial point to be followed to guarantee a smooth intensity ramp up. As expected, electron cloud appeared to...
| Autores principales: | , , , , , , , , , , , , , , , , , |
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| Lenguaje: | eng |
| Publicado: |
CERN
2016
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| Materias: | |
| Acceso en línea: | http://cds.cern.ch/record/2294535 |
| _version_ | 1780956658065735680 |
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| author | Li, K Arduini, G Biancacci, N Bruce, R Buffat, X Carver, L R Hofle, W Iadarola, G Maria, R De Metral, E Papaphilipou, Y Pieloni, T Romano, A Redaelli, S Rumolo, G Salvant, B Schenk, M Tomas, R |
| author_facet | Li, K Arduini, G Biancacci, N Bruce, R Buffat, X Carver, L R Hofle, W Iadarola, G Maria, R De Metral, E Papaphilipou, Y Pieloni, T Romano, A Redaelli, S Rumolo, G Salvant, B Schenk, M Tomas, R |
| author_sort | Li, K |
| collection | CERN |
| description | With the LHC operation at 6.5 TeV and with 25 ns bunch spacing after LS1, the
understanding and control of beam instabilities in 2015 has become at least as
challenging as during Run 1 and a crucial point to be followed to guarantee a
smooth intensity ramp up. As expected, electron cloud appeared to be the
dominant instability driver during the early phases of Run 2 with multi-bunch
operation. The in-stabilities caused by electron cloud at injection limited the
speed of scrubbing and also prevented the efficient use of doublets. Later on,
at a more advanced stage of machine scrubbing, beam coupling impedance and beam-
beam effects also started to play a role, as well as their interplay with the
residual electron cloud. In this talk the main observations of beam
instabilities in the LHC during 2015 will be reviewed, highlighting the key
tools used for the their monitoring and control. Based on our present
understanding, we will then propose settings and operational procedures for
operation in 2016 as well as the required diagnostics for an improved detection
of potential instabilities. Finally, an outlook on open studies and future
potential mitigation measures will be provided. |
| id | oai-inspirehep.net-1637726 |
| institution | Organización Europea para la Investigación Nuclear |
| language | eng |
| publishDate | 2016 |
| publisher | CERN |
| record_format | invenio |
| spelling | oai-inspirehep.net-16377262019-09-30T06:29:59Zhttp://cds.cern.ch/record/2294535engLi, KArduini, GBiancacci, NBruce, RBuffat, XCarver, L RHofle, WIadarola, GMaria, R DeMetral, EPapaphilipou, YPieloni, TRomano, ARedaelli, SRumolo, GSalvant, BSchenk, MTomas, RHow to fight collective effect limitationsAccelerators and Storage RingsWith the LHC operation at 6.5 TeV and with 25 ns bunch spacing after LS1, the understanding and control of beam instabilities in 2015 has become at least as challenging as during Run 1 and a crucial point to be followed to guarantee a smooth intensity ramp up. As expected, electron cloud appeared to be the dominant instability driver during the early phases of Run 2 with multi-bunch operation. The in-stabilities caused by electron cloud at injection limited the speed of scrubbing and also prevented the efficient use of doublets. Later on, at a more advanced stage of machine scrubbing, beam coupling impedance and beam- beam effects also started to play a role, as well as their interplay with the residual electron cloud. In this talk the main observations of beam instabilities in the LHC during 2015 will be reviewed, highlighting the key tools used for the their monitoring and control. Based on our present understanding, we will then propose settings and operational procedures for operation in 2016 as well as the required diagnostics for an improved detection of potential instabilities. Finally, an outlook on open studies and future potential mitigation measures will be provided.CERNoai:inspirehep.net:16377262016 |
| spellingShingle | Accelerators and Storage Rings Li, K Arduini, G Biancacci, N Bruce, R Buffat, X Carver, L R Hofle, W Iadarola, G Maria, R De Metral, E Papaphilipou, Y Pieloni, T Romano, A Redaelli, S Rumolo, G Salvant, B Schenk, M Tomas, R How to fight collective effect limitations |
| title | How to fight collective effect limitations |
| title_full | How to fight collective effect limitations |
| title_fullStr | How to fight collective effect limitations |
| title_full_unstemmed | How to fight collective effect limitations |
| title_short | How to fight collective effect limitations |
| title_sort | how to fight collective effect limitations |
| topic | Accelerators and Storage Rings |
| url | http://cds.cern.ch/record/2294535 |
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