Nav: Home

World's next supercollider design report released

November 14, 2018

Scientists working on the Circular Electron Positron Collider (CEPC), a planned next-generation particle collider in China, released its Conceptual Design Report (CDR) on Nov. 14 in Beijing.

In a special ceremony at the 2018 CEPC workshop at the Institute of High Energy Physics (IHEP), Prof. WANG Yifang, director of the IHEP and chair of the CEPC steering committee, released the CDR to the particle physics community and the public at large.

The two-volume report contains technical details regarding the accelerator (Volume I) and the Physics & Detector (Volume II) of the project. It outlines in great detail the design options of the future collider, which would both complement and go beyond the physics of the Large Hadron Collider at CERN. The report summarizes the work accomplished in the past six years by thousands of scientists and engineers both in China and abroad.

"This is a significant milestone along the road to such an important facility for fundamental physics," said Prof. Geoffrey Taylor of University of Melbourne, chairman of the International Committee for Future Accelerators (ICFA) and the Asian Committee for Future Accelerators (ACFA).

"The CDR signifies that we have completed the basic design of the accelerator, detector and civil engineering for the whole project," said Prof. GAO Yuanning of Peking University and chair of the CEPC Institutional Board. "Now our next step will focus on the R&D of key technologies and prototypes for the CEPC."

Volume I of the report covers the design of the accelerator complex including the linear accelerator, the damp ring, the booster, and the collider. In addition, it describes the cryogenic system, the civil engineering, the radiation protection, and the auxiliary facilities. It also discusses the option to upgrade to a Super proton proton Collider (SppC).

Volume II presents the physics case for the CEPC, describes the detector concepts and their technological options, highlights the expected detector and physics performance, and discusses future plans for detector R&D and physics investigations.

"(CDR) has built the foundation for TDR (Technical Design Report) and engineering design as the next step, and a realistic timeline for construction," said Prof. George Wei-Shu Hou of National Taiwan University and chair of the Asia-Pacific High Energy Physics Panel (AsiaHEP).

"I have no doubt the international community looks forward to partnering in the development and operation of the CEPC and in the quest to better understand the basic constituents of matter," said Prof. Geoffrey Taylor.

The current two-volume CDR ("Blue Report") was preceded by the Preliminary Conceptual Design Report (Pre-CDR, "White Report"), published in March 2015, and a Progress Report ("Yellow Report") published in April 2017.

A five-year R&D period (2018-2022) will precede the construction. During this period, prototypes of key technical components will be built and the infrastructure will be established to support the manufacturing of a large number of required components.

Construction is expected to start in 2022 and be completed in 2030. According to the tentative operational plan, the CEPC will run for seven years as a Higgs factory, followed by two years as a Z factory and one year at the WW threshold. The SppC era could begin following the completion of the CEPC operation.

The CEPC is an important part of the global plan for high-energy physics research. It will support a comprehensive research program by scientists around the world. "Physicists from many countries will work together to explore the frontiers of science and technology, thus taking our understanding of the fundamental nature of matter, energy and the universe to a new level," said Prof. WANG Yifang.

About the CEPC


The discovery of the Higgs boson at CERN's Large Hadron Collider (LHC) in July 2012 created new opportunities for a large-scale accelerator. The Higgs boson is a crucial cornerstone of the Standard Model (SM). In September 2012, Chinese scientists proposed a 240-GeV Circular Electron Positron Collider (CEPC), serving two large detectors for the studies of Higgs bosons. The tunnel for such a collider could also host a Super proton proton Collider (SppC) to reach energies beyond the LHC.

The CEPC is a circular e+ e-collider located in an underground tunnel of 100-km circumference. The accelerator complex consists of a linear accelerator (Linac), a damping ring, a booster, a collider and several transport lines.

The heart of the CEPC will be a double-ring collider. Electron and positron beams will circulate in opposite directions in separate beam pipes. The CEPC booster will be located in the same tunnel above the collider with 10-GeV injection energy and extraction energy equal to the beam collision energy. Top-up injection will be used to maintain constant luminosity. The 10-GeV Linac, an injector to the booster, will be built at ground level and accelerate both electrons and positrons.

In the planned ten-year operation, the CEPC will produce over one million Higgs bosons, one hundred million W bosons, and close to one trillion Z bosons. W and Z bosons are force carriers of the weak force. Billions of bottom quarks, charm quarks and tau-leptons will also be produced in the decays of the Z bosons.
-end-
More information:

1. Download the Conceptual Design Report (Volume I: Accelerator, http://cepc.ihep.ac.cn/CEPC_CDR_Vol1_Accelerator.pdf; Volume II: Physics & Detector, http://cepc.ihep.ac.cn/CEPC_CDR_Vol2_Physics-Detector.pdf)

2. Images, videos and background information for the CEPC (http://cepc.ihep.ac.cn/)

Chinese Academy of Sciences Headquarters

Related Higgs Boson Articles:

Cosmic inflation: Higgs says goodbye to his 'little brother'
In the first moments after the Big Bang, the Universe was able to expand even billions of billions of billions of times faster than today.
Legacy of brilliant young scientist is a major leap in quantum computing
Researchers from the University of Bristol and Université Libre de Bruxelles have theoretically shown how to write programs for random circuitry in quantum computers.
A quark like no other
A University of Iowa physicist is at the forefront of the search to confirm the existence of a particle believed to give mass to all matter.
Physicists awarded funding to enhance our understanding of the universe
Theoretical physicists from the University of Plymouth have been awarded a Consolidated Grant from the Science and Technology Facilities Council to enhance our understanding of the world and the universe that surrounds us.
Physicists at Mainz University construct prototype for new component of the ATLAS detector
One of the largest projects being undertaken at the CERN research center near Geneva -- the ATLAS Experiment -- is about to be upgraded.
A fundamental theory of mass generation
A team of four theoretical physicists, Francesco Sannino from Cp3-Origins at the University of Southern Denmark, Alessandro Strumia from CERN theory division and Pisa Univ., Andrea Tesi from the Enrico Fermi Institute at the University of Chicago in US, and Elena Vigiani from Pisa University have recently published in the Journal of High Energy Physics their work
'Higgs hunter' Sally Dawson receives J.J. Sakurai Prize for Theoretical Particle Physics
Sally Dawson, a theoretical physicist at the US Department of Energy's Brookhaven National Laboratory, has been named a recipient of the 2017 J.J.
The Higgs Bison -- mystery species hidden in cave art
Ancient DNA research has revealed that Ice Age cave artists recorded a previously unknown hybrid species of bison and cattle in great detail on cave walls more than 15,000 years ago.
Wits University scientists predict the existence of a new boson
Using data from a series of experiments that led to the discovery and first exploration of the Higgs boson at the European Organization for Nuclear Research (CERN) in 2012, scientists at the High Energy Physics Group of the University of the Witwatersrand in Johannesburg predict the existence of a new boson that might aid in the understanding of dark matter in the universe.
Zika virus research at Biosecurity Research Institute aims to control, fight mosquitoes
Kansas State University is helping the fight against Zika virus through mosquito research at the Biosecurity Research Institute.

Related Higgs Boson Reading:

Best Science Podcasts 2019

We have hand picked the best science podcasts for 2019. Sit back and enjoy new science podcasts updated daily from your favorite science news services and scientists.
Now Playing: TED Radio Hour

Setbacks
Failure can feel lonely and final. But can we learn from failure, even reframe it, to feel more like a temporary setback? This hour, TED speakers on changing a crushing defeat into a stepping stone. Guests include entrepreneur Leticia Gasca, psychology professor Alison Ledgerwood, astronomer Phil Plait, former professional athlete Charly Haversat, and UPS training manager Jon Bowers.
Now Playing: Science for the People

#524 The Human Network
What does a network of humans look like and how does it work? How does information spread? How do decisions and opinions spread? What gets distorted as it moves through the network and why? This week we dig into the ins and outs of human networks with Matthew Jackson, Professor of Economics at Stanford University and author of the book "The Human Network: How Your Social Position Determines Your Power, Beliefs, and Behaviours".