Title: Materials Data on Li4Ti3Mn4Cr2O18 by Materials Project

Li4Ti3Cr2Mn4O18 crystallizes in the orthorhombic Pmc2_1 space group. The structure is three-dimensional. there are four inequivalent Li1+ sites. In the first Li1+ site, Li1+ is bonded in a 5-coordinate geometry to five O2- atoms. There are a spread of Li–O bond distances ranging from 2.13–2.40 Å. In the second Li1+ site, Li1+ is bonded in a 7-coordinate geometry to seven O2- atoms. There are a spread of Li–O bond distances ranging from 2.07–2.55 Å. In the third Li1+ site, Li1+ is bonded in a 5-coordinate geometry to five O2- atoms. There are a spread of Li–O bond distances ranging from 2.11–2.53 Å. In the fourth Li1+ site, Li1+ is bonded in a 5-coordinate geometry to eight O2- atoms. There are a spread of Li–O bond distances ranging from 2.12–2.84 Å. There are three inequivalent Ti4+ sites. In the first Ti4+ site, Ti4+ is bonded to six O2- atoms to form TiO6 octahedra that share corners with two equivalent MnO6 octahedra and edges with four TiO6 octahedra. The corner-sharing octahedral tilt angles are 50°. There are a spread of Ti–O bond distances ranging from 1.91–2.09 Å. In the second Ti4+ site, Ti4+ is bonded to six O2- atoms to form TiO6 octahedra that share corners with two equivalent MnO6 octahedra, edges with two equivalent TiO6 octahedra, and edges with two equivalent CrO6 octahedra. The corner-sharing octahedral tilt angles are 50°. There are a spread of Ti–O bond distances ranging from 1.85–2.09 Å. In the third Ti4+ site, Ti4+ is bonded to six O2- atoms to form TiO6 octahedra that share corners with four MnO5 square pyramids and edges with four TiO6 octahedra. There are a spread of Ti–O bond distances ranging from 1.92–2.01 Å. There are two inequivalent Cr6+ sites. In the first Cr6+ site, Cr6+ is bonded to six O2- atoms to form CrO6 octahedra that share edges with two equivalent CrO6 octahedra and edges with four MnO6 octahedra. There are a spread of Cr–O bond distances ranging from 2.00–2.03 Å. In the second Cr6+ site, Cr6+ is bonded to six O2- atoms to form CrO6 octahedra that share corners with four MnO5 square pyramids, edges with two equivalent TiO6 octahedra, and edges with two equivalent CrO6 octahedra. There are a spread of Cr–O bond distances ranging from 1.96–2.05 Å. There are four inequivalent Mn2+ sites. In the first Mn2+ site, Mn2+ is bonded to five O2- atoms to form distorted MnO5 square pyramids that share corners with two equivalent TiO6 octahedra, corners with two equivalent CrO6 octahedra, corners with two equivalent MnO6 octahedra, and edges with two equivalent MnO5 square pyramids. The corner-sharing octahedra tilt angles range from 53–66°. There are a spread of Mn–O bond distances ranging from 1.95–2.18 Å. In the second Mn2+ site, Mn2+ is bonded to six O2- atoms to form MnO6 octahedra that share corners with two equivalent TiO6 octahedra, corners with two equivalent MnO5 square pyramids, edges with two equivalent CrO6 octahedra, and edges with two equivalent MnO6 octahedra. The corner-sharing octahedral tilt angles are 50°. There are a spread of Mn–O bond distances ranging from 1.92–1.98 Å. In the third Mn2+ site, Mn2+ is bonded to five O2- atoms to form distorted MnO5 square pyramids that share corners with two equivalent TiO6 octahedra, corners with two equivalent CrO6 octahedra, corners with two equivalent MnO6 octahedra, and edges with two equivalent MnO5 square pyramids. The corner-sharing octahedra tilt angles range from 52–64°. There are a spread of Mn–O bond distances ranging from 1.96–2.03 Å. In the fourth Mn2+ site, Mn2+ is bonded to six O2- atoms to form MnO6 octahedra that share corners with two equivalent TiO6 octahedra, corners with two equivalent MnO5 square pyramids, edges with two equivalent CrO6 octahedra, and edges with two equivalent MnO6 octahedra. The corner-sharing octahedral tilt angles are 50°. There are a spread of Mn–O bond distances ranging from 1.92–1.97 Å. There are eighteen inequivalent O2- sites. In the first O2- site, O2- is bonded in a 4-coordinate geometry to one Cr6+ and two equivalent Mn2+ atoms. In the second O2- site, O2- is bonded in a 3-coordinate geometry to one Cr6+ and two equivalent Mn2+ atoms. In the third O2- site, O2- is bonded in a 4-coordinate geometry to two equivalent Li1+ and two equivalent Ti4+ atoms. In the fourth O2- site, O2- is bonded to two equivalent Li1+ and three Ti4+ atoms to form distorted OLi2Ti3 trigonal bipyramids that share corners with two equivalent OLiTi2Mn tetrahedra, corners with four OLiTiMn2 trigonal pyramids, and edges with two equivalent OLi2Ti3 trigonal bipyramids. In the fifth O2- site, O2- is bonded in a 3-coordinate geometry to two equivalent Li1+ and three Mn2+ atoms. In the sixth O2- site, O2- is bonded to one Li1+, two equivalent Cr6+, and one Mn2+ atom to form distorted OLiMnCr2 trigonal pyramids that share corners with four OLi2Ti2Cr trigonal bipyramids and corners with two equivalent OLiMnCr2 trigonal pyramids. In the seventh O2- site, O2- is bonded to two equivalent Li1+, two equivalent Cr6+, and one Mn2+ atom to form OLi2MnCr2 square pyramids that share corners with two equivalent OLi2MnCr2 square pyramids, edges with three OLi2MnCr2 square pyramids, and edges with two equivalent OLiTiMn2 trigonal pyramids. In the eighth O2- site, O2- is bonded in a 5-coordinate geometry to two equivalent Li1+, one Cr6+, and two equivalent Mn2+ atoms. In the ninth O2- site, O2- is bonded in a 3-coordinate geometry to one Ti4+ and two equivalent Cr6+ atoms. In the tenth O2- site, O2- is bonded to one Li1+, one Ti4+, and two equivalent Mn2+ atoms to form OLiTiMn2 trigonal pyramids that share corners with two equivalent OLi2Ti3 trigonal bipyramids, corners with two equivalent OLiTiMn2 trigonal pyramids, and edges with two equivalent OLi2MnCr2 square pyramids. In the eleventh O2- site, O2- is bonded in a 4-coordinate geometry to two equivalent Li1+ and two equivalent Ti4+ atoms. In the twelfth O2- site, O2- is bonded to two equivalent Li1+, two equivalent Ti4+, and one Cr6+ atom to form OLi2Ti2Cr trigonal bipyramids that share corners with two equivalent OLiTi2Mn tetrahedra, corners with two equivalent OLiMnCr2 trigonal pyramids, edges with two equivalent OLi2Ti2Cr trigonal bipyramids, and edges with two equivalent OLi2TiMn2 trigonal pyramids. In the thirteenth O2- site, O2- is bonded in a 3-coordinate geometry to two equivalent Li1+ and three Mn2+ atoms. In the fourteenth O2- site, O2- is bonded to one Li1+, two equivalent Ti4+, and one Mn2+ atom to form distorted OLiTi2Mn tetrahedra that share corners with two equivalent OLiTi2Mn tetrahedra, corners with four OLi2Ti2Cr trigonal bipyramids, and a cornercorner with one OLi2TiMn2 trigonal pyramid. In the fifteenth O2- site, O2- is bonded to two equivalent Li1+, two equivalent Cr6+, and one Mn2+ atom to form OLi2MnCr2 square pyramids that share corners with two equivalent OLi2MnCr2 square pyramids, edges with three OLi2MnCr2 square pyramids, and edges with two equivalent OLi2TiMn2 trigonal pyramids. In the sixteenth O2- site, O2- is bonded in a distorted trigonal planar geometry to two equivalent Li1+, one Ti4+, and two equivalent Mn2+ atoms. In the seventeenth O2- site, O2- is bonded in a distorted trigonal non-coplanar geometry to three Ti4+ atoms. In the eighteenth O2- site, O2- is bonded to two Li1+, one Ti4+, and two equivalent Mn2+ atoms to form distorted OLi2TiMn2 trigonal pyramids that share a cornercorner with one OLiTi2Mn tetrahedra, corners with two equivalent OLi2TiMn2 trigonal pyramids, edges with two equivalent OLi2MnCr2 square pyramids, and edges with two equivalent OLi2Ti2Cr trigonal bipyramids.