Interactive visualizations and experiments demonstrating quantum network phenomena
Our interactive experiments provide intuitive visualizations of complex quantum network phenomena. These demonstrations help bridge the gap between theoretical understanding and practical implementation, allowing researchers and students to explore quantum concepts in a hands-on way.
Each experiment includes adjustable parameters that can be modified in real-time to observe their effects on quantum systems. The complexity level control in the top navigation allows you to adjust the depth of information presented, from basic conceptual overviews to detailed technical explanations.
This experiment demonstrates quantum teleportation, a process that transfers quantum information from one location to another using quantum entanglement and classical communication.
The visualization shows how quantum states are prepared, entangled, measured, and reconstructed across separated systems, achieving information transfer that would be impossible with classical systems alone.
This experiment explores temporal anomalies in quantum networks, where quantum correlations appear to violate classical time ordering.
The visualization demonstrates how entangled quantum systems can exhibit correlation patterns that challenge our intuitive understanding of causality and time, with potential applications for quantum network timing protocols.
This experiment demonstrates information clustering in quantum networks, where coherent information structures emerge across distributed quantum nodes.
The visualization shows how quantum information distributes across a network, forms coherent clusters, and exhibits emergent properties that could be harnessed for distributed quantum computing.
Our quantum experiment visualizations are built on a multi-layer simulation architecture:
While these visualizations are simplifications of actual quantum phenomena, they accurately represent the key properties and behaviors observed in our research, making complex quantum concepts more accessible.
These interactive experiments are built using a combination of technologies:
The source code for these visualizations is available in our open-source repository, allowing researchers to modify and extend the experiments for their own purposes.
These interactive experiments are based on our ongoing research in quantum networks. Below are key findings from our experimental work:
Our research has demonstrated quantum teleportation with 94% fidelity over existing fiber optic infrastructure at distances up to 35km without dedicated quantum repeaters.
View Research PaperWe've observed non-classical temporal correlation patterns in quantum networks that violate Bell inequalities across time, with potential applications for quantum network synchronization.
View Research PaperOur quantum networks demonstrate emergent clustering behavior where quantum information spontaneously organizes into coherent structures across distributed nodes.
View Research PaperWe've developed protocols for optimizing quantum resource allocation in hybrid networks that combine quantum and classical communication channels.
View Research Paper