High Power Hadron Accelerators

Jie Wei has served as FRIB Accelerator Systems Division Director and has been a professor at MSU since 2010. He obtained his B. Sc. at Tsinghua University in 1983 and Ph. D. in physics at SUNY Stony Brook in 1989. He was awarded an APS Fellow in 2003 and the first IPAC Prize in 2010 for his exceptionally creative contributions to the design, construction, and commissioning of circular accelerators, in particular RHIC, SNS, LHC, as well as the design of CSNS, and for numerous significant developments in the field of beam dynamics. He received the 2024 DOE Achievement Award and the 2026 APS Robert R. Wilson Prize For seminal contributions in the physics of high-intensity hadron accelerators, and for leadership in the development, construction, and commissioning of the world's highest power hadron accelerators, particularly the first continuous-wave superconducting linac for heavy ions above 200 MeV/nucleon. He initiated the CPHS at Tsinghua University and chairs the A-TAC for J-PARC.

Leo R. (Bob) Dalesio has worked on scientific control solutions since 1985, when he joined Los Alamos National Laboratory to develop Supervisory Control and Data Acquisition tools for the Ground Test Accelerator. This SCADA software became the Experimental Physics and Industrial Control System (EPICS). Over the years Bob has been involved in projects as a lead engineer, cost account manager, reviewer, and system architect. He has contributed to APSU, NSLSII, SNS, LCLSI and II, CEBAF, and most recently MPEX and ALSU. He is now the managing partner of Osprey DCS, providing services to successfully deliver open-source, scientific control systems.

Alberto Facco is a senior accelerator physicist, specialized in SRF LINAC technologies, at INFN Legnaro, Italy, and at FRIB (MSU, USA). He studied Nuclear Physics at the University of Padua, Italy, and started his pioneering work in low-beta, bulk niobium superconducting resonators during his postdoctoral stay at the Weizmann Institute (Rehovot, Israel) in 1987. At INFN since 1988, he led the development of Nb SRF cavities for the linacs ALPI-PIAVE at LNL and ISAC2 at TRIUMF, working also in several international linac projects such as EURISOL and IFMIF/EVEDA. Since 2001 he collaborated in the FRIB project at MSU, where he also worked as Professor and SRF Department manager, leading the linac resonators development. He served on technical advisory committees for most of the main HPHA projects worldwide, including J-PARC (Japan), RAON/RISP (Korea), SARAF (Israel) and ESS (Sweden) that he chaired.

Venkatarao (Rao) Ganni is the director of the MSU Cryogenic Initiative and a professor of accelerator physics at Michigan State University. With B. E., M. Tech., M. S., and Ph. D. degrees in mechanical engineering, he has spent more than four decades advancing helium refrigeration and large-scale cryogenic systems. Ganni began his career at Cryogenic Technologies, Inc., leading engineering efforts on commercial and custom cryogenic equipment. He later contributed to major U.S. laboratory programs, including Brookhaven, Jefferson Lab, the Superconducting Super Collider, NASA, the Spallation Neutron Source, and FRIB, covering system design, commissioning, and performance optimization. He leads MSU s collaboration with FRIB to train the next generation of cryogenic engineers. Widely recognized for technical innovation, he invented the patented floating pressure (Ganni) cycle, now used or adapted in most major U.S. helium refrigeration systems. His honors include the Samuel C. Collins Award, the White House Closing the Circle Award, and Fellowship in the Cryogenic Society of America.

Yue Hao is a professor of physics at Michigan State University and an accelerator scientist at the Facility for Rare Isotope Beams (FRIB). His research group focuses on a first-principle understanding of accelerator beam physics, with emphasis on high-intensity beam dynamics, col

Introduction.- Accelerator design and technical aspects.- Beam dynamics: intensity limiting mechanisms.- Cryogenic refrigeration.- Superconducting radiofrequency system.- Magnets.- Controls.- Other technologies for high power hadron
accelerators.- Phases of an accelerator facility.- Examples of high power accelerator facility establishment.