Why Present a Poster at QUANCOM 2026?
- Visibility with experts: Engage with leading researchers in quantum computing, quantum hardware, quantum software, quantum networking, and quantum applications.
- Feedback that matters: Refine methods, systems, and implementations with targeted feedback from a quantum-savvy audience.
- Bridge theory & practice: Share experimental results, tools, benchmarks, and evaluation frameworks to accelerate reproducible quantum science.
- Build collaborations: Meet potential co-authors, mentors, and industry partners in the quantum computing ecosystem.
What Makes a Strong Poster?
- Clear problem framing & rigorous methodology
- Technical insight (scalability, performance, error rates, resource efficiency)
- Security, reliability, and reproducibility considerations
- Compelling visuals (circuits, benchmarks, experimental results, demos/QR codes)
Posters may present early or late-breaking results, negative results with analysis, work-in-progress, experimental demonstrations, tools, benchmarks, or proof-of-concept implementations.
Topics of Interest
Showcase your work in these exciting areas. Including but not limited to the categories below (see CFP for the full scope).
Experimental Demonstrations & Prototypes
- Proof-of-concept quantum systems and prototypes
- Laboratory demonstrations of quantum algorithms
- Hardware testbeds and experimental setups
- Quantum device characterization and testing
Tools, Frameworks & Development Platforms
- Open-source quantum software tools and libraries
- Quantum development environments and IDEs
- Quantum circuit visualization and design tools
- Quantum emulation and simulation platforms
Case Studies & Industry Pilots
- Real-world quantum computing deployment case studies
- Industry pilot programs and proof-of-value projects
- Lessons learned from quantum project implementations
- Integration challenges and solutions
Educational Resources & Training
- Quantum computing curricula and course materials
- Interactive learning platforms and tutorials
- Educational quantum simulators and tools
- Workforce development and skill-building initiatives
Benchmarking & Performance Analysis
- Quantum benchmark suites and evaluation metrics
- Performance comparison studies across platforms
- Cost-benefit analysis of quantum vs classical approaches
- Scalability studies and resource requirements
Quantum-Classical Integration
- Hybrid quantum-classical system architectures
- API design and integration patterns
- Data pipeline integration and workflows
- Middleware and orchestration solutions
Reproducibility & Open Science
- Reproducible quantum computing experiments
- Open datasets and quantum data repositories
- Open-source quantum software contributions
- Best practices for quantum experiment documentation
Early-Stage Research & Exploratory Work
- Preliminary research findings and initial results
- Exploratory quantum algorithm investigations
- Work-in-progress quantum computing projects
- Emerging quantum computing paradigms
Negative Results & Lessons Learned
- Failed approaches and what didn't work
- Challenges encountered and solutions attempted
- Lessons learned from implementation failures
- Common pitfalls and how to avoid them
Submission Guidelines
- Originality: Original, unpublished work not under review elsewhere.
- Format: Springer LNCS format. Use the official Springer LNCS template.
- Length: Up to 2 pages (including figures, tables, appendices, and references).
- Review: Double-blind. Please anonymize your submission.
- Supplementary: Include artifact/demo links and QR codes for videos or interactive materials (optional but encouraged).
Submissions that exceed the page limit or violate the format may be desk-rejected without review.
Important Dates
Poster Submission
June 6th, 2026
Acceptance Notification
July 29th, 2026
Camera-Ready Submission
August 15th, 2026