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[Abstract](287) HTML PDF

SPECIAL TOPIC—Principles and applications of quantum optics·COVER ARTICLE

COVER ARTICLE

Coherent manipulation of multiple ions in a room-temperature surface-electrode trap

XIE Yi, CHEN Ting, WANG Hongyang, TAO Yi, ZHANG Xin, CHEN Yan, ZHANG Jie, WU Wei, CHEN Pingxing

2025, 74 (24): 240301. doi: 10.7498/aps.74.20251454

Abstract +

The development of high-performance chip-scale ion traps is crucial for the integration and scaling of ion-trap-based quantum computers. Although cryogenic environments can greatly reduce anomalous heating, operating ion traps at room temperature remains highly attractive due to its simplicity and lower cost. This work reports significant progress in coherently controlling multiple ions confined in a custom-fabricated, room-temperature surface-electrode trap, establishing a critical foundation for advanced quantum protocols such as quantum error correction and future scalable architectures. Research objectives and methods 　This study aims to characterize a home-built chip trap and demonstrate its capabilities for multi-ion quantum logic under ambient conditions. The trap adopts a six-wire electrode design on a high-resistivity silicon substrate, with ions trapped at a height of 154 μm. A combination of Doppler cooling, electromagnetically induced transparency (EIT) cooling, and resolved-sideband cooling is used to prepare the ions in their motional ground state. Coherent manipulations are performed using both a 729 nm laser (for optical qubits between the $|\text{S}_{1/2},m_j=-1/2\rangle$ and $|\text{D}_{5/2},m_j=-3/2\rangle$ states) and microwave radiation (for qubits between the $|\text{S}_{1/2},m_j=-1/2\rangle$ and $|\text{S}_{1/2},m_j=+1/2\rangle$ states). Quantum state detection is achieved via state-dependent fluorescence by using an EMCCD camera, thereby enabling site-resolved readout. Key results 　Low room-temperature heating rates: The trap exhibits low heating rates, measured to be 0.074(8) quanta/ms in the axial direction (at 833 kHz) and 0.237(51) quanta/ms in the radial direction (at 1.3 MHz). The spectral density of electric-field noise is on the order of $10^{-13}$ ${{\rm{V}}^2 /({\rm{m}}^{2}\cdot{\rm{Hz}}})$ at trap frequencies above 500 kHz, ranking among the best for room-temperature devices. The spectral density of electric-field noise follows an approximate $f^{-2.52(22)}$ dependence, potentially influenced by external filtering circuits. High-fidelity single-ion control A single ⁴⁰Ca⁺ ion is cooled to an average phonon number of 0.04(2) in its axial motion. High-fidelity coherent operations are demonstrated: carrier Rabi oscillations using the 729 nm laser shows a single-pulse fidelity of approximately 98.98(8)%, while microwave-driven operations achieves a fidelity of 99.95(2)%. Ramsey interferometry with microwaves reveals a coherence time $T_2^*$ of 5.0(4) ms.Site-resolved multi-ion coherent control: The core achievement is the global coherent manipulation of ion chains containing up to 20 ions. The system is characterized by driving motional sideband transitions on various axial modes of 5- and 6-ion chains. The resulting Rabi oscillations, measured using site-resolved fluorescence, clearly show the collective dynamics and mode-dependent coupling strengths determined by the normalized mode eigenvectors. Furthermore, global carrier transitions are demonstrated on a two-dimensional (2D) zigzag crystal of 20 ions, confirming the ability to execute simultaneous operations on a large qubit array. Global control of 2D ion crystals Using 20 ions, a 2D zigzag crystal is formed and globally addressed using both laser and microwave drives. Laser-driven carrier transitions show strong decay due to multimode motional coupling, whereas microwave-driven oscillations remain nearly decay-free, consistent with the Lamb–Dicke parameter being negligible for microwave fields. Conclusion 　The room-temperature surface-electrode trap can support low-heating confinement, high-fidelity single- and multi-qubit operations, as well as coherent control of large ion arrays. The site-resolved observations of mode-dependent coupling highlight the potential for utilizing collective vibrational modes for selective quantum control. These results validate the trap as a robust and promising platform for medium-scale quantum information processing and quantum simulation at room temperature. Future work will focus on structural optimizations to reduce radial heating and integration with cryogenic systems to further suppress noise, ultimately advancing toward large-scale quantum computing architectures.

[Abstract](287) HTML PDF

SPECIAL TOPIC—AI + Physical Science

EDITOR'S SUGGESTION

Goal-property-guided material generation: Toward on-demand construction via inverse design of materials

LIU Zhanghe, CHEN Xinyu, ZHOU Qionghua, WANG Jinlan

2025, 74 (24): 240701. doi: 10.7498/aps.74.20250989

Abstract +

In recent years, the application of machine learning in materials science has significantly accelerated the discovery of new materials. In particular, when combined with traditional methods such as first-principles calculations, machine learning models have proven effective in screening potential high-performance materials from existing databases. However, these methods are largely limited by the known chemical spaces, making it difficult to achieve the active design of novel material structures. To overcome this limitation, generative models have become a promising tool for inverse material design, providing new avenues for exploring unknown structures and property spaces. Although existing generative models have achieved initial progress in crystal structure generation, achieving property-guided material generation remains a significant challenge. In this review paper, we first introduce the representative generative models recently applied to materials generation, including CDVAE, MatGAN, and MatterGen, and analyzes their basic abilities and limitations in structural generation. We then focus on strategies for incorporating target properties into generative models to generate the property-guided structure. Specifically, we discuss four representative methods: Con-CDVAE based on target property vectors, SCIGEN with integrated structural constraints and guidance mechanisms, a fine-tuned version of MatterGen leveraging adapter-based property control, and a CDVAE latent space optimization strategy guided by property objectives. Finally, we summarize the key challenges faced by property-guided generative models and provide an outlook on future research directions. This review aims to offer researchers a systematic reference and inspiration for advancing property-driven generative approaches in material design and provides researchers with a systematic reference and insight into the advancement of property-driven generative methods for materials design.

[Abstract](287) HTML PDF

SPECIAL TOPIC—Semiconductor physics and devices

EDITOR'S SUGGESTION

Customizing two-dimensional heterojunction with novel luminescenct anisotropy using van der Waals engineering

WEN Ting, SU Ziluo, WANG Yalan, CAI Shuang, WU Jiaqi, QIN Jiaze, JIAO Chenyin, WANG Zenghui, ZHANG Zejuan, PEI Shenghai, XIA Juan

2025, 74 (24): 241302. doi: 10.7498/aps.74.20251120

Abstract +

Luminescence and anisotropy in two-dimensional (2D) materials have important implications for both fundamental material physics and potential applications such as polarized light-emitting devices. However, many natural-occuring 2D materials typically exhibit either luminescence or anisotropy, but not both. In this work, we utilize van der Waals (vdW) engineering to construct a heterostructure (HS) with anisotropic luminescent properties, which is composed of isotropic monolayer (1L) MoS₂ (with strong intrinsic luminescence) and low-symmetry NbIrTe₄ (strong anisotropy without photoluminescence). Experimentally, we characterize the optical response of the HS by using angle-resolved PL spectroscopy. The results indicate that the intrinsic anisotropic potential field of NbIrTe₄ at the interface effectively breaks the in-plane isotropic symmetry of MoS₂, inducing a pronounced polarization-dependent emission of A and B excitons. The anisotropy ratio is enhanced to ~1.58, corresponding to a linear polarization degree of approximately 22%. This work provides new insights into 2D interfacial coupling and offers useful guidance for the design and engineering of next-generation high-performance, tunable polarized light-emitting devices.

[Abstract](287) HTML PDF

SPECIAL TOPIC—Atomic, molecular and materials properties data

EDITOR'S SUGGESTION

Single charge transfer cross sections of He⁺-H₂O collisions

ZHANG Yu, ZHU Yayan, QI Yueying, QU Yizhi, YU Wandong

2025, 74 (24): 243101. doi: 10.7498/aps.74.20251230

Abstract +

The charge transfer cross sections of collisions between He ions in the solar wind and H₂O molecule constitute essential data required for the astrophysical plasma modeling. However, experimental measurements of single charge transfer (SCT) cross sections for He⁺-H₂O collisions at low-to-intermediate energies (corresponding to the velocity range of the solar wind) are extremely scarce, and first-priciple theoretical calculations have not been conducted. In this study, employing the time-dependent density functional theory nonadiabatically coupled with the molecular dynamics, the SCT cross sections are calculated for He⁺-H₂O collisions over a broad energy range of 1.33–1800 keV. An inverse collision framework is used to investigate the charge transfer dynamics and electron-ion coupling processes. It is found that the SCT cross section exhibits a strong dependence on the molecular orientation. Furthermore, there are significant differences in the contributions of different molecular orientations to the cross section between low-energy and high-energy regions. The computed cross section results show good agreement with the existing data obtained from experiments and classical theoretical models. This indicates that the present theoretical method and numerical framework are not only applicable to handling the charge transfer processes in collisions between dressed ions and molecules but also enable the quantitative analysis of the effect of molecular orientation on the cross section. This study lays a foundation for cross section calculations of complex collision systems. The datasets presented in this paper are openly available at https://doi.org/10.57760/sciencedb.j00213.00193.

[Abstract](287) HTML PDF

SPECIAL TOPIC—Atomic, molecular and materials properties data

EDITOR'S SUGGESTION

Research progress and data assessment of shear viscosity under extreme conditions of warm and hot dense matters

CHENG Yuqing, LIU Haifeng, LI Qiong, WANG Shuaichuang, WANG Lifang, FANG Jun, GAO Xingyu, SUN Bo, SONG Haifeng, WANG Jianguo

2025, 74 (24): 245101. doi: 10.7498/aps.74.20250861

Abstract +

The viscosities of matters under extreme conditions, i.e. warm dense matter (WDM) and hot dense matter (HDM), have significant applications in various fields, such as the design of inertial confinement fusion targets, the astrophysical structure evolution, and the interfacial instability and mixing development under extreme conditions. Since the temperature and pressure ranges accessible by experimental techniques for viscosity measurement are very limited, the acquisition of viscosity data under extreme conditions mainly relies on theoretical calculations. This work introduces a variety of molecular dynamics (MD) methods and models for calculating the viscosities of WDM and HDM, they being quantum MD (QMD), orbital-free MD (OFMD), average atom model combined with hypernetted chain (AAHNC), effective potential theory combined with average atom model (EPT+AA), hybrid kinetics MD (KMD), integrated Yukawa viscosity model (IYVM), Stanton-Murillo transport model (SMT), pseudo-ion in jellium (PIJ), one-component plasma model (OCP), and random-walk shielding-potential viscosity model (RWSP-VM). Simultaneously, the viscosities of various elements obtained by these methods are shown, ranging from low to high atomic number (Z), i.e., H, C, Al, Fe, Ge, W, and U. The accuracy and the applicability of each method are analyzed in detail by comparison. RWSP-VM, which is based on physical modeling and independent of MD data, has comparable accuracy to simulation data over a wide range of temperature and pressure, and is an efficient method of obtaining viscosity data of WDM and HDM. This work will pave the way for calculating the shear viscosities under extreme conditions, and may play an important role in promoting the relevant applications. The data calculated from RWSP-VM in this work are openly available at https://doi.org/10.57760/sciencedb.j00213.00180.

[Abstract](287) HTML PDF

SPECIAL TOPIC—Atomic, molecular and materials properties data

EDITOR'S SUGGESTION

Influence of alloying elements on the thermodynamic and elastic properties of palladium based alloys and database construction

ZHU Hanyu, CHONG Xiaoyu, GAO Xingyu, WU Haijun, LI Zulai, FENG Jing, SONG Haifeng

2025, 74 (24): 246201. doi: 10.7498/aps.74.20251058

Abstract +

The lower friction coefficient and superior mechanical properties of palladium (Pd) alloys make them potentially advantageous for use in high-precision instruments and devices that require long-term stable performance. However, the high cost of raw materials and experimental expenses result in a lack of fundamental data, which hinders the design of high-performance Pd alloys. Therefore, in this study, first-principles calculations are used to determine the lattice constant and elastic modulus of Pd. A model of dilute solid solutions formed by Pd with 33 alloying elements including Al, Si, Sc, Ti, V, Cr, Mn, Fe, Co, Ni, and others, is established. The mixing enthalpy, elastic constant, and elastic modulus are calculated. The results show that, all other alloying elements except for Mn, Fe, Co, Ni, Ru, Rh, Os, and Ir can form solid solutions with Pd. Alloying elements from both sides of the periodic table enhance the ductility of Pd solid solutions, with La, Ag, and Zn having the most significant effects, while Cu and Hf reduce the ductility of Pd. Differential charge density analysis indicates that the electron cloud formed after doping with Ag is spherically distributed, thereby improving ductility. After doping with Hf, the degree of delocalization around the atoms is maximized, indicating a strong ionic bond between Hf and Pd, which results in a higher hardness of Pd₃₁Hf. The datasets presented in this paper are openly available at https://www.doi.org/10.57760/sciencedb.j00213.00186.

[Abstract](287) HTML PDF

SPECIAL TOPIC—Instrumentation and metrology for ultrafast atomic and molecular spectroscopy

EDITOR'S SUGGESTION

Attosecond coincidence interferometer and measurement of attosecond photoelectron ionization time delay in atomic, molecular and cluster systems

WANG Xuhan, OU Xianbin, GONG Xiaochun

2025, 74 (24): 243202. doi: 10.7498/aps.74.20251166

Abstract +

The evolution mechanisms of electrons in isolated atoms, molecules and complex systems on a natural time-scale have long been a fundamental question in atomic and molecular physics, with significant implications for the applications of quantum materials. Over the past two decades, the development of attosecond light pulses and attosecond metrology has opened new opportunities for investigating the electronic dynamics, while also posing new challenges. Traditional detection techniques, such as time-of-flight and velocity map imaging spectrometers, can be used to study the attosecond scattering phase shifts in the photoemission and ionization processes with extremely high temporal and energy resolution. However, the limitations in multi-particle coincidence detection and three-dimensional momentum correlation limit the deeper exploration of many-body correlations and non-adiabatic ultrafast dynamics involving electron-nuclear coupling. To enable multidimensional and real-time observation of the three-dimensional momenta of both electrons and ions during photoionization, the attosecond interferometry has been integrated into electron-ion coincidence systems. In this study, we utilize an attosecond coincidence interferometer that combines an attosecond pump-infrared femtosecond probe scheme with cold target recoil ion momentum spectroscopy. The apparatus enables attosecond-time-resolved momentum imaging of all charged fragments in atomic and molecular systems, thereby providing deeper insights into the dynamics of photoionization. We also highlight the recent groundbreaking applications and advances of attosecond coincidence interferometer in studying photoionization dynamics in atoms, molecules, and more complex systems.

[Abstract](287) HTML PDF

SPECIAL TOPIC—Instrumentation and metrology for ultrafast atomic and molecular spectroscopy

EDITOR'S SUGGESTION

Composite velocity imaging spectrometer on Shanghai soft X-ray free electron laser facility

LIAO Jianfeng, FENG Yunfei, WU Kefei, TAO Jianfei, ZHU Wentao, HUANG Jianye, DING Bocheng, LIU Xiaojing

2025, 74 (24): 243203. doi: 10.7498/aps.74.20251176

Abstract +

Temporal- and angular-resolved photoionization experiments are essential for probing the geometric configuration and electronic state evolution of atoms and molecules, which requires measuring the full spatial angular distributions of electrons and ions in free electron laser (FEL) experiments. Here, we present the first experimental results from the composite velocity imaging spectrometer (CpVMI) on the Shanghai soft X-ray free electron laser facility (SXFEL). The study demonstrates its ability to capture energy and angular information of electrons and ions with high resolution and full solid-angle collection.Krypton (Kr) atoms and carbon tetrachloride (CCl₄) molecules are ionized using FEL pulses at 263.8 eV. Electron momentum images are recorded with an Andor Zyla 4.2 PLUS camera, and ion time-of-flight mass spectra and momentum distributions are acquired using a TPX3CAM. For Kr, the electron spectrum contains peaks from 3p, 3d, and 4p photoionization, as well as the Auger electrons from 3d and 3p levels. The measured anisotropy parameters (β) of these electrons show good agreement with previous theoretical Hartree-Fock calculations. The ion abundance in the time-of-flight mass spectra of Kr is consistent with the ratio derived from the intensities of the corresponding photoelectron peaks.For CCl₄, the electron spectrum contains Cl 2p photoelectrons, 2p Auger electrons, and valence-shell photoelectrons, with their angular distribution parameters also aligning with theoretical predictions. The TPX3CAM can directly measure the momenta of fragment ions without the need of inverse Abel transformation. By integrating the high-resolution flight time mass spectrometry and momentum imaging data obtained from TPX3CAM, we successfully visualize and analyze the key photodissociation pathways of CCl₄ molecules under the action of soft X-ray FEL. In particular, it can distinguish between direct two-body dissociation and multi-step dissociation processes, and observe the unique angular distributions and kinetic energy release characteristics of different dissociation channels.In conclusion, the experimental results clearly show that the CpVMI fully meets the technical requirements for FEL user experiments in terms of energy, angular distribution, and momentum measurement, providing a platform for FEL light-induced dynamics research. Future enhancements, including improved light focusing and the use of supersonic molecular beams, are expected to further improve the performance of the instrument.

[Abstract](287) HTML PDF

SPECIAL TOPIC—Instrumentation and metrology for ultrafast atomic and molecular spectroscopy

EDITOR'S SUGGESTION

Design and application of liquid-phase magnetic-bottle time resolved photoelectron spectroscopy

REN Baihui, YU Yao, YAN Pengyu, WANG Mengyang, MENG Sheng, ZHANG Pengju

2025, 74 (24): 244204. doi: 10.7498/aps.74.20251130

Abstract +

The liquid phase serves as a critical environment for chemical and biological reactions. The chemical and biological reaction dynamics of molecules in liquids exhibit evolution behaviors that are significantly different from those of isolated molecules in the gas phase. The in-depth investigation of the ultrafast excited-state dynamics of liquid-phase molecules is of great importance for uncovering the microscopic mechanisms underlying complex chemical and biological processes. Photoelectron spectroscopy not only reveals the electronic structure of excited-state molecules but also exhibits high sensitivity to structural changes, making it a powerful tool for studying the relaxation dynamics. Liquid-phase time-resolved photoelectron spectroscopy utilizes a liquid microjet within a high vacuum. In this pump-probe technique, an initial pump pulse excites the liquids to initiate dynamics, followed by a delayed probe pulse that ionizes the evolving system. The time-dependent energy distribution of the resulting photoelectrons, which encodes the ultrafast dynamics, is measured by a magnetic-bottle time-of-flight (MB-TOF) analyzer. This review systematically summarizes recent advancements in the time-resolved liquid-phase photoelectron spectroscopy technology for studying ultrafast dynamics in liquids, detailing the fundamental working principles of magnetic-bottle spectrometers and the preparation techniques for liquid microjet targets. Furthermore, typical applications are discussed, concluding with an analysis of current technical challenges and future research directions.

[Abstract](287) HTML PDF

EDITOR'S SUGGESTION

Multiphoton microscopy imaging system driven by dual-wavelength-pumped self-phase modulation spectral selection

CHEN Runzhi, WANG Xiaoying, ZHANG Lihao, LIU Yang, WU Jihua, DIAO Xincai, ZHANG Di, LI Lianyong, CHANG Guoqing, XUE Ping, JING Gang

2025, 74 (24): 244206. doi: 10.7498/aps.74.20251069

Abstract +

Multiphoton microscopy (MPM) has become an essential research tool in biomedicine. Current MPM systems predominantly rely on Ti:sapphire lasers provided tunable femtosecond pulses at 720–950 nm. To access the second biological transparency window (1000–1350 nm), complex optical parametric oscillators are typically required. Furthermore, sources operating in the third biological transparency window (1600–1750 nm) are attracting significant attention for enhanced imaging depth. However, no ultrafast laser source simultaneously covering all three transparency windows exists, thus hindering the widespread application of MPM in life sciences. Here, we demonstrate a fiber-laser-based ultrafast source that generates four-color tunable pulses across 800–1650 nm, covering the full spectral range for multiphoton excitation. This source utilizes our proposed spectral selection technique via self-phase modulation (SESS). SESS ensures SPM-dominated spectral broadening, producing isolated spectral lobes. Filtering the outermost lobes will generate near-transform-limited pulses with broad wavelength tunability. Using this supercontinuum excitation source, we successfully realize label-free imaging of diverse biomedical specimens, validating the performance of MPM empowered by this novel driving source.

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SPECIAL TOPIC—Principles and applications of quantum optics·COVER ARTICLE

COVER ARTICLE

SPECIAL TOPIC—AI + Physical Science

EDITOR'S SUGGESTION

SPECIAL TOPIC—Semiconductor physics and devices

EDITOR'S SUGGESTION

SPECIAL TOPIC—Atomic, molecular and materials properties data

EDITOR'S SUGGESTION

SPECIAL TOPIC—Atomic, molecular and materials properties data

EDITOR'S SUGGESTION

SPECIAL TOPIC—Atomic, molecular and materials properties data

EDITOR'S SUGGESTION

SPECIAL TOPIC—Instrumentation and metrology for ultrafast atomic and molecular spectroscopy

EDITOR'S SUGGESTION

SPECIAL TOPIC—Instrumentation and metrology for ultrafast atomic and molecular spectroscopy

EDITOR'S SUGGESTION

SPECIAL TOPIC—Instrumentation and metrology for ultrafast atomic and molecular spectroscopy

EDITOR'S SUGGESTION

EDITOR'S SUGGESTION

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