Ce topic appartient à l'appel Quantum Machine Learning
Identifiant du topic: HORIZON-JU-EUROHPC-2026-QML-07-01

Quantum Machine Learning

Type d'action : HORIZON JU Research and Innovation Actions
Date d'ouverture : 02 juin 2026
Date de clôture 1 : 28 janvier 2027 01:00
Budget : €6 000 000
Call : Quantum Machine Learning
Call Identifier : HORIZON-JU-EUROHPC-2026-QML-07
Description :

Expected Outcome:

  • Integration of quantum computing into data pre-processing pipelines and learning workflows for data-heavy or computationally intensive tasks, demonstrating clear improvements in processing speed, computational complexity, modelling accuracy, and reduced sample requirements at scales achievable with NISQ-era devices,
  • Reliable and scalable Quantum Machine Learning (QML) models and algorithms, integrated with existing AI frameworks and pipelines, enabling faster data processing, improved prediction accuracy, and enhanced computational capabilities,
  • Validated quantum-enhanced AI methods demonstrating measurable improvements over classical baselines in terms of speed, accuracy, data efficiency, complexity, or scalability, supported by rigorous benchmarking and complexity analysis,
  • Robust, noise-aware QML techniques suitable for NISQ hardware, including error-mitigation strategies and algorithmic adaptations that improve reliability, performance, and reproducibility on real quantum processors,
  • Demonstrators or proof-of-concept applications showcasing the relevance of QML for real-world challenges (e.g. climate and environmental modelling, Earth observation, healthcare and life sciences, materials discovery, finance, robotics, manufacturing, and cybersecurity),
  • Strengthened European leadership and technological sovereignty in quantum computing and trustworthy AI, supported by cross-sector collaboration, knowledge transfer, and contributions to emerging standards, benchmarks and best practices.
  • Enhanced collaboration across quantum computing, machine learning and application domains, fostering a coordinated European QML research and innovation community.

Scope:

Proposals are expected to address multiple key research directions in Quantum Machine Learning (QML), targeting both scientific excellence and industrial relevance. Proposals should clearly outline how to contribute to the development, validation and demonstration of quantum-enhanced AI approaches, with clear pathways towards practical applications. The proposed work should strengthen Europe’s scientific and technological capabilities in quantum computing and accelerate the industrial uptake of quantum-enhanced AI solutions.

Activities may include, but are not limited to

  • design and analysis of quantum, quantum-inspired or hybrid QML algorithms,
  • performance modelling, complexity analysis and benchmarking of quantum-enhanced AI methods,
  • development of error-mitigation and noise-aware strategies tailored to QML workloads,

Proposals should advance scalable QML algorithms capable of addressing large-scale, computationally intensive problems, this includes approaches that

  • can manage massive data volumes and complex computational tasks,
  • enable faster data processing and improved predictive performance in relevant application domains (e.g. hydrologic research, climate modelling, terrain classification from satellite remote sensing, drug discovery, and image-based medical diagnosis).

Many current QML methods remain closely inspired by classical algorithms and therefore do not yet achieve genuine quantum advantage, requiring further developments in

  • quantum-native learning models,
  • efficient quantum kernels and quantum feature mappings,
  • algorithms demonstrating provable or empirical advantages over classical approaches.

Proposals may also include formal complexity analyses, identification of problem classes that can benefit from quantum acceleration.

Developments should address multiple of the following key research directions:

Quantum Supervised Learning (QSL):

Quantum Supervised Learning investigates how quantum algorithms can accelerate or improve the training of supervised learning models, offering novel opportunities to explore quantum–classical learning theories and enabling industry to shorten development cycles and enhance performance in data-intensive domains such as finance, healthcare, and Earth observation. Integrating QSL into existing pipelines may help overcome computational bottlenecks and enable more efficient processing of high-dimensional data

  • Proposals should explore quantum algorithms and quantum subroutines that can be integrated into classical AI pipelines to mitigate computational bottlenecks, improve efficiency in high-dimensional or large-scale settings, and deliver measurable performance gains. Activities should include the development and validation of such methods, with demonstrations in relevant academic or industrial use cases.

Quantum Convolutional Neural Networks (QCNNs)

Quantum Convolutional Neural Networks combine the conceptual strengths of classical convolutional architectures with the computational advantages of quantum processing, offering a promising testbed for exploring expressivity and efficiency in hybrid models and providing industry with a practical pathway to near-term quantum advantage by using QPUs during training while retaining classical inference for scalability and compatibility with existing AI systems

  • Proposals should explore development and evaluation of hybrid QCNN architectures that leverage quantum processing for training, investigate their expressivity, performance and robustness, and demonstrate their applicability to industrial challenges such as pattern recognition, vision-based analytics or complex classification tasks.

Learning with Quantum Models

Quantum models integrate quantum computation directly into both training and inference through parametrised quantum circuits and quantum kernels, enabling advances in understanding quantum data representations, feature expressivity and generalisation theory, while offering industry benefits such as reduced model complexity, faster training cycles and lower data requirements - particularly in data-scarce or high-value domains (e.g. drug discovery, autonomous systems, materials engineering)

  • Proposals should explore the design and evaluation of quantum-native learning models using such circuits and kernels, exploring methods for dimensionality reduction, accelerated training and sample efficiency, as well as extensions toward quantum-enhanced generative models, including diffusion models in applied case studies.

Quantum Reinforcement Learning (QRL)

Quantum Reinforcement Learning investigates how quantum computing can improve the efficiency and scalability of reinforcement learning, offering researchers opportunities to rethink RL fundamentals in high-dimensional or continuous state spaces and providing industry with the potential for faster policy training and more effective exploration strategies (e.g. in robotic, logistics optimisation and adaptive control)

  • Proposals should explore developing quantum or hybrid quantum-classical approaches for reinforcement learning, including quantum-accelerated optimisation for policy search, enhanced exploration mechanisms, and, at more advanced stages, the implementation of quantum agents capable of performing computation during both training and inference.

Quantum Unsupervised Learning

Quantum unsupervised learning explores quantum algorithms capable of detecting latent structures, clusters and patterns in unlabelled data, offering new theoretical insights into quantum-enhanced data analysis and providing industry with potential benefits such as polynomial speedups in tasks like anomaly detection, customer segmentation and predictive maintenance, particularly for complex or high-dimensional datasets where classical methods become computationally prohibitive

  • Proposals should explore advancing quantum algorithms for unsupervised learning, including quantum spectral clustering and related techniques, demonstrating empirical speedups and validating performance on high-dimensional or complex datasets relevant to industrial or research applications.

Quantum AI for Algorithmic Discovery

Quantum AI for algorithmic discovery combines quantum computing with classical machine learning to design new algorithms and computational strategies, enabling researchers to explore vast algorithmic search spaces and develop fundamentally new quantum or hybrid approaches, while offering industry a pathway to automated discovery of optimised algorithms for simulation, optimisation and data-driven modelling (e.g. advanced manufacturing, chemical engineering, cybersecurity and energy systems)

  • Proposals should explore integrating quantum computing with classical AI techniques to automate the discovery and optimisation of algorithms, computational strategies and model architectures, delivering methods, prototypes or benchmarks that reinforce Europe’s leadership in quantum-enhanced AI development.

Collaboration between academia, research infrastructures, industry, SMEs and actors across the European quantum ecosystem is strongly encouraged to ensure wide applicability, rapid technological uptake and sustainable long-term impact. Proposals should demonstrate how the collaborative approach and resulting innovations will contribute to strengthening Europe’s leadership in quantum technologies and in trustworthy, high-performance artificial intelligence.

The proposal must also outline a clear IP plan and licensing strategy under the European Union Public Licence (EUPL-1.2) to safeguard openness and promoting European industrial uptake enabling first exploitation within EU- and Participating States.

Requirements:

  1. Proposals shall take into consideration the state of art of QML and its different key research directions.
  2. All developed software will be made available to the user communities under the European Union Public Licence (EUPL), as the preferred default licence for new software components, or other OSI-approved licences compatible with the EUPL
  3. Proposals are expected to leverage on the code.europa.eu repository and provide relevant software, including necessary supporting data and documentation, via the platform if compatible with the repository’s policy.
  4. Selected consortia are expected to provide systematic feedback to European and international standardisation efforts, including collaboration with CEN/CENELEC, JTC 22 and other relevant working groups;
  5. Selected consortia are expected to closely align with the Quantum Flagship’s Strategic Research and Industry Agenda, and strong collaboration and complementarity with Horizon Europe and EuroHPC quantum projects.

Technology Readiness Level - Technology readiness level expected from completed projects

The rules are described in General Annex B of the Horizon Europe Work Programme 2026-2027.

Activities are expected to start at TRL 3/4 and to achieve TRL 5/6 by the end of the project