The efficiency of short sintering time on thermoelectric properties of delafossite CuCr0.85Mg0.15O2 ceramics

Use your smartphone to scan this QR code and download this article ABSTRACT Introduction: Harvesting the waste heat emitted from the activities of humanity based on thermoelectric devices is an appropriate way to reduce the overconsumption of fossil fuel nowadays. Methods: In this work, CuCr0.85Mg0.15O2 compounds prepared by conventional solid-state reactionmethodwere investigated to findout that the short sintering time is enough for thermoelectric applications, directly low the cost of the devices. Results and Conclusion: We find out that there is a significant change in the crystal structure, the chemical state, and thermoelectric properties along with the increase of the sintering time, but eventually, the dimensionless figure of merit ZT is almost constant regardless of the long or short sintering time which means that the increase of electrical conductivity will compromise the increase of thermal conductivity. The highest ZT value is 0.03 measured at 500 oC for both samples prepared at the sintering time of 3 and 12 hours.


INTRODUCTION
Thermoelectric materials have recently emerged as a potential candidate for harvesting the waste heat from artificial sources: vehicles using the robust engines, thermal power plants, … or natural sources: geothermal or solar energy. Thermoelectric devices convert heat energy based on the dimensionless figure of merit ZT = σ .S 2 .T/(κ e + κ l ) 1 , where σ (S/cm) is electrical conductivity, S (µV/K) is Seebeck coefficient, κ e is electron thermal conductivity and κ l is lattice thermal conductivity. Therefore, a material that serves for thermoelectric device needs the ZT value is as high as possible. Hence, the transport parameters (Seebeck coefficient, electrical, and thermal conductivity) need to be improved. However, these transport parameters commonly vanish to each other (e.g., the increase of electrical conductivity as elevating temperature gives rise to the decrease of Seebeck coefficient and the growth of thermal conductivity because of bipolar effect 1 ). Therefore, it is important to explore a material that could compromise those transport parameters.
Recently, oxide materials emerge as a potential candidate for thermoelectric applications due to their advantages: (i) the stability of oxide compounds when it is exposed on ambient air at high temperature led to enhance the ZT value as following equation 1 ; (ii) the raw materials have low cost and environmental friendliness 2 . There are a number of thermoelectric oxide materials reported with high thermoelectric performance, such as SrTiO 3 , Ca 3 Co 4 O 9 , Na x CoO 2 , ZnO, In 2 O 3 , and BiCuSeO 3 . Among them, the layered cobalt oxides (Ca 3 Co 4 O 9 and Na x CoO 2 ) are known as good p-type thermoelectric oxide material at high temperatures around 700 -1000 K 2,4 . However, it is noted that Na x CoO 2 will be decomposed into insulating Co(OH) 2 as being exposed in a high humidity environment 2 . In the case of the Ca 3 Co 4 O 9 compound, the anisotropic electric properties are caused by its crystal structure and the less densification because of the large difference of temperature between the eutectic point and the stable range of Ca 3 Co 4 O 9 phase are the two main disadvantages of this material 5 . Delafossite, known as an inherited p-type material, has the layered-type structure belonged to cobaltite oxide family like Ca 3 Co 4 O 9 and Na x CoO 2 . The crystal structure of delafossite which has the general chemical formular is ABO 2 (where A is Cu, Ag, Pd or Pt and B is group III elements in the periodic table) is the alternation of A-plane and BO 2 edge-shared octahedral layers. Therefore, it is expected that this material has the thermoelectric performance similar to Ca 3 Co 4 O 9 or Na x CoO 2. Many efforts have been made to enhance the thermoelectric properties of delafossite materials in which doping is a popular method. In the family of delafossite materials, Mg-doped CuCrO 2 have been known as the highest conductivity with a value of 278 S/cm 6 so far. Besides, Mg-doped CuCrO 2 also has a high Seebeck coefficient with the value in the range from 200 -450 µV/K 7-10 . However, this material encounters with the difficulty that the Mg doping could significantly improve electrical conductivity, whereas this gives rise to the dramatical decrease of the Seebeck coefficient 10,11 and causes the increase of the thermal conductivity 11 . For example, Okuda et al. 10 prepared CuCr 1−x Mg x O 2 compounds with various Mg concentrations (0 ≤ x ≤ 0.04) and found out a dramatic decrease of Seebeck coefficient from 350 to 70 µV/K with a small increase of Mg concentration from x = 0 to 0.03, respectively. In another report, Hayashi et al. 11 found out an increase of thermal conductivity from~6 to~7 W/m.K of CuCr 0.97−x Mg 0.03 Ni x O 2 compounds as x increase from 0 to 0.05, respectively. In the previous report 12 , we systematically investigated the CuCr 1−x Mg x O 2 (0 ≤ x ≤ 0.3) compounds. We found out that the high Mg doping concentration (x = 0.15) could significantly increase the electrical conductivity and decrease the thermal conductivity due to the appearance of the multi-scale defects (copper vacancies, oxygen interstitial, secondary phases like CuO, MgCr 2 O 4 ) in the compound. The solid-state reaction method is commonly used to synthesis the bulk Mg-doped CuCrO 2 materials due to its simplification and the ability to build largescale production. The reports related to Mg-doped CuCrO 2 compounds used for thermoelectric applications using the conventional solid-state reaction method almost sintered the pellets for a long time of sintering (conventionally over 10 hours) 7,8,10,11,13-17 . In the industry, reducing the time to make a product is very important to low the cost. In this work, we investigate the effects of the sintering time on thermoelectric properties of CuCr 0.85 Mg 0.15 O 2 compounds to consider the long sintering time as previously reported literature whether it is important or not for this compound.

METHODS
The CuCr 0.85 Mg 0.15 O 2 bulk samples were prepared by using the conventional solid-state reaction method. Cu 2 O, Cr 2 O 3, and MgO powders (the purity > 99% for all) were used as precursor materials. These materials are mixed by distilled water and ground by a planetary ball mill for grinding the mixed powder in alumina oxide (Al 2 O 3 ) mortar for 5 hours. The mixture obtained after the grinding process was put into the oven with a temperature of 120 o C for 24 hours to evaporate the water. After drying, the powder will be ground by hand with an agate mortar and then pressed to form a rectangular shape with a size of 30x30x6 mm 3 . This green compact will be sintered at 1200 o C with sintering times of 3 hours and 12 hours. The compounds' crystal structure was investigated using powder x-ray diffraction (XRD) method on the Bruker D8 Advanced system. A small specimen was extracted from the rectangular pellets and was ground by hand on an agate mortar. A 200-mesh sieve filtered the powder to obtain the particle whose diameter is smaller than 74 microns. The interval step of XRD is 0.02 o, and the period for a data point is 0.25 seconds. The morphology of a crystal grain was imaged by Field Emission Scanning Electron Microscopy (FE-SEM) (Hitachi S-4800) from a surface of a specimen broken from the pellets. The phases of bulk samples were detected by using a JEM2100F high-resolution transmission electron microscope (HRTEM). X-ray photoelectron spectroscopy (XPS) was conducted to investigate the chemical state of the compound by using the K-alpha XPS system (Thermo Scientific) with monochromatic Al Kα-1486.6 eV. The roomtemperature Hall effect based on the Van der Pauw method was used to determine the carrier concentration, hole mobility, and conductivity of the sheet with the dimension of 10×10×0.5 mm 3, which was cut from the initial rectangular pellets. The Seebeck coefficient and electrical conductivity were obtained from the LSR-3 system (Linseis GmbH, Germany) in the temperature range of 50 -500 o C. An LFA-457 Mi-croFlash Thermal Analyzer (NETZSCH, Germany) was used to determine the total thermal conductivity. Figure 1 depicts the XRD diagrams of CuCr 0.85 Mg 0.15 O 2 compounds prepared at the sintering temperature of 1200 o C with the sintering times of 3 and 12 hours. Generally, there is seemingly no significant difference between two XRD patterns which mainly appear in the peaks of the delafossite phase (PDF # 74-0983). Besides, MgCr 2 O 4 and CuO phase were also revealed based on the XRD standards: PDF #77 -0007 and #45 -0937, respectively. There is no trace of the raw materials, including Cu 2 O, Cr 2 O 3 and MgO in the XRD patterns, indicating that the compounds were completely converted into CuCrO 2 , MgCr 2 O 4, and CuO phase at the sintering temperature of 1200 o C. In the literatures, CuCrO 2 material is proved that this compound is successfully formed at the sintering temperature more fabulous than 1000 o C from the raw materials of Cu 2 O and  Figure 2 was used as a supplemental tool for the X-ray diffraction method to detect the existence of the multi-phases in the compounds. The co-existence of CuCrO 2 , MgCr 2 O 4 , and CuO phases in bulk samples is clearly observed regardless of the long or short sintering time. In addition, interplanar spacing between crystal planes of those phases has a reducing trend which implies that the compound become more denser as increasing the sintering time. This result shows the consistent increase of mass density and the sintering time as seen in Table 1.

RESULTS AND DISCUSSIONS
The surface morphology of the CuCr 0.85 Mg 0.15 O 2 compounds sintered for different dwell times can be observed in Figure 3. In both images, the CuCrO 2 phase can clearly be observed via the grains with the face like "terraces" because the delafossite material has the layer structure [23][24][25] . Besides, for the sample prepared with low dwell time, grains with the shape of the octahedron (typical shape of spinel MgCr 2 O 4 ) can be distinctly observed and evenly distributed in the compound, while the octahedral grains are difficult to find in the image of the sample with high dwell time. It is difficult to observe the existence of the CuO phase by FESEM images due to small contributions, as seen in XRD results. Therefore, from FESEM images, it can be clearly seen the predominance of delafossite phase in the compounds which is the consistence of XRD results. The Cu 2p photoelectron spectra of the CuCr 0.85 Mg 0.15 O 2 compounds and its Cu 2p 3/2 deconvoluted spectra are shown in Figure 4. The XPS spectra of Cu 2p in Figure 4(a) show an insignificant difference between the compounds and witness the simultaneous existence of Cu + and Cu 2+ ion states. Besides, the appearance of a broadband located at ca. 940 -945 eV and ca. 960 -965 eV named "satellite" peaks indicates the contribution of the Cu 2+ ion state 26 . The blue dash circle in Figure 4(a) indicates that the Cu 2+ state tends to increase with sintering time. To get more information on the change of the Cu 2+ state, the Cu 2p 3/2 was deconvoluted into two peaks of Cu + and Cu 2+ as seen in Figure 4 (b) and (c), respectively. The area percentage of Cu + state has a reducing trend with the increase of sintering time, while Cu 2+ has the opposite trend. The mixed-valence states Cu + /Cu 2+ relates to the electrical transport mechanism in Cu-based materials 27 . As listed in Table 2, the Cu + /Cu 2+ ratio has a reduced trend with the increase of sintering time, which indicates that the electrical transport mechanism depends on this ratio in this work, which means that the conduction occurs by small polaron hopping via the mixed-valence state Cu + /Cu 2+ . Figure 5 depicts the dependence of Cr 3+ 2p ion state of CuCr 0.85 Mg 0.15 O 2 compounds on the sintering time. There is no difference between the line of two samples, which indicates that the sintering time does not give rise to the change in the Cr 3+ ion state. Besides, the appearance of Cu L 3 M 45 M 45 at the binding energy of 569.2 eV indicates that the delafossite phase is contaminated by copper oxide 28 .
In comparison with XPS spectra of Cu 2p and Cr 2p, the XPS spectra of O 1s shown in Figure 6(a) has a significant difference between two sintering time. To get more detailed information, the XPS spectra of O 1s were deconvoluted into three peaks: (O i ) is assigned to the oxygen in its position of crystal structure which bonds with metal atoms, (O ii ) relates to the intercalation of oxygen between the Cu-plane and CrO 6 plane in delafossite structure, and (O iii ) is surface absorbed oxygen 22,29,30 . The deconvoluted results are shown     in Figure 6(b) and (c), and their details are listed in Table 2 below. The increase of sintering time gives rise to a decrease in O ii and O iii , while the percentage of O i has the opposite trend. The increase of the percentage of O i with an approximate ratio of 13.4 % indicates that the crystal structure is significantly improved, which is consistent with XRD results. In comparison, the percentage of O ii decreases by about 2.7 %, which implies that the increase of sintering time causes O ii to move into oxygen vacancies and become O i . Besides, the densification of the compound with the increase of sintering time as seen in Table 1 gives rise to a decrease the percentage of O iii .
The hole concentration, hole mobility, and conductivity of CuCr 0.85 Mg 0.15 O 2 compounds prepared at the sintering time of 3 and 12 hours are listed in Table 3. Those values generally increase with the elevation of sintering time from 3 to 12 hours. This enhancement of electrical properties is due to the improvement of crystal structure, and the sites of oxygen vacancies filled up by O ii, as mentioned above.      Figure 8 shows the correlation between the electron (κ e ), lattice (κ lat. ), and total thermal conductivity (κ tot. ) and measuring the temperature of CuCr 0.85 Mg 0.15 O 2 compounds prepared at sintering time of 3h and 12h. Figure 8(a) shows that the electron thermal conductivity exhibits a small increase with the sintering time, but its contribution to the total thermal conductivity is insignificant. The lineshape of κ lat. and κ tot. match well together, which indicates that the κ tot. is mainly governed by the κ lat. . The κ tot. increases approximately 10 % with the rise of sintering time from 3 hours to 12 hours. The increase of κ tot. relates to the change of crystallite size of CuCrO 2 and MgCr 2 O 4 phases. More specifically, CuCrO 2 phase has high thermal conductivity (5 -10 W/mK) 11,24 , while MgCr 2 O 4 phase has relatively low thermal conductivity (~2 W/mK) 12,31 . Therefore, the increase and decrease of crystallite size of CuCrO 2 and MgCr 2 O 4 phase, respectively, give rise to the increase of the κ tot. . There is a slight increase of PF, as seen in Figure 7 along with the rise of sintering time. Still, the thermal conductivity shown in Figure 8 also increases, which gives rise to the almost unchanged ZT values despite a fourfold increase of the sintering time as depicted in Figure 9. The thermal conductivity is almost constant with the measuring temperature, and therefore the rise of ZT is dependent on electrical conductivity. The compounds reach the highest ZT value of 3

CONCLUSIONS
The effects of the sintering time on the crystal structure, the chemical state, and the thermoelectric properties of CuCr 0.85 Mg 0.15 O 2 compounds prepared at a sintering temperature of 1200 o C have been investigated in this work. The XRD results show an increase of crystallite size of CuCrO 2 and CuO phase. In contrast, the crystallite size of the MgCr 2 O 4 phase shows the reducing tendency, which gives rise to the increase of total thermal conductivity. However, the ZT value is almost constant due to the rise of electrical conductivity. Generally, based on ZT results, it is observed that in the case of CuCr 0.85 Mg 0.15 O 2 compounds, the short sintering time (3 hours) is enough for synthesizing materials used for thermoelectric applications, which in turn increase the economic performance.

LIST OF ABBREVIATIONS
ZT: dimensionless figure of merit XRD: powder x-ray diffraction FESEM: Field Emission Scanning Electron Microscopy HRTEM: high-resolution transmission electron microscope XPS: X-ray photoelectron spectroscopy B.E.: Binding energy FWHM: fullwidth at half maximum