Two‐photon excitation of excitons in CuCl in total reflection geometry

Hasuo, Masahiro; Shimamoto, Atsuyoshi; Fujimoto, Takashi

doi:10.1046/j.1365-2818.2003.01120.x

Cited by 3 publications

(1 citation statement)

References 15 publications

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“…At present, non-linear EF techniques represent a tiny, if growing, fraction of the recent TIRF literature. 2PEF EF spectroscopy [36][37][38][39][40], two-photon EW pattern photobleaching [22] and 2PEF EF microscopy [20,[41][42][43][44] combine the optical sectioning capacity of EF imaging with a number of advantages that derive from the quadratic intensity dependence of 2PEF (figure 4, bottom): (1) The restriction of fluorescence excitation to a well-defined planar excitation volume V 2ω = 2πw 2 r w z (ϑ)/cos(ϑ) that can be defined in analogy to the familiar cigar-shaped 2PEF excitation volume [20] (see section 2.2). ( 2) The suppression of background fluorescence from scattered excitation photons (figure 5).…”

Section: Benefits From Non-linear Opticsmentioning

confidence: 99%

Non-linear evanescent-field imaging

Oheim¹,

Schapper²

2005

J. Phys. D: Appl. Phys.

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Total internal reflection fluorescence (TIRF), a general term that embraces any spectroscopic or microscopic technique based on the evanescent field created by TIR of light, is further establishing itself as an important tool for studying near-surface phenomena. Impingement of a femtosecond-pulsed infrared beam on a reflecting interface creates the conditions for ‘macroscopic’ evanescent-field two-photon fluorescence excitation. The two-photon fluorescence excitation volume is confined by both the non-linearity of the multi-photon process and the spatial inhomogeneity of the evanescent field. The absence of scattered excitation resulting in a low background and the possibility of simultaneous multi-colour fluorescence excitation should make non-linear evanescent-field excitation particularly attractive for quantitative single-molecule observation and ultra-sensitive screening assays. In this topical review, we survey the requirements, present the current results and explore the potential of this novel non-linear microscopy.

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Section: Benefits From Non-linear Opticsmentioning

confidence: 99%

Non-linear evanescent-field imaging

Oheim¹,

Schapper²

2005

J. Phys. D: Appl. Phys.

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Effects of enhanced electronic correlation on magnetic properties of light non-metallic element (B, C, N, and O)-doped CuCl: A first-principles study

et al. 2014

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First principles and Monte Carlo study of Mn-doped CuCl/CuBr as room-temperature ferromagnetism materials

Chen

2012

Journal of Applied Physics

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The magnetic properties of Mn-doped CuCl and CuBr are investigated by first-principles calculations and Monte Carlo simulation. With 3.125% doping, Mn 3d orbitals exhibit significant spin splitting and hybridize strongly with Cu 4d and Cl (Br) 3p orbitals, resulting in a net magnetic moment of 4.619 and 4.580 μB in CuCl and CuBr, respectively. The formation energy is 255.5 MeV for CuCl and 400.5 MeV for CuBr, indicating that Mn doping can be easily realized in the experiment. With 6.25% doping, ferromagnetic ground state is favored in most of the doping configurations. The Curie temperature is estimated at 420 K for CuCl and 275 K for CuBr by Monte Carlo simulation. Thus Mn-doped CuCl and CuBr are promising candidates for room-temperature ferromagnetic materials. The ferromagnetism of the two systems can be explained by a hole-mediated double exchange mechanism.

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Two‐photon excitation of excitons in CuCl in total reflection geometry

Cited by 3 publications

References 15 publications

Non-linear evanescent-field imaging

Non-linear evanescent-field imaging

Effects of enhanced electronic correlation on magnetic properties of light non-metallic element (B, C, N, and O)-doped CuCl: A first-principles study

First principles and Monte Carlo study of Mn-doped CuCl/CuBr as room-temperature ferromagnetism materials

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