H. Aghaee, B. Akhbari, Classical-Quantum Multiple Access Wiretap Channel. In 2019 16th International ISC (Iranian Society of Cryptology) Conference on Information Security and Cryptology (ISCISC), pages 99–103. IEEE, 2019.
H. Aghaee, B. Akhbari, Three-User Classical-Quantum Interference Channels with secrecy constraints: a Mixed Strong-Very Strong Interference. In 10th Information and Knowledge Technology Conference (IKT2019), 2019.
H. Aghaee, B. Akhbari, Private Classical Information Over a Quantum Multiple Access Channel: One-Shot Secrecy Rate Region. In 2020 10th International Symposium on Telecommunications (IST), pages 222–226. IEEE, 2020.
H. Aghaee, B. Akhbari, Classical-Quantum Multiple Access Channel with Secrecy Constraint: One-Shot Rate Region. International Journal of Information and Communication Technology Research, 12(2):1–10, 2020.
H. Aghaee, B. Akhbari, Classical-Quantum Multiple Access Wiretap Channel with Common Message: One-Shot Rate Region. In 2020 11th International Conference on Information and Knowledge Technology (IKT), pages 55–61. IEEE, 2020.
H. Aghaee, B. Akhbari, One-Shot Achievable Secrecy Rate Regions for Quantum Interference Wiretap Channel. The ISC International Journal of Information Security (ISeCure), 14(3):71–80, 2022.
H. Aghaee, B. Akhbari, Entanglement-Assisted Classical-Quantum Multiple Access Wiretap Channel: One-shot Achievable Rate Region. In 2022 30th International Conference on Electrical Engineering (ICEE), pages 693–699. IEEE, 2022.
H. Aghaee, B. Akhbari, Quantum Multiple Access Wiretap Channel: On the One-Shot Achievable Secrecy Rate Regions. The ISC International Journal of Information Security (ISeCure), 15(3), 2023. doi: 10.22042/isecure. 2023.180848
J. Hawellek, A. Mohan, H. Aghaee, and C. Deppe, The Interference Channel with Entangled Transmitters. arXiv:2411.10067 [quant-ph], 2024.
H. Aghaee and C. Deppe, On Oblivious Transfer Capacity of Noisy Multiple Access Channel. arXiv:2501.17021 [cs.IT], 2025.
J. Hawellek, A. Mohan, H. Aghaee, and C. Deppe, The Interference Channel with Entangled Transmitters. Accepted in 2025 IEEE International Symposium on Information Theory (ISIT 2025), 2025.
H. Aghaee and C. Deppe, On Oblivious Transfer Capacity of Noisy Multiple Access Channel. Accepted in 2025 IEEE International Symposium on Information Theory (ISIT 2025), 2025.
Lectures
1- Public and Private Classical Communications over Quantum Multiple Access Channels (QMACs): Decoding Techniques, and Bottlenecks (i.i.d./one-shot regimes)-Institute of Communications Engineering, Technical University of Munich-April 2023
2- Network Oblivious Transfer: OT over MAC-QuaPhySi project meeting-Technical University of Braunschweig-January 2025
