T
Thomas Fernholz
Researcher at University of Nottingham
Publications - 51
Citations - 2289
Thomas Fernholz is an academic researcher from University of Nottingham. The author has contributed to research in topics: Ultracold atom & Interferometry. The author has an hindex of 24, co-authored 50 publications receiving 2146 citations. Previous affiliations of Thomas Fernholz include University of Amsterdam & University of Copenhagen.
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Simultaneous in situ measurement of CO, H2O, and gas temperatures in a full-sized coal-fired power plant by near-infrared diode lasers.
TL;DR: This work presents what is to their knowledge the first near-infrared diode-laser-based absorption spectrometer that is suitable for simultaneous in situ measurement of carbon monoxide, water vapor, and temperature in the combustion chamber of a 600-MW lignite-fired power plant.
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Deterministic quantum teleportation between distant atomic objects
H. Krauter,D. Salart,Christine A. Muschik,Jonas M. Petersen,Heng Shen,Thomas Fernholz,Eugene S. Polzik +6 more
TL;DR: In this article, the authors demonstrate the deterministic continuous-variable teleportation between two atomic ensembles at room temperature, which makes it possible to teleport time-evolving quantum states from one ensemble to the other.
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Quantum memory for entangled continuous-variable states
Kasper Jensen,Wojciech Wasilewski,Wojciech Wasilewski,H. Krauter,Thomas Fernholz,Thomas Fernholz,Bo Melholt Nielsen,Masaki Owari,Martin B. Plenio,Alessio Serafini,Michael M. Wolf,Eugene S. Polzik +11 more
TL;DR: In this article, a method for storing continuous variable states of light for up to a millisecond in room-temperature memories is demonstrated, where the state of light can also carry data.
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Digital, phase-sensitive detection for in situ diode-laser spectroscopy under rapidly changing transmission conditions
TL;DR: In this article, a new harmonic detection scheme for fully digital, fast-scanning wavelength-modulation spectroscopy (DFS-WMS) was presented for in situ absorption measurements in combustion environments under fast fluctuating transmission conditions.
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Spin Squeezing of Atomic Ensembles via Nuclear-Electronic Spin Entanglement
Thomas Fernholz,Hanna Krauter,Kasper Jensen,Jacob F. Sherson,Anders S. Sørensen,Eugene S. Polzik +5 more
TL;DR: Spin squeezing in a room temperature ensemble of approximately 10(12) cesium atoms using their internal structure, where the necessary entanglement is created between nuclear and electronic spins of each individual atom, provides improvement in measurement sensitivity beyond the standard quantum limit.