Tuning the Porous Structure in PMMA-Templated Mesoporous MoO₂ for Pseudocapacitive Li-Ion Electrodes

Abstract: MoO2 is an exciting candidate for next-generation energy storage. It can be used for fast-charging applications in nanoscale form, but its kinetic performance is often limited by insulating MoO3 surface oxide layers. Here, we developed methods to produce polymer-templated porous MoO2 powders where electrical conductivity was well-maintained throughout the structure, even in the presence of some surface oxidation. Porosity, pore size, and crystallite size were controlled by varying the amount and size of the co… Show more

“…The other option for the increased capacity in the nanoscale materials would be double layer capacitance. Based on previous work, we expect the surface area of the nanostructured MoO 2 to be in the range of 30−40 m 2 /g, 17,45,52 which would correspond to an electric double layer capacitance of 9−12 F/g (5−6 mAh/g for this voltage window), which alone does not account for the higher capacity. While the nanoporous MoO 2 has a similar surface area to the MoO 2 nanocrystals, the relatively low temperature used during the nanocrystal synthesis likely leads to a larger amount of undercoordinated surface sites and results in the significantly higher capacity from surface redox reactions compared to the other samples.…”

“…Between these chains are tunnels of interstitial sites for Li + diffusion and storage, while overlap of partially filled d orbitals between neighboring Mo atoms along the chains provides metallic electrical conductivity . Despite these advantages, micron-scale MoO 2 shows rather slow (de)­insertion kinetics, due to its need for a first-order phase transition during Li + insertion and its considerable 13% increase in unit cell volume at full lithiation. , More recently, nanostructured architectures of MoO 2 have shown much higher rate capability, ,− with limited ex situ evidence for changes in their phase transition mechanism during lithiation.…”

Understanding How the Suppression of Insertion-Induced Phase Transitions Leads to Fast Charging in Nanoscale Li_xMoO₂

“…The other option for the increased capacity in the nanoscale materials would be double layer capacitance. Based on previous work, we expect the surface area of the nanostructured MoO 2 to be in the range of 30−40 m 2 /g, 17,45,52 which would correspond to an electric double layer capacitance of 9−12 F/g (5−6 mAh/g for this voltage window), which alone does not account for the higher capacity. While the nanoporous MoO 2 has a similar surface area to the MoO 2 nanocrystals, the relatively low temperature used during the nanocrystal synthesis likely leads to a larger amount of undercoordinated surface sites and results in the significantly higher capacity from surface redox reactions compared to the other samples.…”

“…Between these chains are tunnels of interstitial sites for Li + diffusion and storage, while overlap of partially filled d orbitals between neighboring Mo atoms along the chains provides metallic electrical conductivity . Despite these advantages, micron-scale MoO 2 shows rather slow (de)­insertion kinetics, due to its need for a first-order phase transition during Li + insertion and its considerable 13% increase in unit cell volume at full lithiation. , More recently, nanostructured architectures of MoO 2 have shown much higher rate capability, ,− with limited ex situ evidence for changes in their phase transition mechanism during lithiation.…”

Understanding How the Suppression of Insertion-Induced Phase Transitions Leads to Fast Charging in Nanoscale Li_xMoO₂

“…Poly(methyl methacrylate) (PMMA) is frequently used because of its lowtemperature burn-out, low ash content, and biocompatibility. [24][25][26] Porous materials achieved using PMMA with the sacrificial templating method have yielded a wide range of nanoscale pores, finding applications in catalyst materials, [27][28][29][30][31][32][33] films, [34,35] membranes, [36,37] oxides, [38][39][40] carbon-based structures, [41][42][43][44] bioactive glass, [45] electrode materials, [46,47] and scaffolds and foams. [48,49] In addition, microscale pores have been successfully fabricated using packed PMMA beads (5-800 μm) as pore-forming agents, resulting in porosities ranging from 7% to 80%.…”

Ceramic Foams with Controlled Geometries Through 3D‐Printed Sacrificial Templates

“…Materials that store charge primarily through intercalation pseudocapacitance, however, do not undergo a first-order phase transition. One method to suppress these first-order phase transitions is to reduce the size of the primary particles, as has been shown in TiS 2 , 4 MoS 2 , 7,9 MoO 2 , 6,20 and LiFePO 4 . 21 Although several Li + systems (viz., Nb 2 O 5 and MoO 3 ) have demonstrated high levels of intercalation pseudocapacitance, 6,22−24 fewer materials have been explored for high-rate Na + ion intercalation pseudocapacitance.…”

“…Materials that store charge primarily through intercalation pseudocapacitance, however, do not undergo a first-order phase transition. One method to suppress these first-order phase transitions is to reduce the size of the primary particles, as has been shown in TiS 2 , MoS 2 , , MoO 2 , , and LiFePO 4 …”

Ultrafast Sodium Intercalation Pseudocapacitance in MoS₂ Facilitated by Phase Transition Suppression