Frank Gäbler scite author profile

Single phase powders of (Sr3N)Sb, (Sr3N)Bi ($Pm{\bar 3}m$, No. 221, Z = 1, Sb: a = 517.25(2) pm, V = 138.390(8) · 106 pm3, Bi: a = 520.691(8) pm, V = 141.170(4) · 106 pm3), (Ba3N)Sb, and (Ba3N)Bi (P63/mmc, No. 194, Z = 2, Sb: a = 753.33(3) pm, c = 664.45(3) pm, V = 326.56(2) · 106 pm3, Bi: a = 761.28(4) pm, c = 668.05(3) pm, V = 335.30(2) · 106 pm3) were obtained from reactions of melt beads of the respective elements with bulk compositions of A3E (A = Sr, Ba; E = Sb, Bi) in nitrogen atmosphere of ambient pressure at T = 1070 K (Sr) and T = 1120 K (Ba). The compositions were derived from chemical analyses and supported by Rietveld refinements based on powder X‐ray diffraction patterns. The Sr containing compounds crystallize in the cubic anti‐perovskite type arrangement, the Ba containing compounds in the hexagonal anti‐BaNiO3 structure type. Magnetic susceptibility and electrical resistivity data indicate that the compounds are diamagnetic semiconductors. The optical band gaps of (Sr3N)Sb and (Sr3N)Bi were determined by diffuse reflectivity to 1.15 eV and 0.89 eV, respectively. The experimental results are in agreement with electronic structure calculations. Chemical bonding is characterized in a simplified picture as ionic with significant orbital mixing.

show abstract

(Sr₃N_x)E and (Ba₃N_x)E (E = Sn, Pb): Preparation, Crystal Structures, Physical Properties and Electronic Structures

Gäbler¹,

Kirchner²,

Schnelle³

et al. 2005

Zeitschrift anorg allge chemie

View full text Add to dashboard Cite

Black powders of (Sr3Nx)Sn (x = 0.74(2), a = 523.51(5) pm), (Ba3Nx)Sn (x = 0.62(2), a = 552.93(1) pm), (Sr3Nx)Pb (x = 0.81(3), a = 524.22(1) pm) and (Ba3Nx)Pb (x = 0.826(4), a = 554.40(3) pm, Pm3¯m, No. 221, Z = 1) were obtained from reactions of melt beads of the respective metals with bulk compositions of A3E (A = Sr, Ba; E = Sn, Pb) in nitrogen atmosphere at temperatures in the range of 970 K ‐ 1220 K. The compositions were derived from chemical analyses, supported by Rietveld refinements based on powder X‐ray and neutron diffraction patterns taken on (Ba3Nx)Sn (x = 0.64(1); neutron diffraction: RBragg = 8.70 %, RF = 6.10 %; X‐ray diffraction: RBragg = 11.60 %, RF = 12.00 %). The phases crystallize in cubic anti‐perovskite type arrangements. Measurements of the magnetic susceptibility indicate a nearly temperature independent paramagnetism. The electrical resistivities are weakly temperature dependent with resistivities at 300 K in the order of 1 mΩ·cm. Electronic structure calculations on ordered superstructures of the composition (A3N2/3)E reveal the phases as intrinsic metals and suggest the tendency towards higher nitrogen site occupation (x > ⅔).

show abstract

(La₃ Z _x)Al and (Ce₃ Z _x)Al with Z = C, N, O: preparation, physical properties and chemical bonding of metal-rich perovskites

Kirchner

Gäbler

Schnelle

et al. 2006

View full text Add to dashboard Cite

Abstract. The inverse cubic Perovskites (La 3 O)Al, (La 3 N)Al, (Ce 3 O)Al, and (Ce 3 N)Al are reported together with the solid solution series (Ce 3 C 1-x N x )Al. The crystal structure of (La 3 N)Al is analyzed in detail based on single crystal X-ray diffraction data (Space group Pm 3 m, a = 509.04(1) pm, Z = 1, R gt (F) = 0.008, wR(F 2 ) = 0.018). Combined X-ray powder diffraction and thermal analysis studies on samples with various N and O contents indicate only small tolerance of the ternary compounds towards Z = N, O deficiency and small solubility of Z in hexagonal α-Ce 3 Al. Indications for the existence of a cubic β-Ce 3 Al with Cu 3 Au structure type could not be derived from any experiment. All studied phases are metals, the Ce compounds contain the rare-earth metal in Ce(4f 1 ) states according to X-ray absorption spectroscopy and measurements of the magnetic susceptibilities. The Ce moments order antiferromagnetically with T N decreasing and scaling with increasing unit cell dimension of the compounds. Electronic band structure calculations reveal a trend to increased mixing of Z and La states on going from Z = O via N to C. Formation of a band gap even in the formally electronically balanced (La 3 C)Al is mainly prohibited by insufficient charge transfer between the metal species.

show abstract

Stacking Design of Inverse Perovskites: The Systems (Sr₃_-_xBa_xN)E, E = Bi, Sb

Gäbler

Niewa

2007

Inorg. Chem.

View full text Add to dashboard Cite

The first representatives of 4H (BaMnO3-type structure, P63/mmc, Z = 4) and 9R (BaMnO3-type structure, Rm, Z = 9) inverse Perovskite phases are presented. The phases are obtained within the solid solutions (Sr3-xBaxN)E with E = Bi, Sb. The crystal structures and homogeneity ranges were studied by combined X-ray and neutron diffraction as well as chemical analyses. The cubic Perovskite phase with Bi (Sb) is stable in the range of 0.00 < or = x < or = 0.90(5) (0.00 < or = x < or = 1.30(5)), the 4H variant is stable for 1.55(5) < or = x < or = 2.10(5) (1.85(5) < or = x < or = 2.45(5)), the 9R structure is stable for 2.50(2) < or = x < or = 2.55(2) (2.56(2) < or = x < or = 2.60(2)), and the 2H phase is stable for 2.75(5) < or = x < or = 3.00 (2.80(5) < or = x < or = 3.00). Ba occupies preferable sites in the hexagonal stacking of close packed layers of alkaline earth metal ions and E3-; Sr is mainly located in cubic stacked layers. The phase order upon going from cubic (Sr3N)E to 2H-type (Ba3N)E concomitant to the pronounced Sr/Ba partial order can, in general, be rationalized considering the Coulomb repulsion of nitride ions, as well as the size and charge density of the alkaline earth metal ions.

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Frank Gäbler

(Sr₃N)E and (Ba₃N)E (E = Sb, Bi): Synthesis, Crystal Structures, and Physical Properties

(Sr₃N_x)E and (Ba₃N_x)E (E = Sn, Pb): Preparation, Crystal Structures, Physical Properties and Electronic Structures

(La₃ Z _x)Al and (Ce₃ Z _x)Al with Z = C, N, O: preparation, physical properties and chemical bonding of metal-rich perovskites

Stacking Design of Inverse Perovskites: The Systems (Sr₃_-_xBa_xN)E, E = Bi, Sb

Contact Info

Product

Resources

About

Frank Gäbler

(Sr3N)E and (Ba3N)E (E = Sb, Bi): Synthesis, Crystal Structures, and Physical Properties

(Sr3Nx)E and (Ba3Nx)E (E = Sn, Pb): Preparation, Crystal Structures, Physical Properties and Electronic Structures

(La3 Z x)Al and (Ce3 Z x)Al with Z = C, N, O: preparation, physical properties and chemical bonding of metal-rich perovskites

Stacking Design of Inverse Perovskites: The Systems (Sr3-xBaxN)E, E = Bi, Sb

Contact Info

Product

Resources

About

(Sr₃N)E and (Ba₃N)E (E = Sb, Bi): Synthesis, Crystal Structures, and Physical Properties

(Sr₃N_x)E and (Ba₃N_x)E (E = Sn, Pb): Preparation, Crystal Structures, Physical Properties and Electronic Structures

(La₃ Z _x)Al and (Ce₃ Z _x)Al with Z = C, N, O: preparation, physical properties and chemical bonding of metal-rich perovskites

Stacking Design of Inverse Perovskites: The Systems (Sr₃_-_xBa_xN)E, E = Bi, Sb