We investigate electron paramagnetic resonance spectra of bismuth-doped silicon, at intermediate magnetic fields B ' 0:1-0:6 T, theoretically and experimentally (with 9.7 GHz X-band spectra). We identify a previously unexplored regime of ''cancellation resonances,'' where a component of the hyperfine coupling is resonant with the external field. We show that this regime has experimentally accessible consequences for quantum information applications, such as reduction of decoherence, fast manipulation of the coupled electron-nuclear qubits, and spectral line narrowing. DOI: 10.1103/PhysRevLett.105.067602 PACS numbers: 76.30.Àv, 03.67.Lx, 71.55.Cn, 76.90.+d Following Kane's suggestion [1] for using phosphorusdoped silicon as a source of qubits for quantum computing, there has been intense interest in such systems [2]. The phosphorus system ( 31 P) is appealing in its simplicity: It represents a simple electron-spin qubit S ¼ 1 2 coupled to a nuclear-spin qubit I ¼ 1 2 via an isotropic hyperfine interaction AI:S of moderate strength ( A 2 ¼ 117:5 MHz). However, recent developments [3-5] point to Si:Bi (bismuth-doped silicon) as a very promising new alternative. Two recent studies measured spin-dephasing times of over 1 ms at 10 K, which is longer than comparable (nonisotopically purified) materials, including Si:P [3,4]. Another group implemented a scheme for rapid (on a time scale of $100 s) and efficient (of order 90%) hyperpolarization of Si:Bi into a single spin state [5].Bismuth has an atypically large hyperfine constant A 2 ¼ 1:4754 GHz and nuclear spin I ¼ 9 2 . This makes its EPR spectra somewhat more complex than for phosphorus, and there is strong mixing of the eigenstates for external field B & 0:6 T. Mixing of Si:P states was studied experimentally in Ref. [6], by means of electrically detected magnetic resonance, but at much lower fields B & 0:02 T. Residual mixing in Si:Bi for B ¼ 2-6 T, where the eigenstates are *99:9% pure uncoupled eigenstates of bothÎ z andŜ z , was also proposed as important for the hyperpolarization mechanism of illuminated Si:Bi [5]. In Ref.[4] it was found that even a $30% reduction in the effective paramagnetic ratio df dB (where f is the transition frequency) leads to a detectable reduction in decoherence rates.Below, we present an analysis of EPR spectra for Si:Bi, testing this against experimental spectra. We identify the points for which df dB ¼ 0, explaining them in a unified manner in terms of a series of EPR ''cancellation resonances''; some are associated with avoided level crossings while others, such as a maximum shown in ENDOR [7] spectra at B % 0:37 T in Ref.[4], are of a quite different origin. These cancellation resonances represent, to the best of our knowledge, an unexplored regime in EPR spectroscopy, arising in systems with exceptionally high A and I. They are somewhat reminiscent of the so-called ''exact cancellation'' regime, widely used in ESEEM spectroscopy [7,8] but differ in essential ways: For instance, they affect both electronic and nuclear freq...
