Useful Resources
Intro to quantum computing
Quantum Computers - Quanta and Scott Aaronson (~10m video)
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Silicon Photonic Quantum Computing - Jeremy O'Brien (~25m video)
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Useful Quantum Computing - Pete Shadbolt (~20m video)
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Quantum Computing for Climate Change - McKinsey (~10m read)
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How Quantum Computing can help tackle global warming (An interview of PsiQuantum CEO Jeremy O'Brien) - McKinsey (~10m read)
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Non-technical articles
Detailed technical talks
Unique architectures for photonic quantum computing - High-level overview of architectures for fault-tolerant optical quantum computing (Naomi Nickerson, FTQC, 2020)
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Intro to fault tolerance (Naomi Nickerson 2019)
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Measurement based fault tolerance beyond foliation - High-level overview of some unique possibilities around doing fault tolerance with photonics (Naomi Nickerson, QEC 2019)
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Fusion-Based Quantum Computing - Overview of the underlying quantum architecture (Mihir Pant, 2021)
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QIP2021 Tutorial: Architectures for fault tolerant quantum computing - Detailed tutorial on fault-tolerant architectures (Naomi Nickerson, 2021)
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Frontiers of Quantum Science – Terry Rudolph - Lecture 1
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Frontiers of Quantum Science – Terry Rudolph - Lecture 2
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Frontiers of Quantum Science – Terry Rudolph - Lecture 3
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Technical papers
Fusion-based quantum computation - Most recent technical paper, covering some aspects of our fault-tolerant architecture (Sara Bartolucci et al., 2021)
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Suppressing quantum errors by scaling a surface code logical qubit (Google Quantum AI, 2023)
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Why I am optimistic about the silicon-photonic route to quantum computing - technical advantages and challenges of photonic quantum computing (Terry Rudolph, 2016)
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Linear optical quantum computing with photonic qubits (Pieter Kok et al., 2007)
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Loss-tolerant teleportation on large stabilizer states (Terry Rudolph et al., 2018)
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A variational eigenvalue solver on a photonic quantum processor (Peruzzo et al., 2014)
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Photonic quantum technologies (O’Brien, 2009)
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Linear optical quantum computing with photonic qubits (Carolan et al., 2015)
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Large-scale silicon quantum photonics implementing arbitrary two-qubit processing (Qiang et al., 2018)
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