MicroCloud Hologram Inc. Develops Local Quantum Coherence (LQC) for Precise Detection of Quantum Phase Transition (QPT) Phenomena in Multi-Model Systems

Rhea-AI Summary

MicroCloud Hologram Inc. (NASDAQ: HOLO) has announced a breakthrough in quantum physics research, developing Local Quantum Coherence (LQC) for detecting quantum phase transitions (QPT) in various quantum systems. The company's research applies LQC to several quantum models, including the one-dimensional Hubbard model, XY spin chain model, and Su-Schrieffer-Heeger model.

The research demonstrates that LQC can effectively detect quantum phase transitions at both zero and finite temperatures, offering advantages over traditional detection methods. HOLO's study revealed that LQC shows distinct behaviors in different quantum systems, particularly in quantum dots, providing new insights for quantum materials and device development.

The company's findings contribute to understanding quantum many-body systems and offer new theoretical tools for studying quantum phase transitions, potentially advancing the development of quantum technologies.

Positive

• Development of new quantum detection technology that could lead to advanced quantum materials and devices
• Successfully demonstrated LQC's effectiveness in detecting quantum phase transitions at various temperatures
• Created proprietary quantum analysis tools with potential commercial applications

Negative

• No immediate revenue impact or commercialization timeline mentioned
• Research still in theoretical stage without clear path to monetization

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On the day this news was published, HOLO gained 4.39%, reflecting a moderate positive market reaction.

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SHENZHEN, China, Feb. 20, 2025 /PRNewswire/ -- MicroCloud Hologram Inc. (NASDAQ: HOLO), ("HOLO" or the "Company"), a technology service provider, they focuses on the in-depth exploration of the connection between local quantum coherence (LQC) and quantum phase transition (QPT), providing new perspectives and theoretical foundations for understanding the characteristics and transition mechanisms of quantum systems.

The study of quantum phase transitions is of crucial importance for revealing the mysteries of quantum many-body systems, as well as for developing novel quantum materials and quantum devices. However, accurately detecting and understanding the process of quantum phase transitions has remained one of the key challenges in this field. HOLO introduces the important concept of local quantum coherence (LQC), based on Wigner-Yanase skew information, to study quantum phase transitions. Wigner-Yanase skew information is a significant quantity in quantum information theory, capable of characterizing the non-classical properties of quantum states. Local quantum coherence focuses on the quantum coherence properties in local regions of a quantum system. This coherence is one of the key distinguishing features between quantum and classical systems, reflecting the superposition property of quantum states and the degree of entanglement between quantum bits. In their research, HOLO applies LQC to several typical quantum models, including the one-dimensional Hubbard model with three-spin interactions, the XY spin chain model, and the Su-Schrieffer-Heeger model. The one-dimensional Hubbard model is an important model for describing the motion and interaction of electrons in a lattice and is widely used in condensed matter physics to study the properties of strongly correlated electron systems. The XY spin chain model mainly investigates the interactions between spins and the resulting quantum state properties. The Su-Schrieffer-Heeger model is commonly used to describe the electronic structure and superconducting phenomena in organic polymers.

Through in-depth studies of these models, HOLO discovered that LQC and its derivatives can successfully be used to detect different types of quantum phase transitions in spin and fermion systems. In these models, quantum phase transitions lead to significant changes in the system's quantum states, and LQC is able to sensitively capture these changes. For example, in the one-dimensional Hubbard model, when the system undergoes a quantum phase transition from a metallic phase to an insulating phase, the value of LQC shows a clear discontinuity, which corresponds to the critical point of the quantum phase transition, providing a clear signal for determining the occurrence of the quantum phase transition. In the XY spin chain model, LQC can accurately reflect the changes in the correlation between spins during the quantum phase transition process, helping to deepen the understanding of the microscopic mechanisms behind quantum phase transitions.

Additionally, HOLO also investigated the role of LQC in detecting quantum phase transitions at finite temperatures. In real quantum systems, temperature often cannot be ignored, and finite temperatures can affect quantum states, potentially causing some quantum properties to vanish. In such cases, traditional tools used for detecting quantum phase transitions, such as entanglement, may lose their effectiveness. However, HOLO's research shows that LQC, as a manifestation of quantum discord (QD), can still effectively detect quantum phase transitions at finite temperatures. Quantum discord is a broader measure of quantum correlations, which not only includes entanglement as a strong form of quantum correlation but also encompasses non-entangled yet quantum-correlated states. As a specific manifestation of quantum discord, LQC can capture subtle changes in quantum correlations within a system at finite temperatures, providing a new approach for detecting quantum phase transitions.

HOLO further demonstrated that, compared to quantum dots, LQC can exhibit different behaviors in various forms. Quantum dots are zero-dimensional quantum systems with unique quantum properties, commonly used in fields like quantum information processing and quantum computing. The behavior of LQC in quantum dot systems differs from that in other quantum systems, as it is influenced by factors such as the size, shape, and surrounding environment of the quantum dot. Through comparative studies, HOLO discovered that LQC displays a rich variety of characteristics in different quantum systems, providing important clues for further understanding the nature of quantum systems and for the development of novel quantum technologies.

HOLO's research on the connection between LQC and QPT offers new theoretical tools and research methods for the study of quantum phase transitions. This achievement not only helps deepen our understanding of the fundamental properties of quantum many-body systems but also provides potential application directions for the design of future quantum materials and the development of quantum devices.

About MicroCloud Hologram Inc.

MicroCloud is committed to providing leading holographic technology services to its customers worldwide. MicroCloud's holographic technology services include high-precision holographic light detection and ranging ("LiDAR") solutions, based on holographic technology, exclusive holographic LiDAR point cloud algorithms architecture design, breakthrough technical holographic imaging solutions, holographic LiDAR sensor chip design and holographic vehicle intelligent vision technology to service customers that provide reliable holographic advanced driver assistance systems ("ADAS"). MicroCloud also provides holographic digital twin technology services for customers and has built a proprietary holographic digital twin technology resource library. MicroCloud's holographic digital twin technology resource library captures shapes and objects in 3D holographic form by utilizing a combination of MicroCloud's holographic digital twin software, digital content, spatial data-driven data science, holographic digital cloud algorithm, and holographic 3D capture technology. For more information, please visit http://ir.mcholo.com/

Safe Harbor Statement

This press release contains forward-looking statements as defined by the Private Securities Litigation Reform Act of 1995. Forward-looking statements include statements concerning plans, objectives, goals, strategies, future events or performance, and underlying assumptions and other statements that are other than statements of historical facts. When the Company uses words such as "may," "will," "intend," "should," "believe," "expect," "anticipate," "project," "estimate," or similar expressions that do not relate solely to historical matters, it is making forward-looking statements. Forward-looking statements are not guarantees of future performance and involve risks and uncertainties that may cause the actual results to differ materially from the Company's expectations discussed in the forward-looking statements. These statements are subject to uncertainties and risks including, but not limited to, the following: the Company's goals and strategies; the Company's future business development; product and service demand and acceptance; changes in technology; economic conditions; reputation and brand; the impact of competition and pricing; government regulations; fluctuations in general economic; financial condition and results of operations; the expected growth of the holographic industry and business conditions in China and the international markets the Company plans to serve and assumptions underlying or related to any of the foregoing and other risks contained in reports filed by the Company with the Securities and Exchange Commission ("SEC"), including the Company's most recently filed Annual Report on Form 10-K and current report on Form 6-K and its subsequent filings. For these reasons, among others, investors are cautioned not to place undue reliance upon any forward-looking statements in this press release. Additional factors are discussed in the Company's filings with the SEC, which are available for review at www.sec.gov. The Company undertakes no obligation to publicly revise these forward-looking statements to reflect events or circumstances that arise after the date hereof.

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SOURCE MicroCloud Hologram Inc.

FAQ

What is the significance of HOLO's Local Quantum Coherence (LQC) development?

HOLO's LQC development provides new tools for detecting quantum phase transitions in multiple quantum systems, offering improved detection capabilities at both zero and finite temperatures compared to traditional methods.

How does HOLO's LQC technology work with quantum phase transitions?

LQC uses Wigner-Yanase skew information to study quantum phase transitions, focusing on quantum coherence properties in local regions of quantum systems and detecting changes in quantum states during phase transitions.

What quantum models did HOLO test with their LQC technology?

HOLO tested LQC on three main models: the one-dimensional Hubbard model, the XY spin chain model, and the Su-Schrieffer-Heeger model.

What advantages does HOLO's LQC technology offer over traditional quantum detection methods?

LQC can effectively detect quantum phase transitions at finite temperatures where traditional tools like entanglement may lose effectiveness, and it can capture subtle changes in quantum correlations within systems.