#quantumemitters

University of California, Santa Barbara (UCSB) quantum information science researchers found a new, highly robust silicon qubit that could form the basis of scalable quantum technology. The hydrogen-free CN center solves silicon-based quantum emitter manufacturing problems.

The team, led by Materials Professor Chris Van de Walle, has found a stable defect that is compatible with industrial processes, suggesting a way to link laboratory quantum research with large-scale semiconductor-based quantum device manufacturing.

The Silicon Advantage

For the perfect qubit, the quantum equivalent of a classical computer bit, materials that are easy to create in vast quantities have been sought. Silicon, the core of the trillion-dollar semiconductor industry, is best for this transformation. Because silicon chip production infrastructure exists, researchers can employ this material without adopting new manufacturing paradigms.

Quantum technologies require “fab-friendly” physical systems with desirable quantum characteristics. Researchers have struggled to find silicon faults that are physically durable and can communicate across long distances using present infrastructure. CN center discovery solves communication and stability difficulties.

T Center “Hydrogen Fragility” Resolved

Before the CN center was discovered, the T center dominated scientific interest. The T center, a silicon imperfection consisting of carbon and hydrogen atoms, can store quantum information for long periods of time, like diamonds' NV center.

But hydrogen is the T center's "Achilles' heel". In a crystal lattice, hydrogen atoms are notoriously unstable because they are “slippery” and migrate easily during high-temperature heating and chemical processing for chip production. This sensitivity makes it difficult for engineers to create millions of identical T centers on a silicon wafer, which is needed for scalable quantum processors.

CN Center: Strong Alternative

To address this dependability issue, the UCSB Computational Materials Group used powerful first-principles computer simulations to find a hydrogen-free replacement. Their analysis revealed the CN center, a one-carbon (C)-one-nitrogen (N) compound.

The CN core is stronger than the hydrogen center because carbon and nitrogen produce stronger and more stable silicon lattice connections. While overseeing the experiment, UCSB postdoctoral scholar Kevin Nangoi noted, “This defect will be more robust and easier to realize in actual devices because it does not contain hydrogen like the T center does.”

The simulation findings reveal that the CN center duplicates the T center's electrical and optical features without fabrication concerns. According to project postdoctoral researcher Mark Turiansky, the core is solid and stays stable even under rigorous heat processing conditions used in conventional semiconductor manufacturing.

Transitioning to the Quantum Internet

The CN center is stable and communicatively gifted. For a global “Quantum Internet” to exist, qubits must produce light in the telecom band, which may pass via fiber-optic cables with little signal loss.

These telecom photons are naturally emitted by the CN center. A stable “spin” that serves as quantum memory can be directly coupled to a quantum communication unit, a “photon,” by building a spin-photon interface. Due to its compatibility with global fiber-optic networks, the CN center is a strong candidate for long-distance quantum networking.

Simulation of Future Hardware

First-principles computer simulations enabled this discovery. These advanced models allow researchers to predict the properties of material systems that have not yet been developed in a lab. Theoretical models guide technical efforts to create novel quantum devices, saving time and money.

Professor Van de Walle noted that if the CN center is experimentally proven, it might be used as a building block for electronics that use the same silicon material as modern computers and cellphones.

Moving Forward: Experimental Validation

This research will proceed to experimental validation. To study the CN core physically, scientists worldwide will “plant” carbon and nitrogen atoms into silicon lattices.

The CN center may become the industry standard for future quantum hardware if experiments match UCSB calculations. This suggests that a fault-tolerant quantum computer that can simulate new drugs or crack complex encryptions may require a precise silicon technology enhancement rather than a manufacturing revolution.

Trinity researchers unify magnetodielectric cavity dynamics, a quantum nanophotonics breakthrough.

Quantum Nanophotonics A theoretical breakthrough from Trinity College Dublin's School of Physics and CRANN Institute answers a significant quantum nanophotonics challenge. In APL Quantum, Lars Meschede, Daniel D. A. Clarke, and Ortwin Hess presented a unified theoretical framework for the quantization of electromagnetic resonances, or quasinormal modes (QNMs), in spatially inhomogeneous, dissipative, and dispersive magnetodielectric resonators.

Challenge of Lossy Nanostructures Nanoscale cavity quantum electrodynamics (cQED) designs have advanced faster than theoretical models. Traditional semiconductor quantum optics uses high-quality-factor dielectric microcavities to imitate “normal modes” with genuine frequencies and limitless lifetimes. Modern nanostructures, especially plasmonic and magnonic cavities, are fundamentally different.

Plasmonic resonators are valued for confining light to sub-wavelength scales to raise local electromagnetic fields exceeding the diffraction limit. Even single molecules can achieve room-temperature cQED. Spin-photon interfaces are created by collective microwave excitations of spins in ferrimagnetic structures in cavity magnonics, a new field.

They are “lossy” because to radiative leakage and material absorption (Ohmic dissipation). Non-Hermitian systems often fail standard quantization methods or use ad hoc protocols that are not field-theoretically justifiable.

Conquering Modal Divergence Lossy cavities' natural resonances, quasinormal modes (QNMs), have intricate eigenfrequencies, making math difficult. Light leakage from these “open” cavities causes the QNM fields to diverge dramatically at long distances. This discrepancy makes orthogonality, normalization, and completeness difficult to express.

Exterior complex coordinate transformations—equivalent to PMLs—fixed the issue for Trinity. These specialised layers enclosed the computer domain, transforming unlimited space into a confined domain. This method converts unphysical radiative losses into non-radiative material dissipation to strictly regularize modes inside and outside the resonator chamber.

A New Quantum Formalism The researchers used macroscopic quantum electrodynamics to quantify these regularized modes. Their method finds canonical field variables in complex dielectric and magnetic media.

The breakthrough relies on the concept of creation and annihilation operators, which generate modal Fock states. These states describe the excitations of “field-dressed matter”—a blend of material polaritonic excitations and the electromagnetic field.

Researchers found an effective Lindblad master equation. This equation controls the quantum dynamics of modes and their interactions with quantum emitters (QEs) such molecular spins and semiconductor quantum dots. By accounting for coherent and dissipative coupling, the master equation captures complex interference effects like Fano-like features that occur when multiple modes interact with a single emitter.

Results, Numerical Validation The researchers demonstrated their framework's predictive power using two rigorous numerical examples:

Scientists tested a nitrogen-vacancy center QE diamond resonator. Even with low cavity quality factors, the quantum quasinormal modes theory predicted the Purcell factor (the amplification of spontaneous emission) with good agreement with exact semi-classical models. The theory accurately represented the system's temporal Rabi oscillations in the strong coupling region, matching mQED computations. 3D Spherical Cavity: Applying the theory to a silicon sphere in a vacuum eliminated PML layer unphysical gain contributions. Modelling resonance shapes from Lorentzian peaks to Fano-like decay rate suppressions was successful. Making Quantum 2.0 Possible The consequences of this discovery go beyond “Quantum 2.0”. This rigorous and mathematically possible nanophotonic technology evaluation helps build near-field multipartite entanglement creation, ultrafast all-optical switching, and on-demand single-photon sources.

Unprecedented quantum frequency conversion for future quantum networks by scientists

An international research team demonstrated a highly efficient and compact quantum frequency converter that can bridge the gap between high-performance quantum emitters and conventional telecommunications infrastructure, advancing the "quantum internet" concept. The study, led by Mathis Cohen and Université Côte d'Azur, Quandela SAS, and Université Paris-Saclay, describes a system that converts single photons from the near-infrared (NIR) spectrum to the telecommunication C-band with unparalleled end-to-end efficiency and quantum integrity preservation.

Challenge of Wavelength Incompatibility

The main obstacle to long-distance quantum resource distribution is wavelength mismatch. Current high-performance deterministic single-photon emitters, such as those based on semiconductor quantum dots (QDs), atoms, or color centers, operate in the near-infrared range (780–950 nm). However, typical silicon optical fibers lose signal when transmitting these wavelengths long distances.

The telecommunication C-band (about 1550 nm) has the lowest absorption in contemporary fiber networks and is the “natural flying qubit carrier” for long-distance communication. Quantum Frequency Conversion (QFC) adjusts a photonic state's wavelength while preserving its quantum properties, such as unicity and indistinguishability.

An Innovative Efficiency Standard

Researchers use a fiber-pigtailed semiconductor quantum dot single-photon source and a fiber-coupled nonlinear optical Lithium Niobate waveguide in their coherent frequency converter approach. This integrated system converted 925.7-nm photons to 1560-nm.

The team achieved 48.4% end-to-end efficiency. Because quantum information processing is susceptible to photon loss, this measure is crucial. The device maintained an in-fiber single-photon rate of 2.8 MHz (3.7% brightness) at the quantum frequency conversion stage's input, resulting in 1.3 MHz after maximum efficiency processing. A commercial fiber-pigtailed source sets a new photon rate record at the end of a quantum frequency conversion system.

Quantum Fidelity Maintenance

Efficiency is lost if quantum information is confused during conversion. The team prioritized indistinguishability (ensuring photons are the same in all physical modes) and unicity (releasing only one photon at a time).

Using HBT interferometry, researchers assessed the second-order autocorrelation coefficient (g(2)(0)). Single-photon purity was nearly 100%, with values of 0.044 before conversion and 0.051 after.

Hong-Ou-Mandel (HOM) interference tests also assessed indistinguishability. Conversion raised system corrected indistinguishability from 79.3% to 80.0%. These results demonstrate that the interface maintains coherence and that quantum dot photons are not degraded during conversion.

Designed for Real Life

This new system is fiber-integrated, unlike many previous demonstrations that used massive, “free-space” optical structures, which are vibration-sensitive and difficult to scale. For this wavelength shift, the conversion step uses a 4 cm periodically poled lithium niobate waveguide (PPLN/WG).

A 400 by 400 mm breadboard houses the pump preparation, conversion, and filtering stages, making the layout extremely small. The system is portable and can be used in real-world quantum network applications and out-of-lab deployment.

Another significant quality is spectral tunability. A configurable pump laser and crystal temperature allowed the researchers to tailor the conversion process over a 10 nm range. This aligns telecom wavelengths from different quantum dots, which is necessary in actual quantum networks to synchronize many sources.

Noise Reduction and Technical Precision

The conversion technique uses difference-frequency generation (DFG) powered by a strong 2272 nm continuous-wave pump laser. Noise—especially Raman scattering and residual pump light—is a major technical challenge in such systems. A filtering stage was built using four telecom dense-wavelength demultiplexers (DWDM) to address this. The system had excellent noise reduction with an SNR above 400 in the ideal working range.

Future Impact

This work enables several cutting-edge quantum technologies:

Quantum Key Distribution (QKD): Single-photon qubit carriers offer secure communication channels.

Quantum Repeaters: These devices can teleport quantum states over long distances, transcending laboratory limits.

Distributed Quantum Computing: Smoothly connecting quantum information processing units at different wavelengths.

Scientists at Argonne find and design atomic quantum emitters for future instruments.

Quantum Emitters

Researchers at the U.S. Department of Energy's (DOE) Argonne National Laboratory and the University of Illinois Urbana-Champaign have advanced quantum technology by designing and positioning atomic-scale single-photon sources in ultrathin 2D materials. This groundbreaking finding uses the Centre for Nanoscale Materials' (CNM) cutting-edge Quantum Emitter Electron Nanomaterial Microscope (QuEEN-M) to enhance quantum technology.

Quantum emitters, nicknamed tiny switches, properly activate photons to form the “bits” of many quantum technologies. Atomic-scale faults in materials provide these essential elements, and quantum computing, secure communication, and ultraprecise sensing depend on their precision in light production. However, identifying and managing these atomic light switches has been tough scientifically.

See also Argonne National Laboratory News about Quantum Material.

With the QuEEN-M at the CNM, a DOE Office of Science user facility, the scientists found and created these essential light sources in hexagonal boron nitride. Linking the atomic structure of quantum emitters to their optical behaviour has allowed researchers to create materials with unique quantum properties for future devices.

“The challenge in studying quantum emitters is that their optical behaviour is determined by their atomic structure, which is very hard to observe directly,” said Argonne materials scientist and Interim Group Leader for Electron and X-ray Microscopy Jianguo Wen. Research traditionally chose between bigger samples for light emission observation and thinner samples for atomic structure study.

Wen and his team avoided this by using the high-resolution QuEEN-M microscope and cathodoluminescence spectroscopy. Light is produced by directing an electron beam at the material. The colour and intensity of the light produced reveal important facts about the quantum emitter and its defect sites. QuEEN-M is a unique electron microscope with modern electron optics and detectors.

The QuEEN-M is a Thermo Fisher Spectra 300 probe-corrected scanning transmission electron microscope with a CL spectrometer, ultrafast pulser, and beam blanker. This powerful apparatus allows EDS/EELS mapping, CL spectroscopy, 4D-STEM, and real-space atomic-resolution imaging with high spatiotemporal resolution.

The discovery that hexagonal boron nitride layers twisted at specific angles to generate “twisted interfaces” boost quantum emitter light signals by up to 120 times. The researchers used this amplified signal to locate emitters with astonishing precision of fewer than 10 nanometres. The group used this exact method to identify a blue quantum emitter in hexagonal boron nitride as a carbon dimer, a pair of vertically stacked carbon atoms.

The researchers were able to manufacture quantum emitters on demand by adding carbon to the material and activating emitters with the electron beam. Thomas Gauge, an Argonne physicist, said, “The ability to link the atomic structure with the light it emits allowed for the precise engineering of these quantum emitters, which we can now create and modify on demand using an electron beam.” “The ability to place these photons with high accuracy is crucial for the quantum electronics of the future,” said Argonne scientist Benjamin Diroll.

These precision engineering capabilities allow scientists to build quantum-specific materials that can be placed on a chip. Quantum technologies are expected to evolve faster and merge these customised materials with other technologies to improve signals and information transmission.

CNM's Electron and X-ray Microscopy (EXM) group researches quantum emitters. From atomic to device size, the EXM group characterises and regulates material functions. This objective aligns with the CNM's five scientific themes: quantum coherence by design, interfaces, assembly, and fabrication for emergent features, ultrafast dynamics and non-equilibrium processes, AI/ML Accelerated analytics and automation, and nanoscale discovery for new energy

At the nano to atomic scale, the EXM team's spatial, energetic, and temporal resolution allows for unprecedented understanding of material properties. Now, electron microscopes can resolve single atoms hidden in structures. Ultrafast Electron Microscopy (UEM) helps the EXM group study nanoscale dynamics.

The UEM studies nanoscale structure and chemical dynamics using electrons at sub-picosecond speeds. The UEM enables sub-nanometer, sub-picosecond, and sub-electronvolt spatial, temporal, and energy resolutions to understand material transient events. User access is available. Technical specifications estimate temporal, spatial, and energy resolutions at 1 ps, 1 nm, and 1 eV. Using Altos Photonics lasers and a JEOL JEM2100PLUS electron microscope, this equipment can observe short-lived metastable phases and fast dynamics in materials that conventional electron microscopes cannot.

The EXM group uses the Hard X-ray Nanoprobe (HXN) at APS Sector 26 for strong X-ray microscopy. At APS beamline 26-ID, the CNM/APS HXN facility delivers a hard X-ray beam tunable spanning the 6–12 keV spectral range and focussed down to 25 nm onto the material. This energy range is best for mapping most elements, crystalline thin films, devices, interfaces, and inner-shell electronic resonances.

HXN supports scanning nanodiffraction, Bragg ptychography (5 nm resolution), and multimodal chemical and structural nanoimaging (30 nm resolution). X-ray microscopy efforts include time-resolved pump-probe Bragg diffraction microscopy at the HXN for operando picosecond/nanoscale studies and AI/ML-enabled Bragg ptychographic imaging in the dynamical regime for complete 3D visualisation of deep defects.

Advanced Materials published this quantum emitter study, funded by the DOE Office of Basic Energy Sciences, Argonne's Laboratory Directed Research and Development program, and QIS. The National Nanotechnology Initiative's core infrastructure investment is five DOE Nanoscale Science Research Centres (NSRCs), including the CNM.

The photon purity of quantum light is over 90% improved by molecular coating. Quantum technology advanced with the discovery of a coating method that improves quantum light precision and consistency. The unique method uses PTCDA, an organic chemical, and a semiconductor to generate single photons with consistent energy. Functional quantum technologies require consistency.

Researchers expect these more reliable semiconductors may boost quantum computing performance. The paper's corresponding author, Northwestern University's Mark Hersam, emphasized the goal of creating quantum networks and a quantum internet. Quantum communication requires reliable, scalable, and tuneable single photons, which this new technology will help build.

Overcoming Quantum Emitter Variability

Due to existing materials, developing reliable quantum light sources is difficult. The semiconductor employed in the study was atomically thin tungsten diselenide with one layer. Defects like missing atoms cause tungsten diselenide to emit single photons. Quantum emitters are very sensitive to their surroundings. Airborne pollutants like oxygen may interact with these emitters. This interaction changes emitters' single-photon emission. Any fluctuation in photon amount or energy drastically limits quantum technologies' performance. This unique coating approach was developed to address the “noisy” character of quantum light caused by environmental interactions. The work protected fragile emission sites to improve quantum light clarity and precision. A Perfect Molecular Solution: PTCDA The research team overcame environmental susceptibility with their unique PTCDA coating. An organic molecule called PTCDA shields tungsten diselenide when placed on it. In a vacuum chamber, PTCDA molecules are carefully deposited one layer at a time during coating. According to Hersam, this extraordinarily uniform molecular layer protects single-photon emitters from contaminants. This approach produces a "molecularly perfect coating," which provides a consistent environment for single-photon-emitting sites.

Managed Shifting Improves Purity

Solid-State Quantum Emitters

Pioneering research into solid-state quantum emitters, nanoscale light sources that enable safe data transfer, precise measurements, and powerful computation, is accelerating quantum communication and sensing technologies. (Alan) Quantum News Hound reports that an exhaustive analysis by scientists at the University of Electronic Science and Technology of China emphasises their importance in scalable quantum computing across three primary material platforms:

The Basics of Quantum Emitters

Understand Quantum Emitter Basics Quantum emitters can produce entangled photon pairs and single photons upon request. Atomic systems require precise trapping, but solid-state emitters are embedded in materials, making nanofabrication for scaled quantum technologies easier.

Key Performance Indicators

Several key measures evaluate performance:

Radiative Rate & Spectra/Linewidth: High radiative rates (hundreds of MHz or GHz) are preferred for photon creation. The coherent zero-phonon line (ZPL) should be close to unity and have a short, transform-limited linewidth.

Single-Photon Purity: g^(2)(0), preferably 0, indicates genuine single-photon emission, excluding simultaneous photons.

Quantifying photon identicality is fundamental to quantum interference. Evaluation uses Hong-Ou-Mandel (HOM) interference, where ideal indistinguishable photons have unit contrast. High indistinguishability requires minimizing dephasing. Photon efficiency controls brightness. Integrated optical cavity emitters increase emission rate and collecting efficiency (Purcell effect).

The ability to deterministically release one photon every trigger pulse is called “on-demand operation.” To provide coherent control, resonant π-pulses are used to excite the emitter with near-unit fidelity. This requires separating the pump laser and released photons.

Quantum networks require a matter qubit with extended coherence durations and a photonic interface. Scalability requires telecom wavelength emission, multi-emitter consistency, and nanophotonic circuit compatibility.

Potential Material Platforms

Research focusses on three solid-state platforms:

The speed and brightness of quantum dots (QDs) make them a highly advanced photonic quantum resource. QDs have 98% entangled photon fidelity and >99% single-photon purity. Emissions influence telecom O- and C-band. Even though spin coherence (microsecond to sub-millisecond) is shorter than diamond/SiC defects, noise reduction improves their properties.

Diamond Defect Centres: Even at room temperature, diamond defect centres have extended spin coherence periods, making them ideal for information processing and quantum sensing. Group IV defects (SiV-, GeV-, and SnV-) contribute more ZPL, but NV-centers have stable spins. High single-photon purity (97–99%) is normal, but indistinguishability is difficult. Photonic structure integration is progressing despite fabrication issues.

Silicon carbide (SiC): Defect centres' interesting quantum properties and compatibility with semiconductor architecture are making them more popular. SiC has a wide bandgap and good heat conductivity. With emission from 600 nm to the telecom O-band, it has many problems. SiC has excellent spin properties and prospective spin-photon interfaces at ambient temperature due to divacancy centres' five-second coherence durations. SiCOI supports advanced integrated nanophotonic devices.

Challenges Overcame, Future Prospects

Important concerns persist across platforms:

Extension of Coherence: Cavity augmentation improves QD performance at higher temperatures.

Scalable Fabrication: Material variability and emitter location are crucial for large-scale integration.

Despite improvements in room-temperature emitters, cryogenic conditions are usually best for performance.

Telecom wavelengths: Long-distance communication requires frequency conversion or direct emission.