Electron transport in CaMnO3 − δ at elevated temperatures: a mobility analysis

Abstract: The drift mobility of electron charge carriers in oxygen non-stoichiometric manganite CaMnO 3− δ was calculated by combining the total electrical conductivity and oxygen non-stoichiometry data at 700-950°С and oxygen partial pressure varying between 10 −6 and 1 atm. The carrier concentration changes with pressure and temperature were obtained with the help of the earlier-developed defect model involving reactions of oxygen exchange and thermal excitation of manganese sites. The activation energy for mobility i… Show more

“…First principle studies [28] as well as experiments [18] show that oxygen deficiency largely effects the Seebeck coefficient. The additional charge due to the oxygen loss is compensated by the reduction of Mn 4 þ to Mn 3 þ [14,29].…”

“…The changes in |S| can be semi-quantitatively described using Heikes'-formula [4]. Likewise, the reduction due to oxygen loss causes a higher Mn 3 þ /Mn 4 þ ratio with identical consequences on the transport properties [18]. The reduction can be seen as a "self-doping" process where the additional Mn 3 þ significantly affects the transport properties.…”

Enhancement of redox- and phase-stability of thermoelectric CaMnO3− by substitution

“…First principle studies [28] as well as experiments [18] show that oxygen deficiency largely effects the Seebeck coefficient. The additional charge due to the oxygen loss is compensated by the reduction of Mn 4 þ to Mn 3 þ [14,29].…”

“…The changes in |S| can be semi-quantitatively described using Heikes'-formula [4]. Likewise, the reduction due to oxygen loss causes a higher Mn 3 þ /Mn 4 þ ratio with identical consequences on the transport properties [18]. The reduction can be seen as a "self-doping" process where the additional Mn 3 þ significantly affects the transport properties.…”

Enhancement of redox- and phase-stability of thermoelectric CaMnO3− by substitution

“…In recent years, more and more attentions are focus on oxide thermoelectric materials, such as layered perovskite Ca 3 Co 4 O 9 [1][2][3][4], electronic doped CaMnO 3 [5][6][7][8][9][10], and electronic doped Ti oxide [11][12][13][14], because they are more suitable for high temperature application in respect that their structural and chemical stability, low cost and so on. The efficiency of a TE generator depends on the material's TE dimensionless figure of merit (ZT).…”

Thermoelectric properties of A-site substituted Lanthanide Ca0.75R0.25MnO3

“…As for the perovskite the deviations are not surprising. It is well‐known that the oxygen content of a perovskite is dependent on both the temperature and the surrounding partial pressure of oxygen . It is therefore no surprise that the rate at which the oxygen is released from the perovskite is also affected.…”

Determining CLOU Reaction Kinetics for Combined Oxygen Carriers—Discussing the Experimental Methods