Unveiling the Defect Structure of Lithium Niobate with Nuclear Methods

Kling, A.; Marques, J.G.

doi:10.3390/cryst11050501

Cited by 7 publications

(8 citation statements)

References 307 publications

(485 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Their structure and behavior upon heating/cooling strongly resembled those obtained by thermal reduction, showing broad features at ~1.6 eV, ~2.6 eV and ~3.2 eV; however, the main band showed trapped-electron character in contrast to the case of low-temperature irradiation where it was rather of trapped-hole type; upon heating there was again a reversible transformation of the main band at ~2.6 eV to the band at ~1.6 eV, whereby the same isosbestic point near 600 nm was observed as for reduced crystals [36,52]. The particle energy threshold found for increased defect formation was 0.3 MeV, corresponding to an oxygen displacement energy of 53 eV, in reasonable agreement with oxygen displacement thresholds in other oxides (see references in [6,52]). No saturation after five over-threshold doses of 2 × 10 18 e/cm 2 could be observed.…”

Section: Defect Generation In Cln By High-energy Irradiation At Highe...supporting

confidence: 80%

“…Originally, the same was also assumed for LiNbO 3 (LN), and most authors did not (and many still do not) have any doubts about simply postulating vacant oxygen sites (V O ) capable of trapping one or two electrons (F + and F-centers, respectively) in discussions of their experiments and proposed applications (see, e.g., [1,2]). The controversy about the availability of oxygen vacancies manifests in the reviews of Sánchez-Dena et al [3,4], is touched upon by some topical reviews [5,6], and is also closely related to the topics of other papers [7][8][9][10][11] of the present Special Issue, and deserves a clarifying discussion.…”

Section: Introductionmentioning

confidence: 74%

See 1 more Smart Citation

‘Horror Vacui’ in the Oxygen Sublattice of Lithium Niobate Made Affordable by Cationic Flexibility

Corradi

Kovács

2021

Crystals

View full text Add to dashboard Cite

The present review is intended to interest a broader audience interested in the resolution of the several decades-long controversy on the possible role of oxygen-vacancy defects in LiNbO3. Confronting ideas of a selected series of papers from classical experiments to brand new large-scale calculations, a unified interpretation of the defect generation and annealing mechanisms governing processes during thermo- and mechanochemical treatments and irradiations of various types is presented. The dominant role of as-grown and freshly generated Nb antisite defects as traps for small polarons and bipolarons is demonstrated, while mobile lithium vacancies, also acting as hole traps, are shown to provide flexible charge compensation needed for stability. The close relationship between LiNbO3 and the Li battery materials LiNb3O8 and Li3NbO4 is pointed out. The oxygen sublattice of the bulk plays a much more passive role, whereas oxygen loss and Li2O segregation take place in external or internal surface layers of a few nanometers.

show abstract

Section: Defect Generation In Cln By High-energy Irradiation At Highe...supporting

confidence: 80%

Section: Introductionmentioning

confidence: 74%

‘Horror Vacui’ in the Oxygen Sublattice of Lithium Niobate Made Affordable by Cationic Flexibility

Corradi

Kovács

2021

Crystals

View full text Add to dashboard Cite

show abstract

“…The minimum yields (

), i. e., the ratio of counts in aligned and random incidence cases, are calculated in this study for a depth of 1

m corresponding to the alpha particle energy range of 7.357 to 7.566 MeV. In lithium niobate, the guiding effect for ions is mainly established by the repelling Coulomb potential of the Nb (Z = 41) atomic chains in all axial directions [ 26 ]. This leaves the chains consisting of Li atoms (Z = 3)—and to a lesser extent those of O (Z = 8)—very sensitive to disturbances in their sub-lattices, which manifest themselves in an increase of the minimum yield with respect to a perfect lattice.…”

Section: Resultsmentioning

confidence: 99%

“…Ion channeling is an important method for the study of lattice defects and dopant lattice location determination and has been intensively applied to the case of LiNbO

(for an extensive review and details on the technique see [ 26 ]). While the Rutherford Backscattering Spectroscopy under channeling conditions is the most widely applied method, the investigation of light elements relies on Nuclear Reaction Analysis (NRA).…”

Section: Introductionmentioning

confidence: 99%

Correlation between Infrared Absorption and Lithium Sublattice Disorder in Magnesium-Doped Lithium Niobate

Kling

2023

Materials

Self Cite

View full text Add to dashboard Cite

Lithium niobate is a ferro- and piezoelectric material with excellent optical properties and a wide variety of applications. The defect structures of congruent and Mg-doped crystals are still under intense discussion. In this work, undoped lithium niobate and magnesium-doped lithium niobate grown from congruent melt with the addition of 0 to 9 mol% MgO were investigated by infrared absorption, establishing the dependence of the absorbance on the Mg-doping level in two bands related to OH− stretching vibrations. The absorption band at 3485 cm−1 peaks at a MgO concentration in melt of 1 mol% and vanishes for MgO concentrations above the threshold level for optical damage suppression (4.8 mol%). A corresponding peak occurs in the minimum yield of the 7Li(p,α)4He reaction during ion channeling measurements, indicating a maximum of disorder in the Li sublattice. A possible explanation for this correlation is the attribution of this absorption band to ilmenite stacking fault sequences instead of isolated NbLi antisites in undoped and low-doped material. On the other hand, the OH− absorption band at 3535 cm−1 stays weak up to the MgO concentration threshold, and then increases, hinting to a defect related to the increase of vacancies due to the lack of charge compensation.

show abstract

“…A similar detailed review on defects in LN and LT crystals studied by nuclear methods has been presented by Kling and Marques [4]. They focus on ion beam methods under channeling conditions for the direct determination of the lattice site of dopants and intrinsic defects.…”

Section: Reviews On Defects In Linbomentioning

confidence: 96%

New Trends in Lithium Niobate: From Bulk to Nanocrystals

Kovács

Corradi

2021

Crystals

View full text Add to dashboard Cite

The recent Special Issue on lithium niobate (LiNbO3) is dedicated to Prof. Schirmer and his topics and contains nineteen papers, out of which seven review various aspects of intrinsic and extrinsic defects in single crystals, thin films, and powdered phases; six present brand-new results of basic research, including two papers on Li(Nb,Ta)O3 mixed crystals; and the remaining six are related to various optical and/or thin film applications.

show abstract

Unveiling the Defect Structure of Lithium Niobate with Nuclear Methods

Cited by 7 publications

References 307 publications

‘Horror Vacui’ in the Oxygen Sublattice of Lithium Niobate Made Affordable by Cationic Flexibility

‘Horror Vacui’ in the Oxygen Sublattice of Lithium Niobate Made Affordable by Cationic Flexibility

Correlation between Infrared Absorption and Lithium Sublattice Disorder in Magnesium-Doped Lithium Niobate

New Trends in Lithium Niobate: From Bulk to Nanocrystals

Contact Info

Product

Resources

About