Colloidal Synthesis of Multinary Alkali-Metal Chalcogenides Containing Bi and Sb: An Emerging Class of I–V–VI2 Nanocrystals with Tunable Composition and Interesting Properties

The growth mechanism and synthetic controls for colloidal multinary metal chalcogenide nanocrystals (NCs) involving alkali metals and the pnictogen metals Sb and Bi are unknown. Sb and Bi are prone to form metallic nanocrystals that stay as impurities in the final product. Herein, we synthesize colloidal NaBi1–xSbxSe2–ySy NCs using amine–thiol–Se chemistry. We find that ternary NaBiSe2 NCs initiate with Bi0 nuclei and an amorphous intermediate nanoparticle formation that gradually transforms into NaBiSe2 upon Se addition. Furthermore, we extend our methods to substitute Sb in place of Bi and S in place of Se. Our findings show the initial quasi-cubic morphology transforms into a spherical shape upon increased Sb substitution, and the S incorporation promotes elongation along the <111> direction. We further investigate the thermoelectric transport properties of the Sb-substituted material displaying very low thermal conductivity and n-type transport behavior. Notably, the NaBi0.75Sb0.25Se2 material exhibits an ultralow thermal conductivity of 0.25 W·m–1·K–1 at 596 K with an average thermal conductivity of 0.35 W·m–1·K–1 between 358 and 596 K and a ZTmax of 0.24.


■ INTRODUCTION
Several multinary metal chalcogenides have been identified as high-performance materials in diverse fields such as photovoltaics, thermoelectrics, optoelectronics, and catalysis. 1−9 Among them, the coinage metals (Cu, Ag)-based I−V-VI 2 NCs (V = As, Sb, As) have recently gained attention owing to their promising chemical and physical properties to be used as thermoelectric (TE) materials and as absorber layers in solar cells among other applications. 10−12 Replacing the Valence I coinage metals with main group alkali metals such as Na and K and retention of the V valence pnictogen metals give rise to compositions with potentially useful properties such as high light absorption coefficients and intrinsically low thermal conductivities. 13−17 The nonparticipation of low energy orbitals of alkali metals in the valence band is further beneficial to tune TE and photovoltaic properties. 15 The presence of group V metals (Sb, Bi) in a trivalent state allows local structural anharmonicity induced by stereochemically active lone pairs (LPs) that is crucial to achieving low thermal conductivity. 18 Besides, the substitution of foreign cations such as Sb on the Bi sites increases the configuration entropy and point defects with efficient phonon scattering to lower the thermal conductivity value. 19 However, very high configurational entropy is detrimental to charge carrier transport, reducing electrical conductivity. Thus, the Sb to Bi substitution concentration needs to be optimized in such main group I−V− VI 2 compositions to simultaneously reach low thermal and high electrical conductivities.
In the colloidal hot injection (HI) method, efficient control over nucleation and growth stages can be achieved by choosing suitable precursors and reaction parameters. 20−22 Several multinary metal chalcogenide compositions such as Cu 2 FeSnSe 4 , Cu 2 MSnS 4 (M = Co, Fe, Ni, Zn, Cd), Cu 2 ZnSn(S 1−x Se x ) 4 , CuIn 1−x Gax(S 1−y Se y ) 2 , Cu α Zn β Sn γ Se δ , Ag-In-Zn-S, etc. have been achieved in NC forms by using the HI method. 4,23−28 The compositional library has been further extended using attractive cation exchange (CE) processes. 29−31 For the above-mentioned systems, Ag 2 E or Cu 2 E (E = S, Se, Te) form as initial nuclei possessing highly mobile Ag + or Cu + cations on the rigid chalcogen sublattice. The subsequent cationic substitution into the ion-conducting sublattice forms multinary phases. 32−35 Systems involving trivalent group VA metals tend to form monometallic NCs (e.g., Bi 0 ) as the initial nuclei in the presence of reducing solvents such as alkyl amine. The gradual transformation of these monometallic NCs to compound metal chalcogenide compositions may be possible at elevated temperatures and in the presence of mobile Ag + or Cu + . 21 However, this type of transformation in the alkali metal-based chalcogenide system is yet to be thoroughly investigated. Very recently, using highly reactive and flammable metal hydride precursors, phase-pure ternary NaBiSe 2 and NaSbSe 2 NCs were synthesized. 36,37 The high reactivity of the metal hydrides leads to uncontrolled nucleation and growth kinetics limiting control over size, and thus, wide size distributions were obtained. The complexity further increases with compositions consisting of three or more elements with the propensity of co-formation of binary chalcogenide phases. Overall, tuning the shape and composition with uniformity in multinary alkali metal chalcogen systems is an extremely challenging task.
Herein, we develop a colloidal HI approach using a thiol− amine solution of Se as a precursor to synthesize multinary alkali metal-based NCs containing Sb and Bi. The easily processed thiol−amine solution of selenium is highly reactive to dissolve metallic Bi NCs. The versatility of the approach allowed the synthesis of NaBi 1−x Sb x Se 2 NCs with complete composition and shape tunability. Finally, we studied the TE performance of the Sb-substituted materials. The best TE performance was obtained from NaBi 0.75 Sb 0.25 Se 2 NCs which exhibited ultralow thermal conductivity and a promising TE figure of merit. ■ RESULTS AND DISCUSSION NaBiSe 2−y S y NCs were produced using a HI colloidal synthesis approach (see the detailed procedure in the Experimental Section). Briefly, in a typical reaction, two equivalents of sodium oleate (Na−OL) solution were mixed with an equivalent of pnictogen metal (Bi, Sb) acetate salt in oleylamine (OLA) and 1-octadecene (ODE) solvent mixture and evacuated at 105°C for 1h. Subsequently, 3 mL of 0.5 M Se-alkahest stock solution was injected at 200°C under the Ar atmosphere as the chalcogen source.
Low magnification transmission electron microscopy (TEM) images show the as-synthesized NaBiSe 2 NCs to be quasi-cubic in shape with an average size of below ∼14 nm (Figures 1a,b and S1a,b). The powder X-ray diffraction (PXRD) analysis of the ternary NCs ( Figure 1c) shows them to adopt the rock salt crystal (Fm-3m) structure with an average crystallite size of ∼12 nm as calculated from Rietveld refinement ( Figure S1). The average crystallite size is close to the size obtained from TEM observations, implying the particles are single crystals. The high crystallinity is further confirmed by the analysis of the selected area electron diffraction (SAED) pattern ( Figure 1d) and fast Fourier transform of a high-resolution TEM (HRTEM) image displaying a d-spacing value of ∼3.0 Å for the (200) planes of the rock salt NaBiSe 2 NCs (Figure 1e).
For S substitution, an excess concentration of elemental S was mixed with Se thiol−amine solution to formulate the chalcogen source (detailed in the Experimental Section). The increased substitution of S induces anisotropy in shape with elongation along the <111> direction. This elongation is confirmed by the increased intensity of the XRD peaks associated with the {111} sets of planes ( Figure 2a). The cation and anion sublattices are stacked alternately along the <111> direction. 16 Thus, the substitution of S occurs along the <111> direction resulting in elongation. As per Vegard's law, increased S substitution displays an XRD peak shift toward higher 2θ values (Figure 2a  compared to ∼2.9 Å for {002} sets of planes of S-rich NCs. Furthermore, STEM-EDS elemental maps of the 50% Ssubstituted NCs displayed the presence of Na, Bi, S, and Se distributed homogenously in the NCs (Figure 2j−n).
The versatility of the synthesis approach allows the extension of the NCs composition to multinary NaBi 1−x Sb x Se 2 by Sb substitution in Bi sites. A series of NaBi 1-x Sb x Se 2 NCs with varied stoichiometry were synthesized by increasing the growth temperature to 240 from 200°C (Se addition at 200°C ) to aid Bi 3+ replacement with Sb 3+ and increasing the growth time >36 minutes depending on the Sb to Bi percentage, as detailed in the Experimental Section. The elemental composition is confirmed by ICP-OES analysis (Table S1). Bi:Sb composition ratios follow the metal precursor mole ratios used in the reaction. With increased Sb substitution, the XRD peaks shift to higher 2θ values, accompanied by a narrowing of peak width as the stoichiometry changes from Bi rich to Sb rich, supporting the Sb incorporation (Figure 3a,b). The lattice constant (calculated from Rietveld refinement of NaBi 1−x Sb x Se 2 NCs, Figure S3) reduces with increased Sb substitution in agreement with Vegard's law. The Sb substitution increases the crystallite size from ∼12 nm for NaBiSe 2 to ∼40 nm for NaSbSe 2 NCs (Figure 3c). The shape anisotropy of the multinary NCs gets affected by Sb substitution forming spherical NCs for Sb-rich phases (Figure 3d-g). Sb 3+ substitution in place of Bi 3+ will require Bi 3+ expulsion from the lattice. The increased growth temperature increases the cationic diffusion, which triggers the replacement and rearrangement of the crystal structure to form quasi-spherical shapes, similar to the thermodynamically favored cuboctahedral shape for FCC crystals. 38 The HRTEM of these NCs confirms their cubic crystal structure and depicts a clear visual of the shape change (Figure 3h,i). Furthermore, the homogenous distribution of Na, Sb, Bi, S, and Se is confirmed via STEM-EDS elemental mapping of NaBi 0.5 Sb 0.5 Se 2 NCs (Figure 3l−q).
OLA is known to reduce the pnictogen−metal salts into metallic NCs, as we have previously reported in the formation of Bi 0 using BiCl 3 precursor with OLA. 21,22 Here, the Bi NCs form upon the reduction of bismuth acetate by OLA. The presence of aldimine (which forms upon oxidation of OLA) in the aliquot supernatant collected at 200°C before Se addition from the NaBiSe 2 reaction, showing peaks at ∼3.2 and ∼7.6 ppm in the 1 H NMR ( Figure S4), confirms the OLA induced reduction of Bi(OAc) 3 . TEM analysis of the aliquot withdrawn before Se introduction displays the presence of quasi-cubic nanoparticles alongside crystalline Bi 0 NCs ( Figure S5). The quasi-cubic nanoparticles are unstable under the electron beam and display amorphous features in the selected area electron diffraction pattern ( Figure S6). The lower stability of these disordered nanoparticles under ambient conditions renders further characterization difficult. The formation of NaBiSe 2 NCs starts immediately after Se-stock injection, which is confirmed from the XRD ( Figure S8  The XRD patterns of the aliquots withdrawn at different growth times between 30 seconds to 20 minutes ( Figure S8) show the formation of NaBiSe 2 NCs alongside decreasing intensity of the Bi phase, which ultimately diminishes after 20 min of growth time at 200°C. However, the discernible intensity of the Bi 3 Se 4 phase can only be seen in the 30 seconds aliquots, confirming the rapid transformation after Se addition. Thus, we propose that the amorphous quasi-cubic-shaped nanoparticles are initially formed alongside Bi NCs (Scheme 1). These amorphous NPs will possibly (amorphous NPs contain Na as suggested by the presence of a peak at ∼1071 eV for Na + in the XPS survey of 200°C aliquot in Figure S15) act as the intermediates for further transformation. The introduction of Se converts the Bi NCs into Bi 3 Se 4 and acts as reservoirs of Bi 3+ . In nonclassical growth theory, a transition between transient amorphous or disordered phase to crystalline phase is observed. 39 allows more Bi 3+ diffusion to form phase-pure NaBiSe 2 NCs. Consequently, the larger Bi and Bi 3 Se 4 NCs dissolve as the growth progresses. Similarly, for the NaBi 0.5 Sb 0.5 Se 2 NCs, the TEM analysis of the aliquot withdrawn at 200°C before Se addition exhibits an amorphous phase alongside Bi and Sb NC formation ( Figure S11). The XRD pattern of the aliquot withdrawn 30 seconds after Se addition displays the formation of NaBiSe 2 NCs alongside the presence of unconverted Sb NCs ( Figure S12a). When the aliquot is observed under TEM, the Bi 3 Se 4 phase formation is revealed, as seen for NaBiSe 2 NCs ( Figure S12b,d). The XRD pattern from the aliquot collected 5 min after Se addition at 220°C indicates the complete conversion of the Sb NCs ( Figure S12a). Thus, the transformation of Sb NCs, possibly into an Sb-chalcogenide phase, acts as the source of Sb 3+ diffusing into NaBiSe 2 at a higher temperature of 240°C to form NaBi 1-x Sb x Se 2 NCs.
To understand the surface chemistry of the solid solution nanocrystals, IR spectra of the NaBiSe 2 , NaBi 0.5 Sb 0.5 Se 2 , and NaSbSe 2 NC powders are analyzed ( Figure 5). In the IR spectra for all the NCs, two strong bands at ∼1440 (symmetric) and ∼1550 cm −1 (asymmetric) are displayed, which are characteristic vibrational features from the surfacebound carboxylates (COO − ) from the oleate species. 41 The difference between the symmetric and asymmetric bands is around ∼110 cm −1 , which signifies the bidentate nature of the surface-bound oleate. 36 The surface-bound oleylamine exhibits its characteristic peaks at ∼1150 cm −1 (C−N stretching), 1650 cm −1 (N−H bending), and a broad stretching band around ∼3250 cm −1 coming from NH 2 stretching. 42,43 Additionally, the C−S stretching frequencies between 1050 and 650 cm −1 could arise from a surface-bound alkane thiol−selenium complex formed upon the reaction of thiol−amine solution with Se, as per equation 2 mentioned in Figure S16. 44,45 Further, from the XPS analysis of NaBiSe 2 , NaBi 0.5 Sb 0.5 Se 2 , and NaSbSe 2 NCs, the elemental composition and surface chemistry of the NCs are corroborated ( Figure 6). The low energy peaks of Sb (Sb 3d at ∼540 eV, Figure 6a), Bi (4f 5/2 at ∼163 eV and Bi 4f 7/2 at ∼158 eV, Figure 6b), and Se (Se 3d 5/2 at ∼53 eV and Se 3d 3/2 at∼54 eV, Figure 6c) and the peak of Na 1s at ∼1071 eV ( Figure 6 d) correspond to the crystal bound Sb, Se, Bi, and Na for the respective NCs. 36, 46 Besides, Sb, Bi, and Se all show higher energy peaks that could be associated with interaction with surface-bound ligands. 47,48 The high energy peaks of Sb 3d (green in 6a) and Bi 4f (green in 6b) possibly arise from the interaction of the Sb and Bi with the COO − group of the surface-bound oleates. Similarly, the Figure 5. IR spectra of NaBiSe 2 (red), NaSb 0.5 Bi 0.5 Se 2 (green), and NaSbSe 2 (blue) nanocrystal powder. Figure 6. (a) XPS of Sb 3d for NaSbSe 2 (black) and NaBi 0.5 Sb 0.5 Se 2 (red), (b) XPS of Bi 4f for NaBiSe 2 (black) and NaBi 0.5 Sb 0.5 Se 2 (red), (c) XPS of Se 3d, (d) Na 1s, (f) C1s, and (e) survey for NaBiSe 2 (green), NaBi 0.5 Sb 0.5 Se 2 (black), and NaSbSe 2 (red).

Chemistry of Materials
pubs.acs.org/cm Article high energy peaks in the Se 3d XPS (54.5 and 55.3 eV) can be ascribed to the surface-bound alkane thiol−selenium complex (R-CH 2 S−Se n−1 -Se − ) formed upon the thiol−amine reaction with Se as observed in the IR spectra. In the C 1s ( Figure 6e) XPS spectra, the higher energy peak at ∼286 eV compared to the C−C/C−H peak at ∼285 eV can be ascribed to C−O/C− N/C−S of the surface-bound oleate, oleylamine, and alkane thiol−selenium complex. 49 The 287.3 and 288.7 eV peaks may arise from the C−OO − of the surface-bound oleate showing monodentate and bidentate binding. Furthermore, the XPS survey of the NCs supports the presence of N from oleylamine as seen from N 1s XPS peak at ∼400 eV ( Figure 6f). A highly disordered multinary composition increases the point defects to scatter phonons thus reducing the thermal conductivity of the material. Additionally, in NaBiCh 2 (Ch = Se, S), the conduction band is dominated by the Bi p orbital, hence the free electron concentration can be modulated by Sb substitution. Thus, the TE properties of nanostructured NaBi 1−x Sb x Se 2 pellets obtained from the hot pressing of the NCs were investigated. For TE applications, a low thermal conductivity (K) and a high power factor S 2 σ are necessary to increase the thermoelectric figure of merit (ZT= S 2 σT/K, where S = Seebeck coefficient and σ = electrical conductivity). However, the interdependent nature of these parameters makes the optimization harder. In NaBi 1−x Sb x Se 2 , increasing the Sb substitution to x = 0.25, the carrier concentration increases as seen from the one order of magnitude rise in the electrical conductivity (σ) from 0.1 S·m −1 for x = 0 to 1.3 S·m -1 for x = 0.25 (Figure 7a). The negative Seebeck coefficient (S) values indicate that the electron is the majority charge carrier for these materials (x = 0, 0.25, and 0.5). The unsubstituted NaBiSe 2 is characterized by high S, ranging from −844 mV·K −1 at 358 K to −499 mV·K -1 at 596 K. At a substitution of x = 0.25, the increase in the carrier concentration reduces the S as shown in Figure 7b. However, a further increase in Sb substitution (x=0.5) becomes detrimental for electrical conductivity and increases the Seebeck coefficient. Recently, the 5S 2 LP in Sb was shown to be stereochemically more active than 6S 2 LP in Bi. 36 The increased LP activity upon Sb substitution induces local structural distortion to disrupt phonon propagation resulting in lower thermal conductivities (K). With x = 0.25 and 0.5, the thermal conductivity decreased below ∼0.8 W·m −1 ·K −1 . Notably, with x = 0.25, a very thermal conductivity of 0.25 W·m −1 ·K −1 is achieved at ∼596 K ( Figure  7c). The cumulative effect of the increased σ and the decreased S ensure a relatively high PF of 0.1 mW·m −1 ·K −2 at 596 K ( Figure S13) which together with the low thermal conductivity resulted in promising ZT values of ∼0.24 at 596 K, well above the ZT values obtained from the unsubstituted material, at 0.03 (Figure 7d). Notably, no significant phase or compositional change occurred for the x = 0.25 sample ( Figure S14). These results demonstrate this substitution approach is an effective strategy to tune the transport properties of multinary alkali metal−pnictogen chalcogenides.

■ CONCLUSIONS
In summary, we have developed a systematic HI synthesis approach to produce NaBi 1−x Sb x Se 2−y S y NCs with controlled composition. The high reactivity of the Se-alkahest precursor used transformed the initial Bi 0 NCs to form NaBiSe 2−y S y NCs via Bi 3+ diffusion into the nascent ternary NCs. Faster conversion of Bi 0 NCs allowed a relatively narrow size distribution. By simply varying the Sb to Bi precursor concentration and S to Se concentration, the composition Chemistry of Materials pubs.acs.org/cm Article and shape of the multinary NaBi 1−x Sb x Se 2 and NaBiSe 2−y S y NCs could be varied. Sb-rich NCs display spherical shapes, and S incorporation in NCs exhibits axial elongation along the <111> direction. The incorporation of Sb also increases the size of NCs. Furthermore, when the TE properties of the Sbsubstituted n-type materials are studied, a significant reduction in thermal conductivity (below 0.8 W·m −1 ·K −1 ) is achieved compared to unsubstituted materials. Furthermore, optimization of the power factor in NaBi 0.75 Sb 0.25 Se 2 increases the TE figure of merit (ZT) an order of magnitude compared to NaBiSe 2−y S y . We anticipate that our synthetic findings will help us to optimize the functional properties of emerging ABE 2 (A = alkali metal, B = Metal 3+ , and E = chalcogen) NCs, opening a range of new possibilities not only in the field of thermoelectrics but also in several other fields of application of these versatile materials.
The 0.5M Se-stock solution was prepared by stirring 10 mmol of Se in 10 mL of OLA and 10 mL of 1-DDT overnight in an Ar-filled glovebox.
NaBiSe 2 Nanocrystal (NC) Synthesis. In a typical synthesis, 77 mg (0.2 mmol) Bi(OAc) 3 and 2 mL of NaOL were mixed with a solvent mixture of 1 mL of OLA and 4 mL of ODE in a RBF, and the reaction mixture was evacuated at 105°C for 1h (5 min ramp to 105°C and 1h soak). The vacuum pressure was kept below 200 mTorr during evacuation. Afterward, the reaction mixture was heated to 200°C under an argon atmosphere (5 min ramp to 200°C). 3 mL of Sestock solution was injected when the temperature reached 200°C. After the Se injection, the temperature drops to below 190°C. When the temperature of the reaction vessel recovers to 200°C, it was allowed to proceed for another 30 min of growth time. Afterward, the heating mantle was removed to terminate the reaction by natural cooling till 90°C. Upon reaching 90°C, 10 mL of toluene was mixed with the gel-like reaction mixture by sonication and vortexing well. NaBi 1−x Sb x Se 2 and NaBiSe 2−y S y Nanocrystal (NC) Synthesis. In a typical synthesis, Bi(OAc) 3 and Sb(OAc) 3 with a molar ratio decided from desired stoichiometry (e.g., 0.15 mmol of Sb(OAc) 3 and 0.05mmol of Bi(OAc) 3 for achieving a composition of Na-Bi 0.25 Sb 0.75 Se 2 ) and 2 mL of NaOL were mixed with a solvent mixture of 1 mL of OLA and 4 mL of ODE in a RBF, and the reaction mixture was evacuated at 105°C for 1h (5 min ramp to 105°C and 1h soak). The vacuum pressure was kept below 200 mTorr during evacuation. Afterward, the reaction mixture was heated to 240°C under an argon atmosphere (5 min ramp to 240°C). 3 mL of Sestock solution was injected when the temperature reached 200°C. When the temperature of the reaction vessel reached 240°C, it was allowed to proceed for another 36 min of growth time for Bi/ Sb=0.75/0.25, 40 min Bi/Sb= 0.5/0.5, 42 min for Bi/Sb=0.25/0.75, and 45 min for NaSbSe 2 . Afterward, the heating mantle was removed to terminate the reaction by natural cooling till 90°C. Upon reaching 90°C, 10 mL of toluene was mixed with the gel-like reaction mixture by sonication and vortexing well. For S substitution, the S-to-Se mole ratio was used based on stoichiometry. For example, to synthesize NaBiSe 1 S 1 , the chalcogen stock solution was prepared by stirring 5 mmol of Se and 5 mmol of S in 10 mL of OLA and 10 mL of 1-DDT, and 3 mL of the stock solution was injected at 200°C with a growth temperature of 240°C for 40 min. For NaBiSe 1.8 S 0.2 and NaBiSe 1.4 S 0.6 , a growth time of 35 and 38 min was used, respectively.
NC Purification Procedure. The NCs synthesized and mixed with 10 mL of toluene were poured into a 50 mL centrifuge tube and vortexed well. After that, the NC solution was mixed with IPA and sonicated for 10 min. The dispersed NCs in an equal amount of toluene and IPA were centrifuged at 5000 rpm for 5 min. The pellet was collected and dispersed in 10 mL of Tol first and 10 mL of IPA was further added, sonicated, and vortexed to disperse the NCs well. The NC solution was again centrifuged at 5000 rpm for 5 min, and the process was repeated another 2 times and dried at 80°C overnight in vacuum.
For thermoelectric pellet fabrication, after the third wash, the nanocrystals were further mixed with 200 μL of butyl amine in the nanocrystal dispersed in 10 mL of toluene and mixed for 15 min via sonication. Afterward, 10 mL of IPA was added to the dispersion and further sonicated for 5 min and mixed via vortex for 1 min. The NC solution was centrifuged at 5000 rpm for 5 min, and the process was repeated 1 more time before drying overnight in a vacuum oven at 80°C . General Safety and Handling. Safety considerations of each chemical should be thoroughly noted from safety data sheets (SDS are available on the chemical supplier webpage) before handling them. The ability to regulate vacuum and Ar-filled inert atmosphere in the Schlenk line is essential. Therefore, before performing any experiments, one should be well-equipped and experienced in air-free synthesis in high boiling point solvents at elevated temperatures and Schlenk line handling. All of the chemicals must be handled with proper personal protective equipment (PPE), especially lab coats, gloves, and safety goggles. All of the chemical substances should be handled/measured inside the glovebox or fume hood as per SDS. Among all of the chemicals, oleylamine is highly corrosive and toxic. Hence, it should be handled in the fume hood with proper PPE. Antimony acetate can be responsible for oral toxicity. Thus, it should be handled in a closed environment with appropriate PPE. 1-Dodecanethiol is corrosive and a skin irritant with a strong odor. Therefore, it should always be handled inside a fume hood. Any spillage should be cleaned immediately. The evacuation steps should be performed with a liquid N 2 trap connection to condense hazardous gas evolved during the reaction. The Ar flow should be maintained using an outlet reservoir such as a bubbler. During the reaction, this will also help prevent direct exposure to evolved gaseous impurities and products. The hot sodium oleate transfer should be done cautiously with a glass syringe.
Aliquot Study. During NC growth, 1 mL of solution from the RBF was withdrawn at desired temperature and time after Se injection. To ensure minimal depletion in precursor concentration, a maximum of 2 mL of reaction solution in total was withdrawn from the RBF. After withdrawal, the growth was immediately quenched by ejecting into 2 mL of Tol. The NCs in 2 mL of Tol were dispersed in 2 mL of IPA and centrifuged for 5 min at 5000 rpm, followed by another two cycles of redispersion in 2 mL of Tol and 2 mL of IPA and centrifugation at 5000 rpm for 3 min. For NMR characterization, the aliquot collected at 200°C was thermally quenched and no toluene was added. After cooling it down to room temperature, the liquid portion of the aliquot was characterized through 1 H NMR (JEOL 400 MHz NMR spectrometer) in CDCl 3 . The peaks were referenced to the residual chloroform peak at 7.26 ppm for 1 H NMR.
Electron Microscopy. For transmission electron microscopy (TEM) analysis, the NCs were dispersed in Tol and drop cast on continuous carbon-coated 200 mesh nickel grids. Low-resolution and high-resolution TEM (HRTEM) and dark-field scanning transmission electron microscopy (DFSTEM) were conducted by using a 200 kV JEOL JEM-2100F field-emission microscope, equipped with a Gatan UltraScan CCD camera and EDAX Genesis energy dispersive X-ray spectroscopy (EDS) detector. For analyzing the HRTEM data, interplanar distances and particle orientation were determined from the selected area FFT analysis using GMS3 software.
Chemistry of Materials pubs.acs.org/cm Article X-ray Diffraction (XRD) Analysis. XRD of drop-cast films of the NCs on the flat surface of p-type boron-doped silicon zero background was conducted using a PANalytical Empyrean instrument equipped with a Cu Kα radiation source (λ = 1.5418 Å) and a 1-D X'celerator strip detector with a diffractometer operating at 40 kV and 40 mA. All of the PXRD patterns of the final NCs were analyzed by the Rietveld method in HighScore Plus software using a pseudo-Voigt profile.
X-ray photoelectron spectroscopy (XPS). X-ray photoelectron spectroscopy (XPS) was carried out using a Kratos AXIS ULTRA spectrometer fitted with a mono Al Kα (1486.58 eV) X-ray gun. Calibration was performed using the C 1s line at 284.8 eV, while construction and peak fitting were performed using CasaXPS software. XPS was performed on the vacuum-dried nanostructure samples.
Thermoelectric Measurements. The Seebeck coefficient and resistivity were simultaneously measured under a helium atmosphere in an LSR-3 Linseis system. All samples were tested for at least three heating and cooling cycles. Considering the system and measurement accuracy and measurement accuracy, we estimated the measurement error of conductivity and Seebeck coefficient to be about 4%. Thermal conductivities were obtained by multiplying the thermal diffusivity (λ), the constant pressure heat capacity (C p ), and the density of the material (ρ): K total = λC p ρ. Thermal diffusivities were measured by a Xenon Flash Apparatus XFA 600 and a Laser Flash Analyzer LFA 1000, Linseis, which have an estimated error of ca. 5%. The heat capacity was estimated from the Dulong−Petit limit (3R law). The densities were calculated from Archimedes' method which is ∼90% of the theoretical density. ■ ASSOCIATED CONTENT
Additional data of SEM, TEM, HRTEM, STEM-EDS mapping, 1 H NMR, XRD patterns, and Rietveld refinement of the aliquot, and nanocrystals samples and additional data of thermal transport property measurement (PDF)