diff --git a/content/publication/dahlberg-netqasm-2021/dahlberg-netqasm-2021.bib b/content/publication/dahlberg-netqasm-2021/dahlberg-netqasm-2021.bib new file mode 100644 index 0000000..06fb2d9 --- /dev/null +++ b/content/publication/dahlberg-netqasm-2021/dahlberg-netqasm-2021.bib @@ -0,0 +1,6 @@ +@article{dahlberg2021netqasm, + author={Dahlberg, Axel and van der Vecht, Bart and Donne, Carlo Delle and Skrzypczyk, Matthew and Raa, Ingmar te and Kozlowski, Wojciech and Wehner, Stephanie}, + title={NetQASM--A low-level instruction set architecture for hybrid quantum-classical programs in a quantum internet}, + year={2021} + journal={arXiv preprint arXiv:2111.09823}, +} diff --git a/content/publication/dahlberg-netqasm-2021/index.md b/content/publication/dahlberg-netqasm-2021/index.md new file mode 100644 index 0000000..0836a6a --- /dev/null +++ b/content/publication/dahlberg-netqasm-2021/index.md @@ -0,0 +1,10 @@ ++++ +title = "NetQASM -- A low-level instruction set architecture for hybrid quantum-classical programs in a quantum internet" +date = 2021-11-18 +authors = ["Axel Dahlberg", "Bart van der Vecht", "Carlo Delle Donne", "Matthew Skrzypczyk", "Ingmar te Raa", "Wojciech Kozlowski", "Stephanie Wehner"] +publication_types = ["3"] +abstract = "We introduce NetQASM, a low-level instruction set architecture for quantum internet applications. NetQASM is a universal, platform-independent and extendable instruction set with support for local quantum gates, powerful classical logic and quantum networking operations for remote entanglement generation. Furthermore, NetQASM allows for close integration of classical logic and communication at the application layer with quantum operations at the physical layer. This enables quantum network applications to be programmed in high-level platform-independent software, which is not possible using any other QASM variants. We implement NetQASM in a series of tools to write, parse, encode and run NetQASM code, which are available online. Our tools include a higher-level SDK in Python, which allows an easy way of programming applications for a quantum internet. Our SDK can be used at home by making use of our existing quantum simulators, NetSquid and SimulaQron, and will also provide a public interface to hardware released on a future iteration of Quantum Network Explorer." +featured = false +url_preprint = "https://arxiv.org/abs/2111.09823" ++++ + diff --git a/content/publication/pompili-experimental-2021/featured.png b/content/publication/pompili-experimental-2021/featured.png new file mode 100644 index 0000000..90ae76e Binary files /dev/null and b/content/publication/pompili-experimental-2021/featured.png differ diff --git a/content/publication/pompili-experimental-2021/index.md b/content/publication/pompili-experimental-2021/index.md new file mode 100644 index 0000000..abe78ac --- /dev/null +++ b/content/publication/pompili-experimental-2021/index.md @@ -0,0 +1,10 @@ ++++ +title = "Experimental demonstration of entanglement delivery using a quantum network stack" +date = 2021-11-22 +authors = ["Matteo Pompili", "Carlo Delle Donne", "Ingmar te Raa", "Bart van der Vecht", "Matthew Skrzypczyk", "Guilherme Ferreira", "Lisa de Kluijver", "Arian J. Stolk", "Sophie L. N. Hermans", "Przemysław Pawełczak", "Wojciech Kozlowski", "Ronald Hanson", "Stephanie Wehner"] +publication_types = ["3"] +abstract = "Scaling current quantum communication demonstrations to a large-scale quantum network will require not only advancements in quantum hardware capabilities, but also robust control of such devices to bridge the gap to user demand. Moreover, the abstraction of tasks and services offered by the quantum network should enable platform-independent applications to be executed without knowledge of the underlying physical implementation. Here we experimentally demonstrate, using remote solid-state quantum network nodes, a link layer and a physical layer protocol for entanglement-based quantum networks. The link layer abstracts the physical-layer entanglement attempts into a robust, platform-independent entanglement delivery service. The system is used to run full state tomography of the delivered entangled states, as well as preparation of a remote qubit state on a server by its client. Our results mark a clear transition from physics experiments to quantum communication systems, which will enable the development and testing of components of future quantum networks." +featured = true +url_preprint = "https://arxiv.org/abs/2111.11332" ++++ + diff --git a/content/publication/pompili-experimental-2021/pompili-experimental-2021.bib b/content/publication/pompili-experimental-2021/pompili-experimental-2021.bib new file mode 100644 index 0000000..62b1e0b --- /dev/null +++ b/content/publication/pompili-experimental-2021/pompili-experimental-2021.bib @@ -0,0 +1,6 @@ +@article{pompili_experimental_2021, + author={Pompili, Matteo and Donne, Carlo Delle and Raa, Ingmar te and van der Vecht, Bart and Skrzypczyk, Matthew and Ferreira, Guilherme and de Kluijver, Lisa and Stolk, Arian J and Hermans, Sophie LN and Pawe{\l}czak, Przemys{\l}aw and others}, + title={Experimental demonstration of entanglement delivery using a quantum network stack}, + year={2021} + journal={arXiv preprint arXiv:2111.11332}, +}