M
Martin M. Fejer
Researcher at Stanford University
Publications - 1227
Citations - 104666
Martin M. Fejer is an academic researcher from Stanford University. The author has contributed to research in topics: Lithium niobate & Gravitational wave. The author has an hindex of 123, co-authored 1190 publications receiving 88708 citations. Previous affiliations of Martin M. Fejer include Laser Interferometer Gravitational Wave Observatory & University of Florida.
Papers
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Journal ArticleDOI
Cascaded frequency upconversion for high-speed single-photon detection at 1550 nm.
TL;DR: Modifications of this device are suitable for downconversion of single photons from visible-wavelength quantum emitters into the telecom band and for detection by low-timing-jitter silicon single-photon avalanche photodiodes (APDs).
Journal ArticleDOI
Nonlinear physical optics with transversely patterned quasi-phase-matching gratings
TL;DR: In this paper, the amplitude and phase of a second-harmonic beam in multiple slit diffraction devices and in quasi-phase-matching (QPM) lenses are demonstrated.
Proceedings ArticleDOI
Visible quasi-phase-matched harmonic generation by electric-field-poled lithium niobate
TL;DR: In this paper, the authors present a model which is used to identify the optimum electrode duty cycle and applied poling field for domain patterning and compare the predicted domain duty cycle with experimental results.
Journal ArticleDOI
GaAs optical parametric oscillator with circularly polarized and depolarized pump
Paulina S. Kuo,Konstantin L. Vodopyanov,Martin M. Fejer,Xiaojun Yu,James S. Harris,David Bliss,David W. Weyburne +6 more
TL;DR: An optical parametric oscillator based on GaAs pumped with linearly polarized and circularly polarized light is demonstrated and it is shown that the relative OPO thresholds agree with theoretical expectations.
Journal ArticleDOI
Noncritical phase matching for guided‐wave frequency conversion
TL;DR: In this paper, the phase matching is made noncritical with respect to small changes in dimensions, which results in larger fabrication tolerances, facilitating the practical realization of nonlinear devices with long interaction lengths.