QT FP Quantum Technologies for Fundamental Physics The Science & The Quantum Technologies Landscape
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QT FP Quantum Technologies for Fundamental Physics The Science & The Quantum Technologies Landscape Ian Shipsey PAAP Town Hall -- 7 January 2021 -- I. Shipsey 1
2012.7.4 discovery of Higgs boson theory:1964 design:1984 The Higgs enables atoms to exist construction:1998 PAAP Town Hall -- 7 January 2021 -- I. Shipsey 2
Detection of gravitational waves LIGO February, 2016 PAAP Town Hall -- 7 January 2021 -- I. Shipsey 4
There has never been a better time to be a particle physicist, particle astrophysicist or cosmologist! PAAP Town Hall -- 7 January 2021 -- I. Shipsey 5
Quantum 1.0 Blackbody Radiation Photo-electric Effect Quantum Mechanics Quantum Sensors and High Energy Physics -- M. Demarteau, March 28, 2019 Slide 6 PAAP Town Hall -- 7 January 2021 -- I. Shipsey 6
Quantum 1.0 Blackbody Radiation Photo-electric Effect Quantum Mechanics Exascale Computing Laser Technology Magnetic Resonance Imaging Global Positioning System Quantum Sensors and High Energy Physics -- M. Demarteau, March 28, 2019 Slide 7 PAAP Town Hall -- 7 January 2021 -- I. Shipsey 7
Quantum 2.0 l There is a growing realization that we are at the dawn of the Second Quantum Revolution. l First Quantum Revolution: exploitation of the quantum nature of matter to build devices l Second Quantum Revolution: engineering of large quantum systems; control of full quantum system at the individual level Quantum Sensors and High Energy Physics -- M. Demarteau, March 28, 2019 Slide 8 PAAP Town Hall -- 7 January 2021 -- I. Shipsey 8
Quantum 2.0 l There is a growing realization that we at the dawn of the Second Quantum Revolution. l First Quantum Revolution: exploitation of the quantum nature of matter to build devices l Second Quantum Revolution: engineering of large quantum systems to build devices using the quantum nature of matter; control of full quantum system at the individual level Satellite Relayed Quantum Network Quantum Gravity – Error Correction AI, ML on Quantum annealer Atomic clocks Phys. Rev. Lett. 120 (2018) 030501 J. High Energy Phys. 2015, 149 (2015). Nature 550 (2017) 375 Google Bristlecone 72-qubit Rigetti → 128-qubit IonQ >60-qubit Nature (564) 87 (2018) arXiv:1807.10749v3 Nature 549, 149 (2017) arXiv:1902.10171 Quantum Sensors and High Energy Physics -- M. Demarteau, March 28, 2019 Slide 10 PAAP Town Hall -- 7 January 2021 -- I. Shipsey 10
Quantum 2.0 l There is a growing realization that we at the dawn of the Second Quantum Revolution. l First Quantum Revolution: exploitation of the quantum nature of matter to build devices l Second Quantum Revolution: engineering of large quantum systems to build devices using the quantum nature of matter; control of full quantum system at the individual level Satellite Relayed Quantum Network Quantum Gravity – Error Correction AI, ML on Quantum annealer Atomic clocks Phys. Rev. Lett. 120 (2018) 030501 J. High Energy Phys. 2015, 149 (2015). Nature 550 (2017) 375 Google Bristlecone 72-qubit Rigetti → 128-qubit IonQ >60-qubit Nature (564) 87 (2018) arXiv:1807.10749v3 Nature 549, 149 (2017) arXiv:1902.10171 Quantum Sensors and High Energy Physics -- M. Demarteau, March 28, 2019 Slide 10 PAAP Town Hall -- 7 January 2021 -- I. Shipsey 11
"Nature isn't classical, dammit, and if you want to make a simulation of nature, you'd better make it quantum mechanical," Feynmann (1981). You can approximate nature with a simulation on a classical computer, but Feynman wanted a quantum computer that offers the real thing, a computer that "will do exactly the same as nature," PAAP Town Hall -- 7 January 2021 -- I. Shipsey 12
What if? Quantum Internet Quantum Artificial Neural Network Quantum Liquid Crystals Quantum Mind Interface Quantum enabled searches for dark matter Quantum Gravity PAAP Town Hall -- 7 January 2021 -- I. Shipsey 14
The Confluence l Quantum Information Science: l Promises, through control of quantum properties, to go beyond Quantum the Standard technologies offer new ways QuantumtoLimit look and deliver at the ultimate universe precision; l Enables novel, cost-effective approaches complementary to traditional HEP approaches; Quantum Sensors and High Energy Physics -- M. Demarteau, March 28, 2019 Slide 30 PAAP Town Hall -- 7 January 2021 -- I. Shipsey 20
The Confluence l High Energy Physics Particle Physics, Particle Astrophysics l In need of new & cosmology hasideas many and more sensitive unanswered instrumentation; questions l Needs precision data to guide the way. Quantum Sensors and High Energy Physics -- M. Demarteau, March 28, 2019 Slide 29 PAAP Town Hall -- 7 January 2021 -- I. Shipsey 21
The Confluence A perfect match at a perfect time! jjllllllljjjjjjjjjjjjjjjjjjjjjjjjjjjjjjjj l ASCR and OHEP were the first offices of the Office of Science to Building a science case: essential for creation of QTFP fully embrace QIS Quantum Sensors and High Energy Physics -- M. Demarteau, March 28, 2019 Slide 31 PAAP Town Hall -- 7 January 2021 -- I. Shipsey 22
The Confluence A perfect match at a perfect time! l ASCR and OHEP were the first offices of the Office of Science to Building a science case: essential for creation of QTFP fully embrace QIS Quantum Sensors and High Energy Physics -- M. Demarteau, March 28, 2019 Slide 31 PAAP Town Hall -- 7 January 2021 -- I. Shipsey 23
Building a community: essential for creation of QTFP Quantum Sensors for Fundamental Physics Community Workshop October 2018 Oxford More on community >140 from EPSRC & STFC in attendance 24 later in this talk
Quantum Technologies Public Funding Worldwide PAAP Town Hall -- 7 January 2021 -- I. Shipsey 25
UK National Quantum Technology Program (NQTP) • Phase 1 2015-2019, Phase 2 2020-24 (total investment Phase 1+2= £1B) • Phase 2 investments: • Industry led projects to drive innovation and commercialisation of QT (£173m over 6 years) • Renewal of the QT Research Hubs (£94m over 5 years) • Research training portfolio (£25m over 5 years) • Quantum Sensors for Fundamental Physics programme (£40m over 4 years) • National Quantum Computing Centre to drive development in this new technology and place us at the forefront of this field (£77m over 5 years) NQTP essential for creation of QTFP PAAP Town Hall -- 7 January 2021 -- I. Shipsey 26
technology hub with expertise in Quantum Sensors and Metrology and a network of academic and industrial partners. Oxford hosts the Networked Quantum Information Technologies Hub (NQIT) which works towards building a quantum computer demonstrator which demonstrates a networked, hybrid light-matter (e.g. ion trap) approach to quantum information processing. The Sussex Centre for Quantum Technologies has expertise in the development of atom/ion based quantum technologies. Two of the foci are ultra-precise magnetic field measurements and ultra-precision spectroscopy of atomic and molecular ions. Sussex is exploiting quantum technology for fundamental science, in particular, a system to measure changes in fundamental constants. The NPL Quantum Metrology Institute (QMI) was established in 2015 to develop and commercialise quantum technologies. RAL Space is establishing the UK’s first Quantum Space Laboratory to Submission of staging proposal Quantum Sensors for Fundamental Physics to rapidly accelerate the development and qualification of quantum technologies for use in a space environment, in collaboration with stakeholders including the European Space Agency (ESA) and STFC Opportunities Call June 2018 Principal Investigators (45) the UK Space Agency (UKSA). Funding of this proposal will greatly facilitate the development of the consortium and SPF bid. Birmingham: Newman QCD / DIS / Forward instrumentation. Nikolopoulos Light Dark Matter / Higgs Bristol: Goldstein Collider physics/instrumentation. Velthuis Instrumentation. Cambridge: Withington Quantum sensors. Gibson Flavour physics. Edinburgh: Muheim Flavour physics, instrumentation. Murphy Dark matter, nuclear physics. Glasgow: Buttar Energy Frontier. Doyle Energy Frontier. Eklund Flavour Physics. Hammond Quantum enhanced gravity sensors. O’Shea Quantum Sensors. Imperial: Araujo Dark Matter/Instruments. Buchmueller Energy frontier/BSM/DarkMatter. Hall Energy frontier/Instruments. Hassard Instruments/Technology Transfer. Sauer and Tarbutt EDM/Atom Interferometry/ultracold. Vacheret Neutrino/DarkMatter/Instruments. Vanner Quan. Optomechanics. Liverpool: Coleman Atom Interferometry. Bowcock EDMs/instrumentation/Quantum Foam. Burdin Dark Matter. Rompotis Muons/Relic neutrinos. NPL*: Gill Ultra-stable lasers & optical clocks. Green Space & Earth observation. Hao SQUIDS & microwave cryo-resonators. Lewis Quantum sensor technology. Manchester: Lancaster Precision muon physics. Additional PIs Oxford: Bortoletto Higgs/BSM/instrumentation. Konoplev Adv. acceleration techniques. Kraus Dark Matter. March-Russell and Randall $ BSM Theory. Shipsey Higgs/muons/dark energy/instruments. subsequently Sheffield & ADMX: Daw Axions/ other dark sector searches. Ryaka * (ADMX Collaboration & U. Wash.) Sussex: Calmet Gravity/Cosmology/Foundations. Dunningham Interferometry in curved spacetime. ~200 total Griffith EDM, magnetic sensors. Keller e/p mass ratio & quantum technology. UCL: Flack Tests of quantum mechanics. Ghag Dark Matter. Hesketh Precision Muon Physics. Nichol (open to all) Neutrinos osc. & astrophysical. Saakyan 0 /proton therapy. Waters 0 . Warwick: Barker Neutrino oscillation physics. Datta Quant. sensors for DM/gravity waves/testing macroscopic QM. Morley Dev. Quant. sensors/tests of quant. gravity. Ramachers 0 detector dev. PAAP Town$ Hall Table 1 Experience of the consortium members. -- 7 January denotes visitor,2021 -- I. Shipsey * denotes partner, & denotes PI 27 Case For Support STFC Reference: ST/S002227/1 Page 3 of 3 Case For Support
Quantum Sensors for Fundamental Physics and Society- Workshop #1 The workshop had four goals: #1 survey the extraordinary science opportunities and UK capabilities to exploit this science in a world-class programme #2 demonstrate to STFC, EPSRC and UKRI the immense interest in the UK in QSFP #3 Build a community around key experiments that would be funded by a future programme #4 Work with STFC &EPSRC on a bid from the UKRI Strategic Priorities Fund (a cross-council fund) for a future programme. Strategy: focus on science, partner with the quantum hubs, build a new EPSRC & STFC community. Opportunities if funded to attract to the UK and train young scientists in a multidisciplinary area Benefits:The exciting science will benefit all the partners involved: universities, labs & hubs, Leveraging the current Hubs to bring state of the art sensors to this new application, a genuinely new interdisciplinary partnership between STFC, EPSRC and other partners enabled by and well-matched to the UKRI 28 era.
Quantum Sensors for Fundamental Physics to Quamtum Technologies for Fundamental Physics The bid was made by STFC/EPSRC December 20, 2018. This requested the funding to create the new programme (£40M/ 3.5 years). The bid was successful creating the Quantum Technologies for Fundamental Physics Programme (QTFP) Feedback: The QSFP consortium has been essential to demonstrating the interdisciplinary interest & formation of a community . Without it there would have been no credible bid. In 2019 QSFP supported more than a dozen workshops that facilitated the formation of teams and the development of proto-proposals around key experiments that targeted the new programme, we also hosted a school in January 2020 We engaged with the international community who gave feedback on our ideas The QTFP call opened 9/19 closed 12/19 many excellent proposals submitted by the community 11 from QSFP and many more not associated with QSFP 29
Quantum Technologies for Fundamental Physics selected proposals: QUEST-DMC + six that were developed by the community activities supported by the STFC Opportunities Award PAAP Town Hall -- 7 January 2021 -- I. Shipsey 30
Dark Matter Searches ALPs axions sterile WIMPs neutrinos ALPs axions sterile WIMP neutrinos s field-like particle-like field-like particle-like coherent/resonant electron nuclear coherent/resonant detection electron recoil nuclear recoil detection recoil recoil 10-22 10-22 10-1810-18 10-1510-15 10-1210-12 10-910-9 1010 -6 -6 1010 -3 -3 10 0 100 10 3 103 10 106 6 109 10 9 1012 10 12 101015 15 1010 18 18 aeV aeV feV feV peVpeV neVneV µeV µeV meV meV eV eV keV keV MeV MeV GeV GeV TeV TeV PeV PeV MPlanck M Planck BH/PBHs Quantum Sensors and High Energy Physics -- M. Demarteau, March 28, 2019 Slide 37 Quantum Technologies open a new frontier on field-like dark matter PAAP Town Hall -- 7 January 2021 -- I. Shipsey 61
An oscillator (resonance) detector can accumulate the weak interactions of light dark matter over many “swings” Detection oscillator Axion wave PAAP Town Hall -- 7 January 2021 -- I. Shipsey 66
Parameter Space for General Axion Dark Matter DOE HEP BRN For Dark Matter Small Projects New Initiatives By general axion I mean any light scalar with suppressed couplings to the standard model A wide variety of quantum enhanced technologies are important PAAP Town Hall -- 7 January 2021 -- I. Shipsey 74
S S Quantum Sensors for the Hidden Sector Sheffield, Cambridge, Oxford, RHUL, Lancaster, UCL, NPL, Liverpool ADMX SQUID washer Resonant feedback test ADMX SQUID housing • A search for axions/ALPs using resonant conversion to microwave ADMX photons in high magnetic fields Microwave • Initial focus on QCD axion, mass range SQUID amplifier 25-40 eV • Collaboration with U.S. Axion Dark Matter eXperiment group, who operate the worlds most sensitive axion search, ADMX. Daresbury Lab V I I + + 50 ⌦ a ⇡ (n ± 1/4) 0 @V /@ a 50 ⌦ /2 ⇡ /2 !0 I0 ⇡ . L ⇡ 1.5 ! = !0 ( + in end )/2⇡ c ⇡ 0.4 ( x x /2) = iZx /Z0 Zx PAAP Town Hall -- 7 January 2021 -- I. Shipsey 116 Z0 50 ⌦
S S Quantum Sensors for the Hidden Sector Sheffield, Cambridge, Oxford, RHUL, Lancaster, UCL, NPL, Liverpool ADMX SQUID washer Resonant feedback test ADMX SQUID housing • A search for axions/ALPs using resonant conversion to microwave ADMX photons in high magnetic fields Microwave • Initial focus on QCD axion, mass range SQUID amplifier 25-40 eV • Collaboration with U.S. Axion Dark Matter eXperiment group, who operate the worlds most sensitive axion search, ADMX. • Beyond QTFP there is ambition in the future to build a UK high field low temperature facility in the UK . But this Daresbury Lab is not part of the currentV programme. I • See Ed Daw talkI at UK HEP Forum + + 50 ⌦ a ⇡ (n ± 1/4) 0 @V /@ a 50 ⌦ • World-leading QCD axion/ ultra- /2 ⇡ light DM searches possible in /2 !0 I0 ⇡ . L ⇡ 1.5 ! = !0 ( + in end )/2⇡ c ⇡ 0.4 ( x x /2) = iZx /Z0 Zx PAAP Town Hall -- 7 January 2021 -- I. Shipsey 117 accessible mass range(s) Z0 50 ⌦
Quantum-enhanced Interferometry Vincent Boyer (Birmingham), Animesh Datta (Warwick), Katherine Dooley (Cardiff), Hartmut Grote (Cardiff, PI), Robert Hadfield (Glasgow), Denis Martynov (Birmingham, Deputy PI) Haixing Miao (Birmingham), Stuart Reid (Strathclyde) Axion-like particle searches Enhancing ALPS @ DESY Semi-classical gravity Quantization of space time See Hartmut Grote talk at UK HEP Forum PAAP Town Hall -- 7 January 2021 -- I. Shipsey 121
A network of clocks for measuring the stability of fundamental constants 7 international G. Barontini, V. Boyer, X. Calmet, M. Chung, N. Fitch, R. Godun, J. Goldwin, institutions V. Guarrera, I. Hill, M. Keller, J. Kronjaeger, H. Margolis, C. Mow-Lowry, P. Newman, L. Prokhorov, B. Sauer, M. Schioppo, M. Tarbutt, A. Vecchio, S. Worm The aim of the consortium is to build a community that will achieve unprecedented sensitivity in testing variations of the fine structure constant, , B’ham NPL Soton Imperial and the proton-to-electron mass ratio, . This in turn will provide more stringent constraints on a wide range of fundamental and phenomenological theories beyond the Standard Model and on dark matter models. The ambition of the QSNET consortium will be enabled by a unique network that connects a number of complementary quantum clocks across the UK Clock WP Variations of fund. Constant Ion clock Yb+ (467 nm) 1 α Atomic clock Sr (698 nm) 1 Stable reference Atomic clock Cs (32.6 mm) 1 µ See Giovanni Barontini talk Highly-charged ion clock Cf15+ (618 nm) 2 α Molecular clock CaF (17 μm) 3 µ at UK HEP Forum Molecular ion clock N2+ (2.31 μm) 3 µ PAAP Town Hall -- 7 January 2021 -- I. Shipsey 122
The AION Project See Oliver Buchmueller Talk at UK HEP Forum A UK Atom Interferometer Observatory and Network to explore Ultra-Light Dark Matter and Mid-Frequency Gravitational Waves. Project executed in national partnership with UK National Quantum Technology Hub in Sensors and Timing, Birmingham, UK, and international partnership with The MAGIS Collaboration and The Fermi National Laboratory, US illustration
& collaborate with MAGIS100 in the US PAAP Town Hall -- 7 January 2021 -- I. Shipsey 127
Very light dark matter & gravitational wave detection similar when detecting Coherent effects of entire field, not single particles Add some AION projection for 10m/100m See talk of Oliver Buchmueller at UK HEP Forum PAAP Town Hall -- 7 January 2021 -- I. Shipsey 128
And in the light Dark Matter Regime Search regime highly motivatedPAAP byTown asymmetric dark matter Hall -- 7 January 2021 -- I. Shipsey 131
Team: Silke Weinfurtner talk Carlo F Barenghi (Newcastle), At UK HEP Forum Thomas Billam (Newcastle), Ruth Gregory (Durham), Gregoire Ithier (RHUL), Zoran Hadzibabic (Cambridge), Friedrich Koenig (St. Andrews), Jorma Louko (Nottingham), Ian Moss (Newcastle), Science goals: John Owers-Bradley (Nottingham), Hiranya Peiris (UCL), • Quantum vacuum: perform experiments for Andrew Pontzen (UCL), Xavier Rojas (RHUL), quantum simulation of false vacuum decay in Pierre Verlot (Nottingham), an inflationary multiverse setting Silke Weinfurtner (Nottingham). • Quantum black holes: to perform the first experiments that will allow systematic study of quantum wave-modes around quantised analogue black holes PAAP Town Hall -- 7 January 2021 -- I. Shipsey 134
Quantum Technologies for Neutrino Mass Consortium F. Deppisch1, J, Gallop2, L. Hao2, S. Hogan1, L.Li3, R. Nichol1, Y. Ramachers4, R. Saakyan1(PI), D. Waters1, S. Withington5 A collaboration of particle, atomic and solid state physicists, electronics engineers and quantum sensor experts 3-yr proposal goal: Technology demonstration for neutrino mass e AAAB7HicbVBNS8NAEJ34WetX1aOXxSJ4sSQi6LHoxWMF0xbaWDbbSbt0swm7G6GE/gYvHhTx6g/y5r9x2+agrQ8GHu/NMDMvTAXXxnW/nZXVtfWNzdJWeXtnd2+/cnDY1EmmGPosEYlqh1Sj4BJ9w43AdqqQxqHAVji6nfqtJ1SaJ/LBjFMMYjqQPOKMGiv5+JifT3qVqltzZyDLxCtIFQo0epWvbj9hWYzSMEG17nhuaoKcKsOZwEm5m2lMKRvRAXYslTRGHeSzYyfk1Cp9EiXKljRkpv6eyGms9TgObWdMzVAvelPxP6+Tmeg6yLlMM4OSzRdFmSAmIdPPSZ8rZEaMLaFMcXsrYUOqKDM2n7INwVt8eZk0L2qeW/PuL6v1myKOEhzDCZyBB1dQhztogA8MODzDK7w50nlx3p2PeeuKU8wcwR84nz+rk46U CRESDA. Atomic Source and Magnetic Trap. determination from 3H -decay ⌫¯e • Trapping ~1020 D/T atoms 3 AAAB9HicbVBNS8NAEJ34WetX1aOXxSJ4KokIeix68VjBfkATymY7aZduNnF3Uyihv8OLB0W8+mO8+W/ctjlo64OBx3szzMwLU8G1cd1vZ219Y3Nru7RT3t3bPzisHB23dJIphk2WiER1QqpRcIlNw43ATqqQxqHAdji6m/ntMSrNE/loJikGMR1IHnFGjZUCP6Qq92U27eU47VWqbs2dg6wSryBVKNDoVb78fsKyGKVhgmrd9dzUBDlVhjOB07KfaUwpG9EBdi2VNEYd5POjp+TcKn0SJcqWNGSu/p7Iaaz1JA5tZ0zNUC97M/E/r5uZ6CbIuUwzg5ItFkWZICYhswRInytkRkwsoUxxeythQ6ooMzansg3BW355lbQua55b8x6uqvXbIo4SnMIZXIAH11CHe2hAExg8wTO8wpszdl6cd+dj0brmFDMn8AfO5w9oKpKA • B-field mapping with ≲0.1ppm precision AAAB8nicbVBNS8NAEN3Ur1q/qh69LBbBU0lU0GPRS48V7AeksWy2m3bp7ibsToQS8jO8eFDEq7/Gm//GbZuDtj4YeLw3w8y8MBHcgOt+O6W19Y3NrfJ2ZWd3b/+genjUMXGqKWvTWMS6FxLDBFesDRwE6yWaERkK1g0ndzO/+8S04bF6gGnCAklGikecErCS/5hd5llfS9zMB9WaW3fnwKvEK0gNFWgNql/9YUxTyRRQQYzxPTeBICMaOBUsr/RTwxJCJ2TEfEsVkcwE2fzkHJ9ZZYijWNtSgOfq74mMSGOmMrSdksDYLHsz8T/PTyG6CTKukhSYootFUSowxHj2Px5yzSiIqSWEam5vxXRMNKFgU6rYELzll1dJ56LuuXXv/qrWuC3iKKMTdIrOkYeuUQM1UQu1EUUxekav6M0B58V5dz4WrSWnmDlGf+B8/gD925EM H • Quantum limited micro-wave electronics 3 Ultimate goal: AAAB83icbVBNS8NAEJ3Ur1q/qh69LBbBU0lU0GPRS48V7Ac0sWy2m3bp7ibsboQS8je8eFDEq3/Gm//GbZuDtj4YeLw3w8y8MOFMG9f9dkpr6xubW+Xtys7u3v5B9fCoo+NUEdomMY9VL8SaciZp2zDDaS9RFIuQ0244uZv53SeqNIvlg5kmNBB4JFnECDZW8h+zyzzzlUBNmg+qNbfuzoFWiVeQGhRoDapf/jAmqaDSEI617ntuYoIMK8MIp3nFTzVNMJngEe1bKrGgOsjmN+fozCpDFMXKljRorv6eyLDQeipC2ymwGetlbyb+5/VTE90EGZNJaqgki0VRypGJ0SwANGSKEsOnlmCimL0VkTFWmBgbU8WG4C2/vEo6F3XPrXv3V7XGbRFHGU7gFM7Bg2toQBNa0AYCCTzDK7w5qfPivDsfi9aSU8wcwx84nz/AApF7 He Neutrino mass measurement at a Tritium facility (e.g. Culham Centre for Fusion Energy) See Ruben Saakyan Goals fortalk 3 year@ UK HEP Forum proposal 135 • Trapping 1014 D-atoms in 1L tap at T = 1K, ρ~1014 cm-3 : WP2 • Mapping B-field uniformity in a trap with ≤ 1ppm precision: WP3 Pathway to 1020 T-atoms • Atomic beam line, trap and scaling up simulations: WP1 !5 1-Apr-2020 Quantum Technologies for Neutrino Mass
The QTFP community comprising the 7 projects are in the process of forming a QTFP Community Committee (two members from each project). The CC will organize the annual (or semi-annual) Community workshops where the 7 projects can present their progress, challenges and future plans. In addition, it will invite people to present new ideas as well as to cover international research happening elsewhere. There will also be an online community platform to share information, best practice and to generally help each other, and an annual school likely aligned with YETI. To further deepen our relationship with the sensing hub we are exploring common events Community Committee School Committee QSHS Ed Daw & Stafford Withington QSHS Ed Daw QI Hartmut Grote & Denis Martynov QI Hartmut Grote QSimFP Silke Weinfurtner & Ruth Gregory QSimFP Silke Weinfurtner AION Oliver Buchmueller & tbd AION Oliver Buchmueller QUEST-DMC Jocelyn Monroe (tbc) QUEST-DMC Jocelyn Monroe (tbc) & Mark Hindmarsh (tbc) QTNM Rubin Saakyan QTNM Rubin Saakyan &tbd QSNET Giovanni Barontini QSNET Giovanni Barontini & tbd Martin Bauer John Ellis Ian Shipsey Ian Shipsey PAAP Town Hall -- 7 January 2021 -- I. Shipsey 137
THE EUROPEAN STRATEGY UPDATE CALLED FOR A DETECTOR R&D ROADMAP – A TASKFORCE ON QUANTUM SENSORS & OTHER INNOVATIVE TECHNOLOGIES IS ONE OF NINE CERN HAS A NASCENT QUANTUM PROGRAMME FERMILAB HAS BEEN CHOSEN AS A DOE QUANTUM SCIENCE CENTER THE FIRST DOE REVIEW OF THE FUTURE OF THE US NATIONAL INSTRUMENTAITON PARTICLE PHYISCS RESEARCH PROGRAMME HAS IDENTIFED AN AMBITIOUS PROGRAMME OF QUANTUM SENSOR RESEARCH QUANTUM TECHNOLOGIES FOR PARTICLE PHYSICS WILL BE A PROMINENT PLAYER FOR THE NEXT SEVERAL DECADES THE ESSENTIAL INGREDIENTS THAT HAVE MADE QTFP POSSIBLE ARE: • COMPELLING SCIENCE • QUANTUM REVOLUTION 2.0 • THE NATIONAL QUANTUM TECHNOLOGY PROGRAM • A STRONG COMMUNITY AWARD LETTERS HAVE BEEN ACCEPTED BY THE SEVEN PROJECTS A UKRI PRESS RELEASE WILL APPEAR WEEK OF JANUARY 11, 2021 THERE IS EXCITING SCIENCE AHEAD! PAAP Town Hall -- 7 January 2021 -- I. Shipsey 138
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