UCL Experimental Particle Physics Consolidated Grant (2015-2019)

伦敦大学学院实验粒子物理综合资助（2015-2019）

• 批准号: ST/N000285/1
• 负责人: Ryan Nichol
• 金额: $ 624.5万
• 依托单位: University College London
• 依托单位国家: 英国
• 项目类别: Research Grant
• 财政年份: 2015
• 资助国家: 英国
• 起止时间: 2015 至 无数据
• 项目状态: 已结题
• 来源: https://gtr.ukri.org/projects?ref=ST%2FN000285%2F1
• 关键词: UCL; Experimental; Particle; Physics; Consolidated

Experimental particle physics studies extremely small sizes, or equivalently extremely high energies. We are seeking to understand the underlying nature of the physical universe in terms of fundamental forces and particles to answer the simple question: how did our universe evolve to allow life.Experiments capable of reaching these extremes of energy & size are very technically demanding. The challenges include devising precision detectors which can operate in hostile environments, particle accelerators which can collide beams at very high energies, super-sensitive detectors capable of identifying very rare decays, high-speed electronics which can read out millions of pieces of information per second & software which can analyse petabytes of data in a distributed fashion. Particle physics thereby stimulates a variety of important technological developments. This is a "consolidated grant", underpinning the base of highly skilled research & technical staff which allows UCL to lead projects at the very highest levels. It provides the support that allows the group to effectively train PhD students & young post-doctoral researchers. The science this grant will support includes:- Understanding the nature of the Higgs boson and the mechanism that gives particles mass.- Understanding why we live in a universe that is dominated by matter with only a tiny anti-matter component, in contrast to the conditions immediately following the Big Bang. We will study in detail the properties of the neutrino, which is a stable, uncharged, almost massless particle released in radioactive beta decays. The neutrino is being studied with the MINOS experiment. UCL is also completing the construction of the SuperNEMO experiment, which will search for the incredibly rare process whereby two simultaneous beta-decays occur inside the nucleus. Examining such decays will yield fundamental insights into the nature of the neutrino.- Searching for phenomena at extremely high energies, well beyond the reach of man-made accelerators like the LHC. We are searching for the interactions of ultra-high energy neutrinos in the Antarctic ice using the ANITA experiment & we will search for the exceedingly rare process whereby a muon (a heavier version of the electron) spontaneously converts into an electron and measure very precisely the interaction of a muon with a magnetic field to establish whether there are new types of interaction or if the muon has any sub-structure.- Developing new accelerator and detector technologies for future experiments. We need to build higher energy colliders, and giant detectors able to detect neutrino beams fired over large distances, as well as 10-times larger underground detectors to continue the search for rare processes. These crucial science goals require the realisation of new detectors with unprecedented performance and which can be scaled-up effectively and affordably.- Sharing the results of our work with other scientists and industry. Our accelerator and radiation measurement expertise can be applied to the fields of nuclear medicine and security. We also cooperate with instrument manufacturers in order to develop better products for our own research and for other scientific and industrial users.Some of this work is funded on other grants but is underpinned by the technical expertise that is supported by this consolidated grant. Continuity & support for the technical base in the UCL High Energy Physics Group is vital to progress the science & the benefits that it brings.

实验粒子物理学研究极小的尺寸，或相当的极高能量。我们正在寻求从基本力和粒子的角度来理解物理宇宙的基本性质，以回答一个简单的问题：我们的宇宙是如何进化到允许生命存在的。能够达到这些极端能量和尺寸的实验在技术上是非常苛刻的。这些挑战包括设计可以在恶劣环境中工作的精密探测器，可以在非常高的能量下碰撞光束的粒子加速器，能够识别非常罕见的衰变的超灵敏探测器，每秒可以读取数百万条信息的高速电子设备以及可以以分布式方式分析PB数据的软件。粒子物理学因此刺激了各种重要的技术发展。这是一个“综合补助金”，支持高技能的研究和技术人员的基础，使UCL能够在最高水平上领导项目。它提供了支持，使该集团能够有效地培养博士生和年轻的博士后研究人员。这项资助将支持的科学包括：-理解希格斯玻色子的性质和赋予粒子质量的机制。理解为什么我们生活在一个由物质主导的宇宙中，只有一个微小的反物质成分，与大爆炸后的条件形成鲜明对比。我们将详细研究中微子的性质，中微子是一种稳定、不带电、几乎没有质量的粒子，在放射性β衰变中释放出来。中微子正在用MINOS实验进行研究。UCL还完成了SuperNEMO实验的建设，该实验将寻找令人难以置信的罕见过程，即核内同时发生两次β衰变。研究这种衰变将产生对中微子性质的基本见解。寻找极高能量的现象，远远超出了大型强子对撞机等人造加速器的能力范围。我们正在使用ANITA实验寻找南极冰中超高能中微子的相互作用，我们将寻找非常罕见的过程，其中μ子（电子的较重版本）自发地转化为电子，并非常精确地测量μ子与磁场的相互作用，以确定是否有新类型的相互作用，或者μ子是否有任何子结构。为未来的实验开发新的加速器和探测器技术。我们需要建造更高能量的对撞机，能够探测远距离发射的中微子束的巨型探测器，以及10倍大的地下探测器，以继续寻找罕见的过程。这些关键的科学目标需要实现具有前所未有的性能的新探测器，并且可以有效地扩展和负担得起。与其他科学家和行业分享我们的工作成果。我们的加速器和辐射测量专业知识可应用于核医学和安全领域。我们还与仪器制造商合作，以便为我们自己的研究和其他科学和工业用户开发更好的产品。这些工作中的一些是由其他赠款资助的，但得到了这项综合赠款支持的技术专长的支持。对UCL高能物理组技术基础的连续性和支持对于推进科学及其带来的好处至关重要。

项目成果

Measurement of the multiple-muon charge ratio in the MINOS Far Detector

MINOS 远探测器中多μ子电荷比的测量

• DOI: 10.1103/physrevd.93.052017
• 发表时间: 2016
• 期刊: Physical Review D
• 影响因子: 5
• 作者: Adamson P

Precision measurement of the speed of propagation of neutrinos using the MINOS detectors

• DOI: 10.1103/physrevd.92.052005
• 发表时间: 2015-07
• 期刊: Physical Review D
• 影响因子: 5
• 作者: P. Adamson;I. Anghel;N. Ashby;A. Aurisano;G. Barr;M. Bishai;A. Blake;G. Bock;D. Bogert;R. Bumgarner;S. Cao;C. Castromonte;S. Childress;J. Coelho;L. Corwin;D. Cronin-Hennessy;J. D. Jong;A. Devan;N. Devenish;M. Diwan;C. Escobar;J. Evans;E. Falk;G. Feldman;B. Fonville;M. Frohne;H. Gallagher;R. Gomes;M. Goodman;P. Gouffon;N. Graf;R. Gran;K. Grzelak;A. Habig;S. Hahn;J. Hartnell;R. Hatcher;J. Hirschauer;A. Holin;J. Huang;J. Hylen;G. Irwin;Z. Isvan;C. James;S. Jefferts;D. Jensen;T. Kafka;S. Amcix;G. Koizumi;M. Kordosky;A. Kreymer;K. Lang;J. Ling;P. Litchfield;P. Lucas;W. A. Mann;M. Marshak;D. Matsakis;N. Mayer;A. McKinley;C. Mcgivern;M. M. Medeiros-M.;R. Mehdiyev;J. Meier;M. Messier;W. Miller;S. Mishra;S. Mitchell;S. M. Sher;C. Moore;L. Mualem;J. Musser;D. Naples;J. Nelson;H. Newman;R. Nichol;J.A.Nowak;J. O’Connor;M. Orchanian;R. Pahlka;J. Paley;T. Parker;R. Patterson;G. Pawloski;A. Perch;S. Phan-Budd;R. Plunkett;N. Poonthottathil;E. Powers;X. Qiu;A. Radovic;B. Rebel;K. Ridl;S. Romisch;C. Rosenfeld;H. Rubin;M. Sánchez;J. Schneps;A. Schreckenberger;P. Schreiner;R. Sharma;A. Sousa;N. Tagg;R. Talaga;J. Thomas;M. Thomson;X. Tian;A. Timmons;S. Tognini;R. Toner;D. Torretta;J. Urheim;P. Vahle;B. Viren;A. Weber;R. Webb;C. White;L. Whitehead;L. Whitehead;S. Wojcicki;J. Wright;V. Zhang;R. Zwaska

Constraints on large extra dimensions from the MINOS experiment

• DOI: 10.1103/physrevd.94.111101
• 发表时间: 2016-08
• 期刊: Physical Review D
• 影响因子: 5
• 作者: P. Adamson;L. Mualem;L. Mualem;H. Newman;M. Orchanian;R. Patterson

Publisher's Note: Limits on Active to Sterile Neutrino Oscillations from Disappearance Searches in the MINOS, Daya Bay, and Bugey-3 Experiments [Phys. Rev. Lett. 117, 151801 (2016)].

• DOI: 10.1103/physrevlett.117.209901
• 发表时间: 2016-11
• 期刊: Physical review letters
• 影响因子: 8.6
• 作者: P. Adamson;-Anonymous

Search for Sterile Neutrinos in MINOS and MINOS+ Using a Two-Detector Fit.

• DOI: 10.1103/physrevlett.122.091803
• 发表时间: 2017-10
• 期刊: Physical review letters
• 影响因子: 8.6
• 作者: P. Adamson;I. Anghel;I. Anghel;A. Aurisano;G. Barr;M. Bishai;A. Blake;A. Blake;G. Bock