Compare Papers

Paper 1

On the Necessity of Entanglement for the Explanation of Quantum Speedup

Michael E. Cuffaro

Year
2011
Journal
arXiv preprint
DOI
arXiv:1112.1347
arXiv
1112.1347

In this paper I argue that entanglement is a necessary component for any explanation of quantum speedup and I address some purported counter-examples that some claim show that the contrary is true. In particular, I address Biham et al.'s mixed-state version of the Deutsch-Jozsa algorithm, and Knill & Laflamme's deterministic quantum computation with one qubit (DQC1) model of quantum computation. I argue that these examples do not demonstrate that entanglement is unnecessary for the explanation of quantum speedup, but that they rather illuminate and clarify the role that entanglement does play.

Open paper

Paper 2

Probing the weak interaction between silver and boron.

Choi HW, Kahraman D, Chen WJ, Wang LS

Year
2026
Journal
Chemical science
DOI
10.1039/d5sc08598e
arXiv
-

Understanding the boron-coinage-metal interactions is critical for understanding the nucleation and growth mechanisms of borophene on coinage-metal substrates. Binary metal-boron clusters provide ideal models for obtaining atomic-level information about the metal-boron interactions. Here we report an investigation of the structure and bonding of the AgB cluster as a model system to gain insight into the interaction of boron with silver, the most inert substrate to grow borophene. Photoelectron spectroscopy reveals that the spectra of AgB resemble those of bare B , suggesting extremely weak chemical interactions between Ag and boron. Quantum calculations show that AgB ( , A') consists of a B borozene weakly interacting with a Ag atom on its edge. Chemical bonding analyses find that the Ag atom interacts with the B motif primarily through its 5s orbital with little perturbation to the structure and bonding of the B borozene. Compared to CuB and AuB , Ag is found to have the weakest interaction with B, consistent with the fact that silver substrates are the most inert for borophene syntheses.

Open paper