Frontiers of Quantum Matter On-a-Chip!

芯片上量子物质的前沿！

• 批准号: RGPIN-2019-04887
• 负责人: Gervais, Guillaume
• 金额: $ 2.48万
• 依托单位: McGill University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=714484
• 关键词: Frontiers; Quantum; Matter; Chip

Frontiers of Quantum Matter On-a-Chip! Our strategic vision is to apply designer's materials and fabrication to the grand challenge of quantum physics, to contribute to the advancement of Canadian excellence and leadership in the burgeoning field of 'tailor-made' quantum matter, and to go beyond the current existing paradigms. i) Beyond Bose and Fermi: Developing thermodynamics 'on-a-chip' [PRB 95, 201306R (2017)] and narrow-band noise measurements [PRL 120, 136801 (2018)], our group has recently measured the entropy *in absolute units* for the 5/2 fractional quantum Hall state. Over the course of this coming DG funding, we will be tackling the grand challenge of determining whether it possesses the conjectured non-abelian entropy, a clear signature of a topological state carrying non-Abelian braiding quantum statistics. ii) Beyond bulk matter: Our research group has tackled the grand challenge of Tomonaga-Luttinger liquid theory for the one-dimensional quantum liquid, and made important progress over the last few years in both an electronic [Science 343, 631 (2014)] and fluidic [Science Advances 1, e1400222 (2015)] system. Over the course of this coming DG funding cycle, we will be tackling the grand challenge of thermoelectricity in 1D (in the same electronic model system) so as to experimentally show the expected breakdown of the Wiedemann-Franz law, as well as establishing “algebraic superfluidity” in a neutral system, as envisioned early on by Haldane. iii) Beyond graphene: Our research group has gone “beyond graphene” and we have been the first (simultaneously with another team in China) to report quantum oscillations in black phosphorus, or “phosphorene” [Nature Communications 6, 7702 (2015)]. Over the course of this coming DG funding cycle, we will be tackling the grand challenge of “antimonene” (Sb) and “bismuthene” (Bi) within a transistor geometry, in an effort to establish their solid-state properties. iv) Beyond low-energy condensed matter physics: Building on years of experiences with fabrication of devices and tailoring 'quantum matter on-a-chip', over the course of this coming DG funding cycle our group will be tackling the grand challenge of finding a supersymmetric (SUSY) quantum phase by proximity coupling of a superconductor with a topological insulator, as predicted by Affleck et al. To achieve this, we propose to merge the thermodynamic measurements discussed in i) and to search for a clear thermodynamic signature of SUSY in solid state physics.

芯片上量子物质的前沿！ 我们的战略愿景是将设计师的材料和制造应用于量子物理学的巨大挑战，为加拿大在“量身定制”量子物质新兴领域的卓越和领导地位的进步做出贡献，并超越当前现有的范式。 i) 超越玻色和费米：开发“片上”热力学 [PRB 95, 201306R (2017)] 和窄带噪声测量 [PRL 120, 136801 (2018)]，我们的小组最近测量了熵 * 5/2 分数量子霍尔态的绝对单位* 在即将到来的 DG 资助过程中，我们将解决这一重大挑战。确定它是否拥有推测的非阿贝尔熵，这是携带非阿贝尔编织量子统计的拓扑状态的清晰特征。 ii) 超越大块物质：我们的研究小组已经解决了一维量子液体的 Tomonaga-Luttinger 液体理论的巨大挑战，并在过去几年中在电子 [Science 343, 631 (2014)] 方面取得了重要进展和流体 [科学进展 1, e1400222 (2015)] 系统 在即将到来的 DG 资助周期中，我们将讨论热电的巨大挑战。 1D（在同一电子模型系统中），以便通过实验展示维德曼-弗朗茨定律的预期崩溃，以及在中性系统中建立“代数超流性”，正如霍尔丹早期所设想的那样。 iii) 超越石墨烯：我们的研究小组已经“超越石墨烯”，并且我们是第一个（与中国的另一个团队同时）报告黑磷或“磷烯”中的量子振荡的人 [Nature Communications 6, 7702 (2015)]在即将到来的 DG 资助周期中，我们将讨论晶体管内“锑烯”(Sb) 和“铋烯”(Bi) 的巨大挑战。几何形状，以努力确定其固态特性。 iv) 超越低能凝聚态物理：基于多年的设备制造和定制“芯片上量子物质”的经验，在即将到来的 DG 资助周期中，我们的团队将面临巨大的挑战，即寻找正如 Affleck 等人所预测的那样，通过超导体与拓扑绝缘体的邻近耦合来实现超对称（SUSY）量子相。为了实现这一目标，我们建议合并 i）中讨论的热力学测量并寻找清晰的方法。 SUSY 在固体物理中的热力学特征。