1

報(bào)告人：Dr. Mei Ting Mak，University of Oxford

時(shí)間：12月16日（周二）10:00

單位：北京大學(xué)物理學(xué)院

地點(diǎn)：物理大樓北539教室

騰訊會(huì)議：789-354-298

2

報(bào)告人：張?chǎng)?，慕尼黑工業(yè)大學(xué)

時(shí)間：12月16日（周二）15:00

單位：清華大學(xué)物理系

地點(diǎn)：物理樓W260

摘要:

Superradiance stands as a hallmark phenomenon in collective quantum optics. I will show the unraveling of superradiant dynamics into individual quantum trajectories via homodyne detection. Remarkably, despite the presence of entanglement, these trajectories can be effectively treated as product states for describing local observables. This finding drastically simplies the complexity of superradiant phenomona and can lead to fully classcial and exact description in some scenerios, offering both analytical treatment and intuitive understanding. Furthermore, I will show that our approach extends to regimes dominated by subradiant decay. Finally, I will present a novel emergent collective behavior in waveguide QED uncovered by this trajectory-based perspective, which renders superradiance robust to strong disorders.

報(bào)告人簡(jiǎn)介:

張?chǎng)危F(xiàn)為慕尼黑工業(yè)大學(xué)博士后，本科畢業(yè)于山東大學(xué)，博士畢業(yè)于杜克大學(xué)，主要研究量子光學(xué)、開(kāi)放量子系統(tǒng)與量子多體理論。

3

報(bào)告人：賀煜，深圳國(guó)際量子研究院/合肥國(guó)家實(shí)驗(yàn)室

時(shí)間：12月17日（周三）10:00

單位：中國(guó)科學(xué)院理論物理研究所

地點(diǎn)：南樓6620

摘要:

硅基量子計(jì)算是目前比較有潛力的一類(lèi)量子計(jì)算體系。我將簡(jiǎn)單介紹硅基量子計(jì)算的背景和發(fā)展現(xiàn)狀，然后進(jìn)一步介紹硅基單原子量子計(jì)算芯片的系列技術(shù)，包括基于掃描隧道顯微鏡氫掩膜直寫(xiě)技術(shù)的單原子級(jí)別的直寫(xiě)，以及基于微波的自旋量子比特調(diào)控和射頻單電子自旋讀出技術(shù)等。進(jìn)而，我們將介紹最近基于該技術(shù)首次實(shí)現(xiàn)的多比特量子糾纏態(tài)制備、量子錯(cuò)誤探測(cè)和糾錯(cuò)、以及邏輯量子比特制備和通用邏輯門(mén)，以及在此基礎(chǔ)上首次實(shí)現(xiàn)邏輯態(tài)的量子算法演示，并最后介紹面向大規(guī)模集成量子計(jì)算的思路和探索。

報(bào)告人簡(jiǎn)介:

賀煜，深圳國(guó)際量子研究院/合肥國(guó)家實(shí)驗(yàn)室研究員，主要研究方向?yàn)榘雽?dǎo)體量子計(jì)算、量子模擬、量子芯片。為博士生導(dǎo)師，硅基量子計(jì)算團(tuán)隊(duì)帶頭人、國(guó)家特聘青年人才、《麻省理工科技評(píng)論》評(píng)選“35歲以下科技創(chuàng)新35人”、主持多項(xiàng)國(guó)家自然科學(xué)基金委、科技部和地方項(xiàng)目，工作入選“2019年全球十大量子計(jì)算實(shí)驗(yàn)”以及“2017年中國(guó)十大科技進(jìn)展新聞”。共發(fā)表30篇SCI論文，含2篇Nature，2篇Nature Photonics，2篇Nature Nanotechnology，10篇Physical Review Letters，2篇Nano Letters等，總引用5500多次，H因子22。

4

報(bào)告人：葛健，中國(guó)科學(xué)院上海天文臺(tái)

時(shí)間：12月17日（周三）15:00

單位：北京大學(xué)物理學(xué)院

地點(diǎn)：物理大樓北547教室

騰訊會(huì)議：187-565-269

5

報(bào)告人：郁海波，University of California Riverside

時(shí)間：12月18日（周三）10:00

單位：中國(guó)科學(xué)院理論物理研究所

地點(diǎn)：南樓6620

摘要:

I will begin with an overview of how cosmic structures form on small scales and how these observations provide unique insights into the nature of dark matter. I will then discuss recent tensions between observations and predictions of the standard cold dark matter framework, which suggest that dark matter may be more complex and dynamic than previously thought. I will highlight possible new-physics solutions, focusing on dark matter self-interactions, and conclude with a look at upcoming observations in the next decade that may decisively reveal the true nature of dark matter.

報(bào)告人簡(jiǎn)介:

郁海波現(xiàn)任美國(guó)加州大學(xué)河濱分校物理與天文系正教授，并擔(dān)任該校實(shí)驗(yàn)宇宙學(xué)中心常務(wù)主任。他是浙江象山人，1999年本科畢業(yè)于浙江大學(xué)，2002年在浙江大學(xué)取得碩士學(xué)位，2007年在馬里蘭大學(xué)獲得博士學(xué)位，之后曾在加州大學(xué)爾灣分校及密歇根大學(xué)從事博士后研究。他的主要研究興趣在粒子物理與天體物理的交叉領(lǐng)域，特別是在天文學(xué)觀測(cè)數(shù)據(jù)中尋找新物理的跡象。具體包括如下主題：自相互作用暗物質(zhì)、小尺度宇宙結(jié)構(gòu)形成的數(shù)值模擬和觀測(cè)、超大黑洞的形成等。近年來(lái)，他及其團(tuán)隊(duì)研究表明自相互作用暗物質(zhì)理論在從矮星系到星系團(tuán)尺度上可產(chǎn)生多樣化暗暈結(jié)構(gòu)，這對(duì)傳統(tǒng)無(wú)碰撞冷暗物質(zhì)模型在小尺度結(jié)構(gòu)問(wèn)題上的難點(diǎn)提出了重要替代思路。他發(fā)表了近100篇學(xué)術(shù)論文，被引用13000余次。

6

報(bào)告人：Ze-Xun Lin, the University of Cambridge

時(shí)間：12月18日（周四）10:30

單位：清華大學(xué)物理系

地點(diǎn)：物理樓W105

摘要:

Recent advances in moire materials and cavity quantum electrodynamics have opened new pathways to engineer correlated and topological phases of matter. In this talk, I will present two emerging directions. First, I will discuss our recent theory of Hall crystals in fractionally filled Chern bands, where a Wigner crystal of holes coexists with a topological electron fluid. Using Hartree–Fock calculations in broken-symmetry states, we identify crystalline phases whose electronic structure and transport signatures are consistent with a nontrivial Chern number and with the re-entrant anomalous Hall features observed in twisted MoTe2.Next, I will introduce a mechanism by which a time-reversal-breaking chiral cavity reshapes the exciton spectrum, driving an s-to-p orbital transition in the exciton ground state. This provides a broadly applicable route to cavity-controlled orbital and topological engineering in 2D semiconductors.

I will conclude with earlier work on nonlinear-phonon–induced control of interlayer Dzyaloshinskii–Moriya interactions.

報(bào)告人簡(jiǎn)介:

Ze-Xun Lin received his B.Sc. in Physics from Nanjing University (2013–2017) and his Ph.D. from the University of Texas at Austin (2017–2023), where he was co-supervised by Gregory Fiete and Allan MacDonald. He was a postdoctoral scholar at UCLA from 2023 to 2025 and is currently a postdoctoral researcher in the Theory of Condensed Matter group at the University of Cambridge. His research focuses on the interplay of correlation and topology in moire quantum materials, cavity-engineered exciton, quantum Hall and superconducting phases, and transport phenomena in frustrated magnetic systems such as pyrochlore spin ice.

7

報(bào)告人：Ilya Belopolski，Nanyang Technological University

時(shí)間：12月18日（周四）14:00

單位：清華大學(xué)物理系

地點(diǎn)：物理樓W105

摘要:

Weyl semimetals are crystals where electronic quasiparticles take the form of Weyl fermions. Such emergent Weyl fermions are massless, chiral and topological—potentially useful for circuit interconnects, ultrafast THz detectors and topological transistors. Despite these promising applications and a decade of intense worldwide research, our best Weyl semimetals to date are in fact basically metallic and dominated by irrelevant, conventional electrons. To solve this problem, we took a different approach—we started from the topological semiconductor Bi2Te3 and used Cr doping to introduce ferromagnetism and drive a topological phase transition to a semimetal. We observed that (Cr,Bi)2Te3 exhibits a record bulk anomalous Hall angle > 0.5 (the key figure of merit for a magnetic Weyl semimetal) along with non-metallic conductivity, sharply distinct from known Weyl materials and conventional ferromagnets. Together with theory, our experiments suggest that (Cr,Bi)2Te3 has a simple, semimetallic electronic structure composed of only two Weyl points, without irrelevant electronic states. Improving the crystalline quality should further increase the figure of merit, and could enable a richer exploration of Weyl light-matter interaction and non-linear response. Our design principle could further be broadened to analogous inversion-symmetry-breaking Weyl semimetals, robust up to room temperature, and multiferroic Weyl semimetals. The interplay of momentum-space Weyl topology with real-space magnetic structures such as skyrmions and p-wave helices offers a further rich playground for novel quantum phases of matter.

報(bào)告人簡(jiǎn)介:

As an undergraduate I developed detectors at the Laser Interferometer Gravitational Wave Observatory in Hanford, Washington (years before the binary black hole merger which won the Nobel Prize!). Then, during a year abroad at the Ecole Polytechnique in Paris I was captivated by the lectures of Antoine Georges on the quantum physics of crystals. So, I switched from astrophysics to condensed matter physics and pursued my Ph.D. at Princeton University with Zahid Hasan. I soon found myself at the frontier of the explosion of interest in Weyl semimetals, driven in part by our group’s discovery in 2015. After my Ph.D. I escaped to Tokyo to work with the renowned Yoshinori Tokura and Naoto Nagaosa, acquiring a new passion for creating quantum materials. I have been honored by the Richard L. Greene Award of the American Physical Society (2021), as well as the Spicer Young Investigator Award of SLAC (California, 2021). I am currently Nanyang Assistant Professor in the School of Electrical & Electronic Engineering at Nanyang Technological University, Singapore.

8

報(bào)告人：齊靜波，電子科技大學(xué)

時(shí)間：12月18日（周四）15:00

單位：北京大學(xué)物理學(xué)院

地點(diǎn)：物理大樓中212報(bào)告廳

摘要:

Intense terahertz (THz) pulses induce transient inversion-symmetry breaking in quantum paraelectric SrTiO3, yet the underlying mechanism remains controversial. Using fields up to ~1.1 MV/cm, we reveal spatially inhomogeneous THz-field-induced second harmonic generation (TFISH) governed by competing lattice and defect dynamics [1]. Short-lived coherent antiferrodistortive (AFD) modes suppress dipole correlations within ~5 ps, while heavily damped soft/AFD modes and a defect-induced low-frequency mode (~0.1-0.3 THz) jointly prevent long-range ferroelectric coherence in oxygen-vacancy-rich regions. Collective modes manifested by oscillatory TFISH components exhibit softening followed by hardening below a critical temperature T*~28 K, confirming transient ferroelectric order where defects are sparse. These results reconcile conflicting interpretations, establish defect-mediated competition as a central regulator of light-induced ferroelectricity, and open routes to ultrafast control of quantum materials.

報(bào)告人簡(jiǎn)介:

齊靜波，電子科技大學(xué)教授。博士畢業(yè)于美國(guó)Vanderbilt大學(xué)，先后在美國(guó)強(qiáng)磁場(chǎng)國(guó)家實(shí)驗(yàn)室和洛斯阿拉莫斯國(guó)家實(shí)驗(yàn)室從事博士后研究工作。主要從事凝聚態(tài)體系中的超快光譜和太赫茲光譜研究，聚焦于磁性、拓?fù)浜完P(guān)聯(lián)量子體系在激發(fā)態(tài)下的超快微觀動(dòng)力學(xué)過(guò)程，以及其衍生的相關(guān)太赫茲技術(shù)方面的應(yīng)用。相關(guān)研究論文發(fā)表在Phys. Rev. Lett., Nat. Commun. 等學(xué)術(shù)期刊上，主持國(guó)家自然科學(xué)基金重點(diǎn)項(xiàng)目和國(guó)家重點(diǎn)研發(fā)項(xiàng)目課題等。

9

報(bào)告人：Xiaohu Yang，上海交通大學(xué)

時(shí)間：12月18日（周四）15:30

單位：北京大學(xué)物理學(xué)院

地點(diǎn)：KIAA-auditorium

摘要:

We are entering a golden age of high-precision cosmology, driven by new-generation large-scale sky surveys (including China's CSST). Galaxy clusters, the universe's largest structures, can be used as powerful "cosmic probes" to illuminate the dominant yet invisible components of the universe: dark matter and dark energy. In this talk, I will present some of our past attempts to find and characterize the galaxy groups/clusters from both large spectroscopic and photometric redshift surveys and their applications in the galaxy formation and cosmological studies. I will also spend some time describing the recent progress of JUST, and its role in the future cluster cosmological probes.

報(bào)告人簡(jiǎn)介:

Xiaohu Yang, is currently a Distinguished Professor at Shanghai Jiao Tong University, Deputy Director of the Tsung-Dao Lee Institute, and Project Lead of the JUST program. He has been supported by the national talent programs including the National Science Fund for Distinguished Young Scholars, the Cheung Kong Scholars Program, and the National High-Level Talents Special Support Program. His research interests mainly focus on the large scale structure of the universe and galaxy formation. Within this framework, he has established the the conditional luminosity function model for galaxy formations, developed the halo-based group finder to map the cosmic web using galaxies, and initiated the ELUCID project with colleagues to reveal the evolution histories of our local universe.

10

報(bào)告人：劉進(jìn)，中山大學(xué)物理學(xué)院

時(shí)間：12月18日（周四）16:00

單位：清華大學(xué)物理系

地點(diǎn)：物理樓W101

摘要:

由單個(gè)光子和單個(gè)原子組成的腔量子電動(dòng)力學(xué)系統(tǒng)是傳統(tǒng)量子物理和現(xiàn)代量子信息技術(shù)中的基本單元之一。在半導(dǎo)體芯片上實(shí)現(xiàn)人造原子和光學(xué)微腔的耦合，可以極大地增強(qiáng)光與物質(zhì)相互作用強(qiáng)度，縮小器件尺寸，提高系統(tǒng)可擴(kuò)展性。 本報(bào)告將聚焦確定性量子點(diǎn) - 微腔耦合器件的大規(guī)模精準(zhǔn)制備。 在此基礎(chǔ)上，我們探索了固態(tài)量子光學(xué)系統(tǒng)中的新穎物理現(xiàn)象和并進(jìn)一步構(gòu)建了高性能的集成化光量子器件。

報(bào)告人簡(jiǎn)介:

劉進(jìn)，現(xiàn)任中山大學(xué)物理學(xué)院教授，博士生導(dǎo)師。2007年和2012年分別獲華南師范大學(xué)學(xué)士和丹麥科技大學(xué)博士學(xué)位。之后在丹麥科技大學(xué)、美國(guó)國(guó)家標(biāo)準(zhǔn)與技術(shù)研究所從事博士后研究工作。2016年回國(guó)任中山大學(xué)教授。

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