Daniel Hader Data-verified
Affiliation confirmed via AI analysis of OpenAlex, ORCID, and web sources.
Researcher
faculty
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Biography and Research Information
OverviewAI-generated summary
Daniel Hader's research centers on theoretical computer science, specifically the abstract tile assembly model. He investigates principles of self-assembly, focusing on how complex structures can be generated from simple components. His work explores concepts such as self-replication, universal shape replication, and the creation of fractal patterns using signal-passing tiles. Hader examines the influence of factors like dimensionality, diffusion, and directedness on simulation models within this framework.
He has published extensively on these topics, with recent work appearing in journals in 2021, 2022, 2023, and 2024, with a forthcoming publication in 2025. Hader collaborates with other researchers at the University of Arkansas at Fayetteville, including Matthew J. Patitz, Andrew Alseth, and Phillip Drake, with whom he has co-authored multiple publications. His scholarly contributions are reflected in an h-index of 3 and 26 total citations across 23 publications.
Metrics
- h-index: 3
- Publications: 23
- Citations: 26
Selected Publications
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Simulation of the abstract Tile Assembly Model using crisscross slats (extended version) (2026)
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Simulation of the Abstract Tile Assembly Model Using Crisscross Slats (2024)
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Universal shape replication via self-assembly with signal-passing tiles (2024)
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Self-replication via tile self-assembly (2024)
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The Impacts of Dimensionality, Diffusion, and Directedness on Intrinsic Cross-Model Simulation in Tile-Based Self-Assembly (2024)
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The Impacts of Dimensionality, Diffusion, and Directedness on Intrinsic Cross-Model Simulation in Tile-Based Self-Assembly (2023)
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The Impacts of Dimensionality, Diffusion, and Directedness on Intrinsic Cross-Model Simulation in Tile-Based Self-Assembly (2023)
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Fractal dimension of assemblies in the abstract tile assembly model (2023)
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Universal Shape Replication Via Self-Assembly With Signal-Passing Tiles (2023)
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Universal Shape Replication Via Self-Assembly With Signal-Passing Tiles (2022)
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Fractal Dimension of Assemblies in the Abstract Tile Assembly Model (2021)
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Self-Replication via Tile Self-Assembly (2021)
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Self-Replication via Tile Self-Assembly (Extended Abstract) (2021)
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Geometric tiles and powers and limitations of geometric hindrance in self-assembly (2021)
Collaboration Network
Top Collaborators
- Geometric tiles and powers and limitations of geometric hindrance in self-assembly
- Self-Replication via Tile Self-Assembly
- Fractal Dimension of Assemblies in the Abstract Tile Assembly Model
- Universal Shape Replication Via Self-Assembly With Signal-Passing Tiles
- The Impacts of Dimensionality, Diffusion, and Directedness on Intrinsic Cross-Model Simulation in Tile-Based Self-Assembly
Showing 5 of 17 shared publications
- Self-Replication via Tile Self-Assembly
- Universal Shape Replication Via Self-Assembly With Signal-Passing Tiles
- Self-Replication via Tile Self-Assembly
- Universal shape replication via self-assembly with signal-passing tiles
- Self-Replication via Tile Self-Assembly (Extended Abstract)
Showing 5 of 7 shared publications
- Fractal Dimension of Assemblies in the Abstract Tile Assembly Model
- Fractal dimension of assemblies in the abstract tile assembly model
- Simulation of the Abstract Tile Assembly Model Using Crisscross Slats
- Simulation of the abstract Tile Assembly Model using crisscross slats (extended version)
- Strict Self-Assembly of Discrete Self-Similar Fractals in the abstract Tile Assembly Model
- Strict Self-Assembly of Discrete Self-Similar Fractals in the Abstract Tile Assembly Model
- Strict Self-Assembly of Discrete Self-Similar Fractals in the Abstract Tile Assembly Model
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