Paper

Phys. Chem. Chem. Phys., 2008, 10, 5388 - 5393, DOI: 10.1039/b804804e

---

Quantum algorithm for obtaining the energy spectrum of molecular systems

Hefeng Wang, Sabre Kais, Alán Aspuru-Guzik and Mark R. Hoffmann

---

Simulating a quantum system is more efficient on a quantum computer than on a classical computer. The time required for solving the Schrödinger equation to obtain molecular energies has been demonstrated to scale polynomially with system size on a quantum computer, in contrast to the well-known result of exponential scaling on a classical computer. In this paper, we present a quantum algorithm to obtain the energy spectrum of molecular systems based on the multiconfigurational self-consistent field (MCSCF) wave function. By using a MCSCF wave function as the initial guess, the excited states are accessible. Entire potential energy surfaces of molecules can be studied more efficiently than if the simpler Hartree–Fock guess was employed. We show that a small increase of the MCSCF space can dramatically increase the success probability of the quantum algorithm, even in regions of the potential energy surface that are far from the equilibrium geometry. For the treatment of larger systems, a multi-reference configuration interaction approach is suggested. We demonstrate that such an algorithm can be used to obtain the energy spectrum of the water molecule.

About this Journal

• Journal Home
• About the Journal

Read the Journal

• Advance Articles
• Browse Issues
• Search RSC Journals
• RSC Prospect Structure Search
• E-Alerts Service
• RSS feed

ReSourCe

• Submit an Article
• Author Guidelines
• Ethical Guidelines
• Copyright & Permissions
• Referee Report Forms

Explore the Journal

• Hot Articles
• Cover Gallery
• Top 10
• People and Contacts

Customer Services

• Subscriptions
• Advertising
• Librarians

Tools