The
mixed cation compounds Na1–x
K
x
AsSe2 (x = 0.8,
0.65, 0.5) and Na0.1K0.9AsS2 crystallize
in the polar noncentrosymmetric space group Cc. The AAsQ
2 (A =
alkali metals, Q = S, Se)
family features one-dimensional (1D) 1/∞[AQ
2
–] chains comprising
corner-sharing pyramidal AQ
3 units in
which the packing of these chains is dependent on the alkali metals.
The parallel 1/∞[AQ
2
–] chains interact via short As···Se
contacts, which increase in length when the fraction of K atoms is
increased. The increase in the As···Se interchain distance
increases the band gap from 1.75 eV in γ-NaAsSe2 to
2.01 eV in Na0.35K0.65AsSe2, 2.07
eV in Na0.2K0.8AsSe2, and 2.18 eV
in Na0.1K0.9AsS2. The Na1–x
K
x
AsSe2 (x = 0.8, 0.65) compounds melt congruently at approximately
316 °C. Wavelength-dependent second harmonic generation (SHG)
measurements on powder samples of Na1–x
K
x
AsSe2 (x = 0.8, 0.65, 0.5) and Na0.1K0.9AsS2 suggest that Na0.2K0.8AsSe2 and
Na0.1K0.9AsS2 have the highest SHG
response and exhibit significantly higher laser-induced damage thresholds
(LIDTs). Theoretical SHG calculations on Na0.5K0.5AsSe2 confirm its SHG response with the highest value
of d
33 = 22.5 pm/V (χ333
(2) = 45.0 pm/V).
The effective nonlinearity for a randomly oriented powder is calculated
to be d
eff = 18.9 pm/V (χeff
(2) = 37.8 pm/V),
which is consistent with the experimentally obtained value of d
eff = 16.5 pm/V (χeff
(2) = 33.0 pm/V). Three-photon
absorption is the dominant mechanism for the optical breakdown of
the compounds under intense excitation at 1580 nm, with Na0.2K0.8AsSe2 exhibiting the highest stability.
Coupling between a magnetic impurity and an external bath can give rise to many-body quantum phenomena, including Kondo and Hund's impurity states in metals, and Yu-Shiba-Rusinov states in superconductors. While advances have been made in probing the magnetic properties of d-shell impurities on surfaces, the confinement of f orbitals makes them difficult to access directly. Here we show that a 4f driven Kondo resonance can be modulated spatially by asymmetric coupling between a metallic surface and a molecule containing a 4f-like moment. Strong hybridization of dysprosium double-decker phthalocyanine with Cu(001) induces Kondo screening of the central magnetic moment. Misalignment between the symmetry axes of the molecule and the surface induces asymmetry in the molecule's electronic structure, spatially mediating electronic access to the magnetic moment through the Kondo resonance. This work demonstrates the important role that molecular ligands have in mediating electronic and magnetic coupling and in accessing many-body quantum states.
The second quantum revolution harnesses exquisite quantum control for a slate of diverse applications including sensing, communication, and computation. Of the many candidates for building quantum systems, molecules offer both...
Infrared laser systems are vital for applications in spectroscopy, communications, and biomedical devices, where infrared nonlinear optical (NLO) crystals are required for broadband frequency down‐conversion. Such crystals need to have high non‐resonant NLO coefficients, a large bandgap, low absorption coefficient, and phase‐matchability among other competing demands; for example, a larger bandgap leads to smaller NLO coefficients. Here, the successful growth of single crystals of γ ‐NaAsSe2 that exhibit a giant second harmonic generation (SHG) susceptibility of d11 = 590 pm V−1 at 2 µm wavelength is reported; this is ~18 times larger than that of commercial AgGaSe2 while retaining a similar bandgap of ~1.87 eV, making it an outstanding candidate for quasi‐phase‐matched devices utilizing d11. In addition, γ ‐NaAsSe2 is both Type I and Type II phase‐matchable, and has a transparency range up to 16 µm wavelength. Thus, γ ‐NaAsSe2 is a promising bulk NLO crystal for infrared laser applications.
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