Quantum Computing Reaches for True Power

QUIBIT CHIP Four quibits are symmetrically coupled via a capacitive island, the cross in the center.

By JOHN MARKOFF
NYT

In 1981 the physicist Richard Feynman speculated about the possibility of “tiny computers obeying quantum mechanical laws.” He suggested that such a quantum computer might be the best way to simulate real-world quantum systems, a challenge that today is largely beyond the calculating power of even the fastest supercomputers.

Since then there has been sporadic progress in building this kind of computer. The experiments to date, however, have largely yielded only systems that seek to demonstrate that the principle is sound. They offer a tantalizing peek at the possibility of future supercomputing power, but only the slimmest results.

Recent progress, however, has renewed enthusiasm for finding avenues to build significantly more powerful quantum computers. Laboratory efforts in the United States and in Europe are under way using a number of technologies.

Significantly, I.B.M. has reconstituted what had recently been a relatively low-level research effort in quantum computing. I.B.M. is responding to advances made in the past year at Yale University and the University of California, Santa Barbara, that suggest the possibility of quantum computing based on standard microelectronics manufacturing technologies. Both groups layer a superconducting material, either rhenium or niobium, on a semiconductor surface, which when cooled to near absolute zero exhibits quantum behavior.

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