Mechanical Alloying of Optimized Mg₂(Si,Sn) Solid Solutions: Understanding Phase Evolution and Tuning Synthesis Parameters for Thermoelectric Applications

Abstract: Mechanical alloying by high energy ball milling is an attractive solid -state technique for synthesizing a diverse range of equilibrium and non-equilibrium phase materials. We have studied the synthesis of n -type thermoelectric Mg 2 Si 0.4 Sn 0.6 solid solution, aiming for a fundamental understanding of the mechanisms underlying this synthesis technique. The investigations on powders by XRD and SEM show that milling leads to welding of Mg and Sn but fracturing of Si. This fractured Si diffuses into the ductil… Show more

“…The optimum milling time highly depends on Si:Sn ratio. Si rich compositions require longer milling time than Sn rich compositions because they have less ductile components [27]. On the other hand, for binary Mg 2 Si, a milling duration of 6 h was found to be sufficient as also reported previously [28,29], presumably because only one phase could be formed.…”

“…The phase purity increases with increasing milling time. Based on a previous report on the same synthesis approach, the formation of compositions close to Mg 2 Sn takes place within the 1 hour for ntype material [27]. Therefore, the milling time is varied between 4 and 20 hours to see the difference in microstructure.…”

Synthesis of p-type Mg2Si1-xSnx with x = 0-1 and optimization of the synthesis parameters

“…The optimum milling time highly depends on Si:Sn ratio. Si rich compositions require longer milling time than Sn rich compositions because they have less ductile components [27]. On the other hand, for binary Mg 2 Si, a milling duration of 6 h was found to be sufficient as also reported previously [28,29], presumably because only one phase could be formed.…”

“…The phase purity increases with increasing milling time. Based on a previous report on the same synthesis approach, the formation of compositions close to Mg 2 Sn takes place within the 1 hour for ntype material [27]. Therefore, the milling time is varied between 4 and 20 hours to see the difference in microstructure.…”

Synthesis of p-type Mg2Si1-xSnx with x = 0-1 and optimization of the synthesis parameters

“…This value is in the expected range for the heavily doped n-type Mg 2 (Si,Sn) compounds due to the high carrier concentration in the order of 10 20 cm À3 . 17,23,43 By increasing the temperature, the absolute Seebeck value is increased for all the samples and reached an average maximum value of À200 AE 10 mV K À1 at $773 K.…”

“…The gure of merit of all samples starts from around 0.3 at $300 K and enhances with increasing temperature to around 1.3 at $773 K, that is quite comparable to the as-synthesized sample using gas atomization method and among the highest so far reported efficiency for this class of material. 12,15,17,23,66 This provides an average zT of 0.9 over the whole temperature range which is distinctly benecial from the module fabrication point of view. The gure of merit of all samples is within the accepted uncertainty range of calculation (10-20%).…”

“…9,10 Increasing the electrical conductivity can be achieved via increasing the carrier density through doping with non-isoelectronic elements. So far, for n-type doping, group XV elements such as bismuth (Bi) [11][12][13][14][15][16][17][18] and antimony (Sb), [19][20][21][22][23][24][25] which replace silicon (Si), appear to be the most potent in enhancing the carrier concentration (more than 10 20 cm À3 at 300 K); therefore, increasing the electrical conductivity. 16 Reducing the thermal conductivity is also attainable by reducing the lattice contribution (k ph ) via phonon scattering.…”

High efficiency Mg₂(Si,Sn)-based thermoelectric materials: scale-up synthesis, functional homogeneity, and thermal stability

Efficiency Measurement and Modeling of a High‐Performance Mg₂(Si,Sn)‐Based Thermoelectric Generator