A new MIT-designed lidar chip uses specially engineered antennas to reduce interference and widen the sensor’s field of view. From self-driving cars navigating busy streets to drones surveying disaster zones, lidar has become one of the most important technologies for helping machines perceive the world in three dimensions. By sending out rapid pulses of infrared [...]
The Fraunhofer Institute for Applied Solid State Physics (IAF) has unveiled a groundbreaking advancement in electric vehicle (EV) power electronics with the development of a gallium nitride (GaN)-based power electronics module tailored for 800 V bidirectional direct current (DC) charging systems. This innovative module, realized within the GaN4EmoBiL project—an initiative funded by the German Federal Ministry for Economic Affairs and Energy (BMWi)—marks a significant leap towards more efficient, compact, and versatile EV charging solutions. The module’s integration into a bidirectional, single-phase off-board charger prototype, implemented by project partner Ambibox GmbH, signals a strategic shift in the landscape of EV charging technology.
At the heart of this module lies 1200 V GaN devices crafted on insulating substrates, leveraging the superior electrical and thermal properties of GaN semiconductors. The demonstrator is designed to accommodate battery voltages ranging from 150 V to an impressive 920 V, providing a versatile platform to evaluate device performance under realistic operating conditions. Gallium nitride’s wide bandgap enables higher breakdown voltage and faster switching speeds compared to conventional silicon-based devices, delivering unprecedented efficiency and power density in a compact footprint. These characteristics are pivotal for next-generation power electronics essential to the electrification of transport and energy systems.
The bidirectional, single-phase 800 V DC charger prototype delivers up to 3 kW of power, addressing a critical market gap where traditional on-board chargers fall short in balancing cost, flexibility, efficiency, and size. EVs typically rely on on-board chargers converting AC from household or public charging infrastructures into DC at 11 or 22 kW for rapid charging. However, these on-board units are burdened by high costs, substantial weight, and significant spatial requirements due to their complex electronics and cooling systems. By relocating the charger off-board and leveraging GaN technologies, the Fraunhofer IAF and partners have engineered a lightweight (5.7 kg including plugs), compact (8.3 liters in volume), and mobile solution compatible with Combined Charging System (CCS) and Schuko plugs.
Beyond physical advantages, the charger embodies the crucial function of bidirectional charging, a technology set to revolutionize grid interaction with EVs. High-voltage reverse power flow capability enabled by the GaN module allows EV batteries to not only draw energy from the grid but also feed stored energy back during peak demand or grid stress, thus acting as distributed energy storage. This vehicle-to-grid (V2G) functionality represents a paradigm shift toward a more resilient, efficient, and sustainable energy infrastructure, integrating transportation and power networks seamlessly.
Fraunhofer IAF continues to push the boundaries of GaN power electronics, pioneering innovative device architectures and integrated power circuits that enable system-level miniaturization through functional integration. Concurrent efforts focus on scaling these technologies to higher voltage classes, larger current capacities, and increased wafer sizes to achieve cost-effective wide-bandgap semiconductor solutions on par with silicon devices. The ultimate ambition is to harness the intrinsic performance benefits of GaN while adhering to the stringent cost targets demanded by widespread commercial adoption.
The institute plans to showcase these advancements at the upcoming PCIM Expo & Conference 2026 in Nuremberg, emphasizing “Power Electronics for Energy Technology.” Presentations and exhibits will highlight a suite of GaN-based components and modules, with the bidirectional EV charging system demonstrator serving as a flagship example. A robust scientific program includes keynote speeches, technical sessions, and panel discussions led by Fraunhofer researchers, illuminating the state-of-the-art in GaN devices and prospects for future innovation.
One keynote by Dr. Michael Basler will trace the evolution from lateral to vertical and bidirectional GaN transistor configurations, outlining the technological trajectories and breakthroughs fueling enhanced power electronic performance. Complementary talks by Dr. Richard Reiner will delve into comparative device concepts and strategies for scaling the power capabilities of GaN technologies to meet the demands of 1200 V and beyond, highlighting critical design trade-offs and manufacturing challenges. Poster sessions featuring research by Jun.-Prof. Dr. Stefan Mönch and Daniel Fugmann will provide detailed insights into inverter integration and device dynamic characteristics fundamental to system optimization.
The emerging All-Electric Society paradigm hinges on continuous advancements in power electronics that can efficiently convert and store energy at ever-increasing voltages and power densities. GaN semiconductors offer transformative potential, enabling devices that operate faster, dissipate less heat, and occupy less volume than silicon counterparts. This technological edge accelerates the deployment of high-performance converters and inverters essential for EVs, renewable energy integration, and smart grid applications, thereby catalyzing the transition to sustainable energy and mobility ecosystems.
Within the domain of electromobility, GaN makes it feasible to harness power electronics operating reliably at voltages up to 1200 V, with future prospects toward 1700 V classes. This capability unlocks new architectures for EV charging infrastructure and onboard powertrains that enhance battery range, charging speeds, and system efficiency while simultaneously reducing overall costs. Collectively, these improvements promise to diversify and democratize electric mobility, extending its appeal and accessibility to a broader segment of society.
The GaN4EmoBiL project embodies a comprehensive effort to bridge the gap between research and real-world application by delivering a cost-effective, intelligent bidirectional charging platform. Research spans from novel GaN high-voltage transistors fabricated on low-cost alternative substrates to innovative bidirectional switch component concepts and integrated system implementations for both on- and off-board chargers. A critical focus on reliability and long operational lifetimes aims to meet stringent automotive standards and market expectations.
As one of the world’s foremost institutes in III-V semiconductor technologies and synthetic diamond research, Fraunhofer IAF leverages deep expertise to develop cutting-edge components for communication, mobility, quantum computing, and sensing. The institute’s integrated approach—from material science through device fabrication and system demonstration—positions it uniquely to translate GaN innovations into impactful technological breakthroughs.
The introduction of the bidirectional GaN-based charging system stands as a testament to the transformative role of wide-bandgap semiconductors in shaping the future of energy and transportation. This development not only addresses current market demands for efficient and flexible EV charging but also lays groundwork for the integration of electric vehicles as active elements within a decarbonized energy grid, aligning with global sustainability goals.
Subject of Research: Gallium nitride (GaN)-based power electronics for 800 V bidirectional DC EV charging systems
Article Title: Fraunhofer IAF Unveils GaN-Based Bidirectional 800 V DC Charger Revolutionizing EV Charging
News Publication Date: 2026
Web References:
– https://www.iaf.fraunhofer.de/en/customers/electronic-circuits/power-electronics.html
– https://www.iaf.fraunhofer.de/en/researchers/electronic-circuits/power-electronics/gan4emobil.html
– https://www.iaf.fraunhofer.de/en/networkers.html
Image Credits: © Fraunhofer IAF
Gallium Nitride, GaN Power Electronics, Electric Vehicle Charging, Bidirectional Charging, Wide-Bandgap Semiconductors, Energy Conversion, Power Modules, Electric Mobility, Vehicle-to-Grid, Off-Board Charger, 800 V DC Charging, Semiconductor Devices
In a groundbreaking advancement at the intersection of organic electronics and biomedical engineering, researchers at Linköping University have successfully replicated the ion signaling mechanism of heart muscle cells using conductive plastics. This achievement marks the first-ever artificial mimicry of cardiac ion transport—a complex biological process responsible for the heart’s relentless rhythm—and ushers in new possibilities for bio-integrated devices such as advanced prostheses, cardiac implants, and sensitive physiological sensors. Published in the revered journal Nature Communications, this pioneering work could redefine how we interface synthetic devices with living tissues.
The human heart’s ceaseless beating—approximately 2.6 billion cycles over an average lifespan—is orchestrated by a delicate dance of ions, including potassium, sodium, and calcium, across cellular membranes. This ion exchange generates the electrical impulses known as action potentials, which trigger myocardial contractions critical for blood circulation. Despite decades of research in bioelectronic interfaces, replicating the nuanced ion channel dynamics of cardiac cells, especially the comparatively slow calcium channels, has remained a formidable challenge for conventional electronics.
Traditional inorganic electronics excel in rapid signal processing but fail to emulate the intrinsic slowness of cardiac calcium ion channels. As Professor Simone Fabiano from Linköping University elucidates, the unique temporal properties of cardiac ion channels are crucial for effective heart function. “Nature has evolved these precise electrophysiological characteristics for good reason,” Fabiano notes. Recognizing this, the team turned to organic electronics, particularly conductive polymers, which naturally facilitate both ion and electron transport and can thus communicate analogously to biological cells.
At the heart of this research is an artificial cardiomyocyte device fabricated entirely from conductive plastic materials that recapitulate the cardiac action potential waveform. This synthetic cell mimics key electrical behaviors of native heart muscle cells by precisely controlling ion fluxes, thereby overcoming the temporal bottlenecks inherent in faster inorganic systems. Postdoctoral researcher Dace Gao explains that this dual ionic and electronic conductivity enables the sophisticated signal transduction necessary for genuine bioelectronic emulation.
Notably, this development builds upon the research group’s prior successes in engineering artificial neurons with organic electronic components. Transitioning from nerve cells to heart muscle cells represented a logical extension, confronting a higher degree of complexity due to the heart’s distinctive calcium channel kinetics. Developing hardware capable of duplicating these slow ion signaling dynamics filled a critical void in synthetic biointerfaces.
The implications of these findings transcend foundational science. According to Fabiano, such organic artificial cardiomyocytes could serve as powerful experimental models to investigate how physiological variables—like ion concentration fluctuations or pH changes—affect cardiac electrical signaling in a precisely controlled environment. “Hardware-based systems allow systematic study that would be challenging or impossible in vivo,” Fabiano remarks, emphasizing the intersection of materials science with electrophysiology.
Looking ahead, the research team aspires to integrate these artificial cardiac cells with living cardiac tissue, forging hybrid platforms that combine biological and synthetic components. This integration would be a transformative leap toward biohybrid implants capable of repairing or augmenting damaged heart tissue. Gao underlines the necessity for artificial cells not only to generate signals but to sense and relay impulses to and from biological cells, effectively functioning as bioelectronic conduits.
Potential applications envisioned by the team include minimally invasive “natural” pacemakers fabricated from flexible, biocompatible conductive polymers that synchronize seamlessly with the heart’s intrinsic rhythms. Furthermore, implants designed to activate specific muscle groups could revolutionize treatments for muscular dystrophies or nerve injuries. Sensitive biosensors derived from this technology might detect early electrophysiological disturbances, enabling preemptive clinical interventions for cardiac diseases.
The materials employed—organic conductive plastics—provide unique advantages over traditional silicon-based electronics. Their inherent compatibility with ionic signaling and their mechanical flexibility allow for intimate interfacing with soft biological tissues, reducing immune response and improving the longevity of implants. These properties position organic electronics as a promising frontier in the design of next-generation medical devices that bridge the gap between organism and machine.
Despite these promising advances, key challenges remain. Integrating artificial cells into the body’s existing complex electrical network requires precise synchronization and reliable signal transmission. The research community must also address long-term stability, biocompatibility, and potential immune reactions to organic materials. Nevertheless, the current breakthrough lays the foundational framework upon which such hurdles may be overcome.
By pioneering an organic artificial cardiomyocyte capable of emulating the nuanced ion transport and action potentials of heart muscle cells, the Linköping University team has opened new vistas in bioelectronic medicine. This fusion of organic materials science and cardiac electrophysiology not only deepens our understanding of living systems but also provides tangible pathways toward innovative therapies and diagnostic tools that harmonize human biology with technology.
As this work progresses, it promises to ignite profound transformations in cardiac healthcare, embodying the promise of truly integrative bioelectronics that respect and replicate the sophistication of the human heart.
Subject of Research: Artificial mimicry of ion signaling in heart muscle cells using organic electronics.
Article Title: An organic artificial cardiomyocyte
News Publication Date: 6-May-2026
Web References: DOI: 10.1038/s41467-026-72584-5
Image Credits: Thor Balkhed
Organic electronics, conductive plastics, cardiac muscle cells, ion signaling, artificial cardiomyocyte, bioelectronic interfaces, action potential, calcium ion channels, electrophysiology, biohybrid implants, pacemakers, biomedical devices
In a groundbreaking advancement for the field of organic electronics, researchers have unveiled a novel approach to creating deep-blue organic light-emitting diodes (OLEDs) that are not only highly efficient but also exhibit exceptional stability over prolonged use. This breakthrough hinges on optimizing the charge transfer dynamics within iridium-based phosphorescent materials, a feat that has eluded scientists for years due to the inherent challenges of balancing luminous efficiency with device longevity. The latest study, published on June 2, 2026, showcases how fine-tuning the molecular design and electronic interactions in these materials can revolutionize display technologies and solid-state lighting.
Organic light-emitting diodes are the backbone of modern display and lighting devices due to their lightweight, flexibility, and potential for low-cost manufacturing. However, blue OLEDs, particularly deep-blue variants, have long remained a bottleneck in the industry. Their performance typically pales in comparison to red and green counterparts, primarily because of difficulties in achieving high external quantum efficiency (EQE) while maintaining operational stability. The degradation mechanisms in blue OLEDs are often exacerbated by the high energy excitons required to produce blue light, resulting in rapid device failure. By addressing these persistent issues through enhanced charge transfer dynamics, the newly proposed iridium phosphorescent OLEDs mark a significant leap forward.
The core innovation lies in manipulating the photophysical properties of iridium complexes, which serve as the emissive centers in these OLED devices. Iridium is favored for its strong spin-orbit coupling, enabling efficient harvesting of triplet excitons and thereby boosting internal quantum efficiency. Yet, the challenge has been to mitigate efficiency roll-off at high luminance and to prolong device lifespan, especially for deep-blue hues where molecular stability is less assured. The interdisciplinary research team meticulously engineered ligands surrounding the iridium ion to facilitate precise electronic communication and improved charge transfer kinetics, which enhances both exciton utilization and thermal robustness.
A crucial aspect of the enhanced performance is the modulation of the charge transfer state between the iridium complex and its ligands. By optimizing this interaction, the researchers achieved balanced charge injection and transport within the OLED stack, thereby minimizing charge recombination losses. This optimization significantly reduces operational voltage, enhances brightness, and curbs the formation of non-radiative decay pathways that typically plague deep-blue emitters. The fine-tuned charge transfer dynamics ensure that excitons are efficiently channeled toward radiative recombination, culminating in record-breaking external quantum efficiencies surpassing previous benchmarks for deep-blue OLEDs.
Moreover, the study delves into the stability metrics under extended operational conditions, employing rigorous lifetime testing that simulates real-world device usage. The newly developed iridium-based OLEDs maintained over 90% of their initial luminance after 10,000 hours of continuous operation at high brightness levels—a figure that substantially outperforms existing commercial blue OLEDs. This endurance is attributed to the molecular stability endowed by the novel ligand design, which not only reinforces the metal center but also minimizes degradation reactions catalyzed by excited-state processes and charge imbalance.
From a device architecture perspective, the researchers integrated the iridium phosphorescent complexes into multi-layer OLED structures optimized for charge balance and thermal management. The strategic selection of charge transport layers and interface engineering further complemented the intrinsic molecular enhancements, enabling synergistic improvements in overall device efficiency and operational lifetime. This holistic approach underscores how molecular design, charge dynamics, and device engineering must coalesce to surmount the intrinsic limitations of deep-blue organic emitters.
The implications of this advancement extend far beyond displays. High-efficiency and stable deep-blue OLEDs pave the way for more energy-efficient solid-state lighting solutions with tailored spectral properties. The ability to generate more accurate blue wavelengths can also enhance color gamut reproduction and visual comfort in display technologies, addressing consumer demands for richer and more vibrant imagery. Additionally, the prolonged lifetime significantly reduces the environmental footprint associated with electronic waste, aligning with sustainable manufacturing goals.
The scientific community has recognized the strategic importance of charge transfer dynamics in governing OLED performance, but this research delivers actionable insights and practical molecular architectures that bring theoretical understanding into real-world application. Through state-of-the-art spectroscopic analyses and computational modeling, the team mapped out the electronic transitions and charge delocalization pathways, correlating these mechanisms directly with device-level improvements. This mechanistic clarity provides a blueprint for future material innovations across various optoelectronic platforms.
Notably, the researchers also investigated the effects of temperature and external stimuli on charge transfer behavior and device stability, demonstrating remarkable resilience under thermal cycling and high operational stress. Such robustness is critical for commercial adoption, where devices must withstand varying environmental conditions without degradation. The depth of characterization extends the relevance of the findings beyond fundamental science, emphasizing practicality and scalability.
Collaborations between chemists, physicists, and engineers were pivotal in realizing this breakthrough. The interdisciplinary nature of the project highlights the necessity of integrating expertise in organometallic chemistry, photophysics, and device fabrication. Such a collaborative framework accelerates innovation cycles and fosters the translation of lab-scale discoveries into market-ready technologies. The success of this study is a testament to the power of synergy in scientific research.
Looking ahead, the research opens avenues for further tuning of emission properties and charge transport by exploring alternative ligand frameworks and metal centers. The principles uncovered may also be applicable to other phosphorescent systems and even emerging classes of thermally activated delayed fluorescence (TADF) emitters. There is a growing excitement that these advancements will catalyze a new generation of high-performance OLEDs with customizable emission spectra and unprecedented durability.
The commercial impact of these findings is poised to be transformative. Deep-blue OLEDs with enhanced efficiency and stability are crucial for the next wave of ultra-high-definition displays, flexible screens, and wearable electronics. Companies investing in OLED technology stand to benefit by adopting these cutting-edge materials and design principles, potentially reducing manufacturing costs and improving product lifespan. As consumer demand for premium visual experiences grows, innovations like these will set new industry standards.
In conclusion, the recent study on high-efficiency and stable deep-blue iridium phosphorescent OLEDs marks a milestone in organic electronics research. By elucidating and optimizing charge transfer dynamics at the molecular level, the researchers have surmounted longstanding challenges in blue OLED performance, delivering devices that combine record efficiency with exceptional stability. This achievement not only enhances current display and lighting technologies but also enriches the scientific understanding of photophysical processes in complex organic-metal hybrid materials. The future of OLED innovation looks brighter than ever.
Subject of Research:
Development of high-efficiency and stable deep-blue iridium phosphorescent organic light-emitting diodes (OLEDs) through enhanced charge transfer dynamics.
Article Title:
High-efficiency and stable deep-blue iridium phosphorescent OLEDs with enhanced charge transfer dynamics.
Article References:
Li, S., Tong, KN., Zhang, M. et al. High-efficiency and stable deep-blue iridium phosphorescent OLEDs with enhanced charge transfer dynamics. Light Sci Appl 15, 259 (2026). https://doi.org/10.1038/s41377-026-02264-y
Image Credits: AI Generated
DOI: 02 June 2026
Keywords:
Deep-blue OLEDs, iridium phosphorescent complexes, charge transfer dynamics, organic light-emitting diodes, device stability, external quantum efficiency, ligand design, photophysics, solid-state lighting, optoelectronics
Checking blood pressure is one of the most common ways doctors assess heart and blood vessel health. High blood pressure affects millions of people around the world and is a major risk factor for heart attacks, strokes, kidney disease, and other serious conditions. Despite its importance, the technology used to measure blood pressure has changed […]
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