DOCSLIB.ORG

Overview of Light Sources Kent Wootton SLAC National Accelerator Laboratory

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Overview of Light Sources Kent Wootton SLAC National Accelerator Laboratory SLAC-PUB-16451 Overview of Light Sources Kent Wootton SLAC National Accelerator Laboratory US Particle Accelerator School Fundamentals of Accelerator Physics 02/02/2016 University of Texas Austin, TX This work was supported in part by the Department of Energy contract DE-AC02-76SF00515. Key references • D. A. Edwards and M. J. Syphers, An Introduction to the Physics of High Energy Accelerators, Wiley, Weinheim, Germany (1993). • DOI: 10.1002/9783527617272 • H. Wiedemann, Particle Accelerator Physics, 4th ed., Springer, Heidelberg, Germany (2015). • DOI: 10.1007/978-3-319-18317-6 • E. J. N. Wilson, An Introduction to Particle Accelerators, Oxford University Press, Oxford, UK (2001). • DOI: 10.1093/acprof:oso/9780198508298.001.0001 • A. Wolski, Beam Dynamics in High Energy Particle Accelerators, Imperial College Press, London, UK (2014). • DOI: 10.1142/p899 2 Third generation storage ring light sources 1. Electron gun 2. Linac 3. Booster synchrotron 4. Storage ring • bending magnets • insertion devices 5. Beamlines 6. Endstations 3 Why use synchrotron radiation? • Wavelength-tunable • 10 eV → 100 keV • High intensity • Spatial coherence • Polarised • Pulsed h Source: lightsources.org 4 Who uses synchrotron radiation as a light source? • Touches every aspect of science • Benefits mostly outside physics • Users predominantly working in universities, national laboratories Source: Advanced Photon Source Annual Report 2014 5 Who uses SR? Imaging Absorption contrast imaging Phase contrast imaging 6 Who uses SR? Imaging X-ray fluorescence mapping 7 Who uses SR? Diffraction Protein crystallography FFT 8 The arms race – light source brilliance Brilliance/brightness = 퐹 2 4th ℬ 4휋 휀푥휀푦 3rd 1st & 2nd K. Wille, The Physics of Particle Accelerators: An Introduction, Oxford University Press, Oxford, UK (2000). J. B. Parise and G. E. Brown, Jr., Elements, 2, 37-42 (2006). 9 Light sources of the world Source: Advanced Photon Source Annual Report 2014 10 Outline – Overview of Light Sources • User requirements of synchrotron radiation • Storage ring light sources • First and second generation storage rings • FODO lattices • Insertion devices – wigglers and undulators • Third generation storage rings • Achromat lattices • Diffraction-Limited Storage Rings • Free-Electron Lasers 11 Generations of storage ring light sources 12 First generation storage ring light sources • Parasitic use of synchrotrons, storage ring colliders • Bending magnet radiation (incoherent, broadband) − 푒 + 푒 S. Doniach, et al., J. Synchrotron Radiat., 4, 380-395 (1997). 13 Particle physics discovery! • Early 1960’s – Anello di Accumulazione (AdA) collider • E = 1.5 GeV • Significant for accelerator physics, but no particle discovery • Early 1970’s – SPEAR-I • E = 4.5 GeV (maximum) • 1974 – / ( ) discovery kept machines at E = 1.55 GeV 퐽 휓 푐푐̅ Source: Brookhaven National Laboratory C. Bernardini, Phys. Perspect., 6, 156-183 (2004). S. Williams, CERN Courier, 1 Jun, 2003 (2003). 14 Parasitic users of bending magnet radiation • Critical photon energy 3 퐸 • Colliders typically want휖 maximum푐 ∝ 휌 (minimise SR power) • Bending magnet light sources want minimum (maximise SR) 휌 휌 For a given current, independent / Source: Australian Synchrotron of beam energy! 퐽 휓 H. Winick, ‘Properties of Synchrotron Radiation’, in Synchrotron Radiation Research, Springer, New York, (1980), p. 17 15 Second generation storage ring light sources • Dedicated electron storage ring light sources • Bending magnet radiation • Predominantly separated- function FODO lattices • Typically VUV, soft X-ray photon energies • Some hard X-ray rings E. Rowe and F. Mills, Part. Accel., 4, 211-227 (1973). 16 Second generation light source – beginning and end National Synchrotron Light Source – I (Brookhaven) 17 Wigglers • Electron storage ring • = 3. • For a given circumference 퐵휌 3356퐸 of bending magnets, bending radius fixed (need to bend beam by RF ) • For a given beam energy, 2휋 no flexibility in magnetic field of bending magnets E. Rowe and F. Mills, Part. Accel., 4, 211-227 (1973). 18 Wigglers ⊙ ⊗ ⊙ ⊗ ⊙ ⊗ ⊙ 19 Wigglers • Incoherent superposition of many bending magnets Source: Australian Synchrotron • Flux scales linearly with number of periods • Critical photon energy linear with magnetic field • Same as bending magnet 20 Undulators ⊙ ⊗ ⊙ ⊗ ⊙ ⊗ ⊙ ⊗ ⊙ ⊗ ⊙ 21 Undulators 휆푢 휆 = 1 + + , 2 22 휆푢 퐾 2 2 휆 2 훾 휃 = 훾 93.4 m T 푞푒 퐾 휆푢퐵 ≈ 휆푢 퐵 22 2휋휋푚푒푐 Undulator radiation • Bright odd harmonics, null even harmonics • Even harmonics don’t perfectly cancel • Non-zero emittance 2 3 4 5 6 휆 휆 휆 휆 휆 휆 • What if you want a different photon energy? 23 Tuning an undulator – deflection parameter = 1 + + 2 22 휆푢 퐾 2 2 • Assume휆 2 fixed, vary훾 휃 훾 = 93.4 휆푢 • Magnetic field or energy Envelopes 퐾 휆푢퐵 • Use permanent magnets, 퐵 훾 vary by varying gap S N S N S N S N S N S N 퐵 S N S N S N S N S N S N 24 A real undulator 25 Difference between undulators and wigglers • Fundamentally, there is no difference! = 퐾 Wiggler,휃푤 if 1 훾 퐾 ≫ ⊙ ⊗ ⊙ ⊗ ⊙ ⊗ ⊙ Undulator, if 1 퐾 ≤ ⊙ ⊗ ⊙ ⊗ ⊙ ⊗ ⊙ 26 Comparison of radiation sources Bending magnet Opening angle 1 Wiggler 휃 ≈ 훾 퐾 Undulator 휃 ≈ 훾 1 After D. Attwood, ‘Soft X-Rays and Extreme휃 ≈ Ultraviolet Radiation’, Lecture Notes, UC Berkeley (2009). 27 Center for X-Ray Optics and Advanced Light Source,푁훾 ‘X-Ray Data Booklet’, LBNL/PUB-490 Rev. 3 (2009). Third generation storage ring light sources • Dedicated storage rings designed specifically for wiggler and undulator light sources (insertion devices) 28 Lattices for light sources • Optimisation? Brilliance/brightness = 4 퐹 • Vertical emittance ideallyℬ zero2 휋 휀푥휀푦 • Practically, 0.01 • Arising from uncorrected betatron coupling with horizontal 휀푦 ≈ 휀푥 plane • Minimising equilibrium emittance is key 휀푥 29 Lattices for light sources • Equilibrium emittance scaling law / d = 2 1/ 3d 2 훾 ∮ ℋ 휌 푠 퐶푞훾 3 푥 퐶푞 2 휀 55푥 ≈ ℱ 푥 휃 = 풥 ∮ 휌= 3푠.84 × 10풥 m 32 3 ℏ푐 −13 • Scale factor퐶푞 (not flux2 ) 푚푐 ℱ 퐹 M. Sommer, Optimization of the Emittance of Electrons (Positrons) Storage Rings, Laboratoire de l'Accélérateur Linéaire, LAL/RT/83-15 (1983). 30 Lattice scale factor 퓕 2 퐶푞훾 3 Name Unit Cell 푥 Ref. 휀 ≈ ℱ 푥 휃 풥 Wiedemann (1980) FODO 1.2 (minimum)퓕 Wolski (2014) 1 TME 0.0215 Wolski (2014) 12 15 1 ≈ TAL 0.2582 Ropert (1993) 15 1 ≈ DBA 0.0646 Sommer (1981) 4 15 7 ≈ TBA 0.0502 Ropert (1993) 36 15 1 ≈ + 1 MBA Wolski (2014) 12 15 1 푀 31 푀 − What is the difference? Curly-H function = + 2 + • Minimising horizontal 2dispersion function′ ′2and its ℋ 훾푥퐷푥 훼푥퐷푥퐷푥 휋푥퐷푥 derivative in the bending magnets SPEAR-2 (FODO) SPEAR-3 (DBA) 32 Example: SPEAR-2 to SPEAR-3 2 퐶푞훾 3 • Let’s assume휀푥 ≈ ℱ both 휃rings Real machines? 풥푥 • = 1 • = 3.0 GeV ( = 5871) SPEAR-2 풥푥 • SPEAR-2, FODO lattice = 160 nm rad 퐸 훾 • FODO, 1.2 • 32 bending magnets 휀푥 = 11.ℱ25°≈ 0.196 rad SPEAR-3 • 120 nm rad = 6 nm rad 휃 ≡ • SPEAR-3, DBA lattice 휀푥 ≈ 푥 • DBA, 0.0646 Real machines휀 don’t run • 36 bending magnets at the theoretical limit! = 10°ℱ ≈ 0.175 rad • 4.5 nm rad 휃 ≡ 푥 R. Hettel,휀 ≈ et al., Design of the SPEAR-3 Light Source, SLAC-PUB-9721 (2003) 33 Theoretical emittance limit and real machines • Operating a lattice close to the theoretical limit requires strong quadrupole fields • Leads to large negative natural 퐵푦 chromaticity • Lattice has very small dispersion (deliberately) 푥 • Chromaticity compensation requires strong sextupole fields • Leads to strong third order resonances in tune space • Non-linear dynamics become the problem • Dynamic aperture becomes very small Source: Wolski, CERN-2010-004.1 (2011). • Difficult to inject off-axis and store electron beams 34 Light sources of the world Source: Advanced Photon Source Annual Report 2014 35 Future light sources • How much can the average brightness be usefully increased? • ‘Continuous’ sources (e.g. storage rings) • How much can the peak brightness be usefully increased? • Pulsed sources (e.g. linacs) 36 Diffraction-Limited Storage Rings • Optimisation of average brightness • Use insertion devices (undulators, wigglers) as light sources (not bending magnets) • Diffraction limited source emittance < 휆 • Soft X-rays, 1 nm 휀 푥 <4휋80 pm rad • Strategy is to maximise number of bending magnets 휆 ≈ → 휀푥 (separated by quadrupoles) 37 MAX-IV – a diffraction-limited storage ring 38 MAX-IV – a diffraction-limited storage ring • MBA (seven- bend achromat) • 20 unit cells • = 340 pm rad • Spatially 휀푥 coherent for > 4 nm 휆 P. Tavares, et al., J. Synchrotron Radiat., 21, 862-877 (2014). 39 3rd generation storage ring magnets, MAX-IV magnets 40 Free-electron lasers • Storage ring light sources are spontaneous sources • Photon emission is random, uncorrelated in phase • Photon emission can be stimulated Source: flash.desy.de 41 Free-electron lasers Source: Los Alamos National Accelerator Laboratory (2010). 42 Free-electron laser (SACLA, Japan) 43 Energy Recovery Linacs • The ‘hybrid car’ of accelerators • Wasteful to accelerate a beam only once and lose that energy • Accelerate a beam to full energy, use it once, and then decelerate it to recover Source: Bilderback, et al., J. the energy Phys. B: At. Mol. Opt. Phys., 38, S773-S797 (2005). • Technology test facilities • Infrared THz sources 44 Coherent synchrotron radiation • Bunch length shorter than SR wavelength? Coherent • Coherent, for wavelengths longer than Incoherent bunch • ~1 ps bunch • Far infrared “THz” source Source: http://www.lns.cornell.edu/~ib38/research.html J. Schwinger, “On Radiation by Electrons in a Betatron”, A Quantum Legacy: Seminal Papers of Julian Schwinger, World Scientific, 307-331, (2000) (LBNL-39088). 45 Summary • Desirable properties of synchrotron radiation as a light source • Historically, synchrotron radiation users parasitic • Technologies such as insertion devices developed as a result • Present day, dedicated synchrotron radiation laboratories • Light source technology developing in two main directions • Average brightness (Diffraction-Limited Storage Rings) • Peak brightness (Free-Electron Lasers) This work was supported in part by the Department of Energy contract DE-AC02-76SF00515.
Load more

Recommended publications
  • X-Ray and Optical Diagnostic Beamlines at the Australian Synchrotron Storage Ring
    Proceedings of EPAC 2006, Edinburgh, Scotland THPLS002 X-RAY AND OPTICAL DIAGNOSTIC BEAMLINES AT THE AUSTRALIAN SYNCHROTRON STORAGE RING M. J. Boland, A. C. Walsh, G. S. LeBlanc, Y.-R. E. Tan, R. Dowd and M. J. Spencer, Australian Synchrotron, Clayton, Victoria 3168, Australia. Abstract powerful diagnostic tool which will deliver data to the Two diagnostic beamlines have been designed and machine group as well as information to the machine constructed for the Australian Synchrotron Storage Ring status display for the users. [1]. One diagnostic beamline is a simple x-ray pinhole General Layout camera system, with a BESSY II style pinhole array [2], designed to measure the beam divergence, size and Fig. 1. shows the schematic layout of the XDB with a stability. The second diagnostic beamline uses an optical sketch of the expected beam profile measurement. Both chicane to extract the visible light from the photon beam diagnostic beamlines have dipole source points. The and transports it to various instruments. The end-station electron beam parameters for the source points are shown of the optical diagnostic beamline is equipped with a Table 1. for storage ring with the nominal lattice of zero streak camera, a fast ICCD camera, a CCD camera and a dispersion in the straights and assuming 1% coupling. Fill Pattern Monitor to analyse and optimise the electron Table 1: Electron beam parameters at the source points. beam using the visible synchrotron light. Parameter ODB XDB β x (m) 0.386 0.386 MOTIVATION β y (m) 32.507 32.464 The Storage Ring diagnostic beamlines were desiged to σx (μm) 99 98 serve two essential functions: σx′ (μrad) 240 241 1.
    [Show full text]
  • Colliding a Linear Electron Beam with a Storage Ring Beam* ABSTRACT
    SLAC i PUB - 4545 February 1988 WA) Colliding a Linear Electron Beam with a Storage Ring Beam* P. GROSSE- WIESMANN Stanford Linear Accelerator Center Stanford University, Stanford, California 94305 ABSTRACT We investigate the possibility of colliding a linear accelerator electron beam with a particle beam stored in a circular storage ring. Such a scheme allows e+e- colliders with a center-of-mass energy of a few hundred GeV and eP colliders with a center-of-mass energy of several TeV. High luminosities are possible for both colliders. Submitted to Nuclear Instruments & Methods * W&k supported by the Department of Energy, contract DE - A C 0 3 - 76 SF 00 5 15. 1. Introduction In order to get a better understanding of the standard model of particle physics, higher energies and higher luminosities in particle collisions are desir- able. It is generally recognized that particle collisions involving leptons have a considerable advantage for experimental studies over purely hadronic interac- tions. The initial state is better defined and cleaner event samples are achieved. Unfortunately, the center-of-mass energy and the luminosity achievable in an electron storage ring are limited. The energy losses from synchrotron radiation increase rapidly with the beam energy. Even with the largest storage rings un- der construction or under discussion the beam energy cannot be extended far beyond 100 GeV [l]. I n addition, the luminosity in a storage ring is strongly limited by the beam-beam interaction. Event rates desirable to investigate the known particles are not even available at existing storage rings. One way out of this problem is the linear collider scheme [2,3].
    [Show full text]
  • FROM KEK-PS to J-PARC Yoshishige Yamazaki, J-PARC, KEK & JAEA, Japan
    FROM KEK-PS TO J-PARC Yoshishige Yamazaki, J-PARC, KEK & JAEA, Japan Abstract target are located in series. Every 3 s or so, depending The user experiments at J-PARC have just started. upon the usage of the main ring (MR), the beam is JPARC, which stands for Japan Proton Accelerator extracted from the RCS to be injected to the MR. Here, it Research Complex, comprises a 400-MeV linac (at is ramped up to 30 GeV at present and slowly extracted to present: 180 MeV, being upgraded), a 3-GeV rapid- Hadron Experimental Hall, where the kaon-production cycling synchrotron (RCS), and a 50-GeV main ring target is located. The experiments using the kaons are (MR) synchrotron, which is now in operation at 30 GeV. conducted there. Sometimes, it is fast extracted to The RCS will provide the muon-production target and the produce the neutrinos, which are sent to the Super spallation-neutron-production target with a beam power Kamiokande detector, which is located 295-km west of of 1 MW (at present: 120 kW) at a repetition rate of 25 the J-PARC site. In the future, we are conceiving the Hz. The muons and neutrons thus generated will be used possibility of constructing a test facility for an in materials science, life science, and others, including accelerator-driven nuclear waste transmutation system, industrial applications. The beams that are fast extracted which was shifted to Phase II. We are trying every effort from the MR generate neutrinos to be sent to the Super to get funding for this facility.
    [Show full text]
  • The U.S. Department of Energy's Ten-Year-Plans for the Office Of
    U.S. DEPARTMENT OF ENERGY The U.S. Department of Energy’s Ten-Year-Plans for the Office of Science National Laboratories FY 2019 FY 2019 Annual Laboratory Plans for the Office of Science National Laboratories i Table of Contents Introduction ................................................................................................................................................................1 Ames Laboratory ........................................................................................................................................................3 Lab-at-a-Glance ......................................................................................................................................................3 Mission and Overview ............................................................................................................................................3 Core Capabilities .....................................................................................................................................................4 Science Strategy for the Future ..............................................................................................................................8 Infrastructure .........................................................................................................................................................8 Argonne National Laboratory .................................................................................................................................
    [Show full text]
  • Proposed Linac Upgrade with a SLED Cavity at the Australian Synchrotron, SLSA
    WEPMA001 Proceedings of IPAC2015, Richmond, VA, USA PROPESED LINAC UPGRRADE WITH A SLED CAVITY AT THE AUSTRALIAN SYNCHROTRON, SLSA Karl Zingre, Greg LeBlanc, Mark Atkinson, Brad Mountford, Rohan Dowd, SLSA, Clayton, Australia Christoph Hollwich, SPINNER, Westerham, Germany Abstract LINAC OVERVIEW The Australian Synchrotron Light Source has been operating successfully since 2007 and in top-up mode General Specifications since 2012, while additionally being gradually upgraded The 100 MeV 3 GHz linac structure is made of a to reach a beam availability exceeding 99 %. Considering 90 keV thermionic electron gun (GUN), a 500 MHz the ageing of the equipment, effort is required in order to subharmonic prebuncher unit (SPB), preliminimary maintain the reliability at this level. The proposed buncher (PBU), final buncher (FBU), and two 5 m upgrade of the linac with a SLED cavity has been chosen accelerating structures. The structures are powered by to mitigate the risks of single point of failure and lack of two 35 MW pulsed klystrons supplied from a pulse spare parts. The linac is normally fed from two forming network (PFN). The low level electronics independent klystrons to reach 100 MeV beam energy, include two pulsed 400W S band amplifiers to drive the and can be operated in single (SBM) or multi-bunch mode klystrons, and two 500W UHF amplifiers for the GUN (MBM). The SLED cavity upgrade will allow remote and SPB. The linac is based on the SLS/DLS design and selection of single klystron operation in SBM and was delivered by Research Instruments, formerly possibly limited MBM without degradation of beam ACCEL, the modulators subcontracted to PPT-Ampegon, energy and reduce down time in case of a klystron failure.
    [Show full text]
  • X-Ray Phase-Contrast Computed Tomography for Soft Tissue Imaging at the Imaging and Medical Beamline (IMBL) of the Australian Synchrotron
    applied sciences Article X-ray Phase-Contrast Computed Tomography for Soft Tissue Imaging at the Imaging and Medical Beamline (IMBL) of the Australian Synchrotron Benedicta D. Arhatari 1,2,3,* , Andrew W. Stevenson 1,4 , Brian Abbey 3 , Yakov I. Nesterets 4,5, Anton Maksimenko 1, Christopher J. Hall 1, Darren Thompson 4,5 , Sheridan C. Mayo 4, Tom Fiala 1, Harry M. Quiney 2, Seyedamir T. Taba 6, Sarah J. Lewis 6, Patrick C. Brennan 6, Matthew Dimmock 7 , Daniel Häusermann 1 and Timur E. Gureyev 2,5,6,7 1 Australian Synchrotron, ANSTO, Clayton, VIC 3168, Australia; [email protected] (A.W.S.); [email protected] (A.M.); [email protected] (C.J.H.); [email protected] (T.F.); [email protected] (D.H.) 2 School of Physics, The University of Melbourne, Parkville, VIC 3010, Australia; [email protected] (H.M.Q.); [email protected] (T.E.G.) 3 Department of Chemistry and Physics, La Trobe University, Bundoora, VIC 3086, Australia; [email protected] 4 CSIRO, Clayton, VIC 3168, Australia; [email protected] (Y.I.N.); [email protected] (D.T.); [email protected] (S.C.M.) 5 School of Science and Technology, University of New England, Armidale, NSW 2351, Australia 6 Faculty of Medicine and Health, University of Sydney, Sydney, NSW 2006, Australia; [email protected] (S.T.T.); [email protected] (S.J.L.); [email protected] (P.C.B.) 7 Medical Imaging & Radiation Sciences, Monash University, Clayton, VIC 3168, Australia; Citation: Arhatari, B.D.; Stevenson, [email protected] A.W.; Abbey, B.; Nesterets, Y.I.; * Correspondence: [email protected] Maksimenko, A.; Hall, C.J.; Thompson, D.; Mayo, S.C.; Fiala, T.; Abstract: The Imaging and Medical Beamline (IMBL) is a superconducting multipole wiggler-based Quiney, H.M.; et al.
    [Show full text]
  • Synchrotron Light Source
    Synchrotron Light Source The evolution of light sources echoes the progress of civilization in technology, and carries with it mankind's hopes to make life's dreams come true. The synchrotron light source is one of the most influential light sources in scientific research in our times. Bright light generated by ultra-rapidly orbiting electrons leads human beings to explore the microscopic world. Located in Hsinchu Science Park, the NSRRC operates a high-performance synchrotron, providing X-rays of great brightness that is unattainable in conventional laboratories and that draws NSRRC users from academic and technological communities worldwide. Each year, scientists and students have been paying over ten thousand visits to the NSRRC to perform experiments day and night in various scientific fields, using cutting-edge technologies and apparatus. These endeavors aim to explore the vast universe, scrutinize the complicated structures of life, discover novel nanomaterials, create a sustainable environment of green energy, unveil living things in the distant past, and deliver better and richer material and spiritual lives to mankind. Synchrotron Light Source Light, also known as electromagnetic waves, has always been an important means for humans to observe and study the natural world. The electromagnetic spectrum includes not only visible light, which can be seen with a naked human eye, but also radiowaves, microwaves, infrared light, ultraviolet light, X-rays, and gamma rays, classified according to their wave lengths. Light of Trajectory of the electron beam varied kind, based on its varied energetic characteristics, plays varied roles in the daily lives of human beings. The synchrotron light source, accidentally discovered at the synchrotron accelerator of General Electric Company in the U.S.
    [Show full text]
  • CERN Intersecting Storage Rings (ISR)
    Proc. Nat. Acad. Sci. USA Vol. 70, No. 2, pp. 619-626, February 1973 CERN Intersecting Storage Rings (ISR) K. JOHNSEN CERN It has been realized for many years that it would be possible to beams of protons collide with sufficiently high interaction obtain a glimpse into a much higher energy region for ele- rates for feasible experimentation in an energy range otherwise mentary-particle research if particle beams could be persuaded unattainable by known techniques except at enormous cost. to collide head-on. A group at CERN started investigating this possibility in To explain why this is so, let us consider what happens in a 1957, first studying a special two-way fixed-field alternating conventional accelerator experiment. When accelerated gradient (FFAG) accelerator and then, in 1960, turning to the particles have reached the required energy they are directed idea of two intersecting storage rings that could be fed by the onto a target and collide with the stationary particles of the CERN 28 GeV proton synchrotron (CERN-PS). This change target. Most of the energy given to the accelerated particles in concept for these initial studies was stimulated by the then goes into keeping the particles that result from the promising performance of the CERN-PS from the very start collision moving in the direction of the incident particles (to of its operation in 1959. conserve momentum). Only a quite modest fraction is "useful After an extensive study that included building an electron energy" for the real purpose of the experiment-the trans- storage ring (CESAR) to investigate many of the associated formation of particles, the creation of new particles.
    [Show full text]
  • Scaling Behavior of Circular Colliders Dominated by Synchrotron Radiation
    SCALING BEHAVIOR OF CIRCULAR COLLIDERS DOMINATED BY SYNCHROTRON RADIATION Richard Talman Laboratory for Elementary-Particle Physics Cornell University White Paper at the 2015 IAS Program on the Future of High Energy Physics Abstract time scales measured in minutes, for example causing the The scaling formulas in this paper—many of which in- beams to be flattened, wider than they are high [1] [2] [3]. volve approximation—apply primarily to electron colliders In this regime scaling relations previously valid only for like CEPC or FCC-ee. The more abstract “radiation dom- electrons will be applicable also to protons. inated” phrase in the title is intended to encourage use of This paper concentrates primarily on establishing scaling the formulas—though admittedly less precisely—to proton laws that are fully accurate for a Higgs factory such as CepC. colliders like SPPC, for which synchrotron radiation begins Dominating everything is the synchrotron radiation formula to dominate the design in spite of the large proton mass. E4 Optimizing a facility having an electron-positron Higgs ∆E / ; (1) R factory, followed decades later by a p,p collider in the same tunnel, is a formidable task. The CepC design study con- stitutes an initial “constrained parameter” collider design. relating energy loss per turn ∆E, particle energy E and bend 1 Here the constrained parameters include tunnel circumfer- radius R. This is the main formula governing tunnel ence, cell lengths, phase advance per cell, etc. This approach circumference for CepC because increasing R decreases is valuable, if the constrained parameters are self-consistent ∆E. and close to optimal.
    [Show full text]
  • Argonne National Laboratory
    AT A GLANCE: ARGONNE NATIONAL LABORATORY Argonne National Laboratory accelerates science and technology (S&T) to drive U.S. prosperity and security. The laboratory is recognized for seminal discoveries in fundamental science, innovations in energy technologies, leadership in scientific computing and analysis, and excellence in stewardship of national scientific user facilities. Argonne’s basic research drives advances in materials science, chemistry, physics, biology, and environmental science. In applied science and engineering, the laboratory overcomes critical technological challenges in energy and national security. The laboratory’s user facilities propel breakthroughs in fields ranging from supercomputing and AI applications for science, to materials characterization and nuclear physics, and climate science. The laboratory also leads nationwide collaborations spanning the research spectrum from discovery to application, including the Q-NEXT quantum information science center, Joint Center for Energy Storage Research, and ReCell advanced ba!ery recycling center. To take laboratory discoveries to market, Argonne collaborates actively with regional universities and companies and expands the impact of its research through innovative partnerships. FUNDING BY SOURCE HUMAN CAPITAL 3,448 FTE employees FY 2019 Costs (in $M) HEP $20 379 joint faculty Total Laboratory Operating NE $38 317 postdoctoral researchers Costs: $837* NP $30 297 undergraduate students DOE/NNSA Costs: $727 ASCR $97 224 graduate students SPP (Non-DOE/Non-DHS) 8,035 facility users Costs: $87 BES $274 FACTS NNSA 809 visiting scientists SPP as % of Total Laboratory $57 Operating Costs: 13% DHS $24 CORE CAPABILITIES DHS Costs: $24 BER $31 Accelerator S&T SPP $87 *Excludes expenditures of Advanced Computer Science, Visualization, and Data Other SC monies received from other Other DOE $23 Applied Materials Science and Engineering $65 DOE contractors and through EERE $91 Applied Mathematics joint appointments of research Biological and Bioprocess Engineering sta!.
    [Show full text]
  • X-Ray Photoelectron Spectroscopy of Hydrogen and Helium 12 February 2019
    X-ray photoelectron spectroscopy of hydrogen and helium 12 February 2019 This work demonstrated that ambient pressure X- ray photoelectron spectra of hydrogen and helium can be obtained when a bright-enough X-ray source is used, such as at the National Synchrotron Light Source II. In the case of helium gas, the spectrum shows a symmetric peak from its only orbital. In the case of hydrogen gas molecules, an asymmetric peak is observed, which is related to the different possible vibrational modes of the final state. The hydrogen X-ray beam induces photo-ejection of an electron from 2 (left) hydrogen and (right) helium . Credit: US molecule vibrational structure is evident in the H 1s Department of Energy spectrum. More information: Jian-Qiang Zhong et al. Synchrotron-based ambient pressure X-ray For the first time scientists measured the photoelectron spectroscopy of hydrogen and vibrational structure of hydrogen and helium atoms helium, Applied Physics Letters (2018). DOI: by X-rays. The results disprove the misconception 10.1063/1.5022479 that it's impossible to obtain X-ray photoelectron spectroscopy (XPS) spectra of hydrogen and helium, the two lightest elements of the Periodic Table. This was thought to be the case due to low Provided by US Department of Energy probabilities of electron ejection from these elements induced by X-rays. Unparalleled beam brightness at the National Synchrotron Light Source-II significantly increases the probability of a photon colliding with a gas atom at ambient pressures. The beamline makes it possible to use XPS to directly study the two most abundant elements in the universe.
    [Show full text]
  • Advanced Photon Source: Lighting the Way to a Better Tomorrow
    www.anl.gov www.aps.anl.gov ADVANCED PHOTON SOURCE — LIGHTING THE WAY TO A BETTER TOMORROW Frontier science serving the national interest and positively impacting nearly every aspect of our lives THE APS ENABLES RESEARCH IN NEARLY EVERY SCIENTIFIC DISCIPLINE ☐ Materials science ☐ Chemical science ☐ Environmental, geological, and planetary science ☐ Physics ☐ Polymer science ☐ Biological and life science ☐ Pharmaceutical research ☐ Nanoscale research The U.S. Department of Energy Office of Science’s (DOE-SC’s) Advanced The APS Upgrade will provide Photon Source (APS) gives scientists access to high-energy, high-brightness, researchers with a next-generation highly-penetrating x-ray beams that are ideal for studying the arrangements tool to probe structure and function of molecules and atoms, probing the interfaces where materials meet, across length, time, and energy determining the interdependent form and function of biological proteins, scales, extending the U.S. global and watching chemical processes that happen on the nanoscale. leadership in hard x-ray science for This remarkable scientific tool helps of these institutions and companies decades to come. researchers illuminate answers to invest millions of dollars to equip NOBEL PRIZE-WINNING the challenges of our world, from APS x-ray beamlines. The APS facility RESEARCH developing new forms of energy to houses x-ray-producing technologies The recipients of the 2009 Nobel sustaining our nation’s technological that comprise one of the most Prize in Chemistry published papers and economic competitiveness to complex machines in the world, on their award-worthy work based on pushing back against the ravages of the result of innovative research data collected at DOE x-ray disease.
    [Show full text]