Hierarchical porous ceramics with multiple open pores from boehmite gel emulsions

Ceramic foams with highly porous microstructure play significant roles in increasing area, especially those with open channels and superior specific surface area. A simple and versatile route to prepare ceramic foams with open pores has been put forward in this research, via gelation of boehmite nanoparticles-assembled emulsions. Notably, hierarchical porous microstructure with open channels and uniform pore structure was prepared. High specific surface area up to 389.4 m 2 /g is attainable, making them excellent adsorption material, when combining the merit of hierarchical pore structure. Furthermore, lattice-shaped ceramics are prepared via direct ink printing gelled emulsion, displaying the potential of forming lightweight material with complex shape and designable macro-structure. The 3D printed foams exhibit multiple open pores, which cover the length scale from mm-scale, to μm-scale and nm-scale, making them promising materials in several fields, including adsorption, catalysts supports, and filtrations, etc.


Introduction
Owing to rewards from the synergy effect of different levels of pores regardless of scales, shapes, connectivity or locations, hierarchical porous ceramics generally behave outstanding multi-functionalities including high selectivity, specific surface area, relative strength as well as rapid mass transport, which could be well tuned according to the practical demands and also perform excellent in the applications involving adsorbents, catalyst supports, drug delivery, filtration, energy storage and the like [1][2][3] . The pore structure can be recognized as close or open pores, depending on the interconnectivity between adjacent [4] . In general, porous ceramics dominated by closed pores could be preferred choices for thermal insulations or wave-transparent materials, while those with open pores can be arranged to catalysts or filters [5] . For catalysts, porous ceramics combining both open pores and high specific surface area, high-temperature and corrosion resistance are in urgent need nowadays, also bio-implants from biocompatible ceramics with open pores have drawn more attention in recent decades [6] . Therefore, hierarchical porous ceramics occupied predominantly by open pores, in addition to possessing high specific surface area and precisely designed pore distributions at varied levels would be promising for the abovementioned fields. Among the common processing routes for introducing pores, i. g., partial sintering, sacrificial fugitives, replica templates, direct foaming, freeze casting as well as 3D printing methods [6][7][8][9][10][11] , replica templates technique is known for the obtain of interconnected open cells, which would be realized by the impregnation of precursor and produce exactly the same structure with initial porous materials. However, the existing templates from the nature or synthesis template constrains the achievement of μm-sized open pores, and the elimination of 3 templates would also import new defects. As an alternative and efficient approach for porous materials with high interconnectivity, high internal phase emulsions that are stabilized by colloidal ceramic particles have proved to be a low-cost, eco-friendly, versatile way to prepare highly porous ceramics, and successfully applied in various systems involving hydroxyapatite scaffolds, mullite, ZrO 2 , Si 3 N 4 , etc [12][13][14][15] . Furthermore, Minas C. et al. put forward to fabricate hierarchical porous ceramics via 3D printing emulsions and foams, where the emulsions or foams template the micropores.
Nowadays, the development of new technologies in key areas from adsorption to catalyst support propose increasingly demands for new structural materials with improved performance [16] . These materials will not only have high porosity, but also open pore structure and large specific surface area. We herein propose a novel method to

Experimental procedures
In this work, boehmite powder was purchased from Hangzhou Zhihuajie Technology Co., Ltd., China. Short chain amphiphilic pentanoic acid was acquired from Sinopharm Chemical Reagent Co., Ltd., Beijing, China. Octane was purchased from Shanghai 4 Aladdin Biochemical Technology Co., Ltd., China, which act as the oil phase. Firstly, to obtain homogeneous boehmite colloidal suspension with solid loading of 20 wt%, magnetic stirring of boehmite powder and deionized water were carried out in water bathing of 80°C for 24 h. Subsequently, 0.35 wt% pentanoic acid (based on the mass of boehmite) was added to the well-dispersed suspension in a hood, followed by magnetic stirring for another 1 min. Then, octane (the volume ratio of water to octane is 1:6) was added into the above aqueous suspension along with stirring. After that, mechanical stirring at speed of 1000 rpm for 3-5 min was conducted for the above mixture to prepare The phase composites of dried foams and sintered foams were detected by X-ray diffraction with Cu Kα radiation (XRD, D8 ADVANCE, Bruker, Karlsruhe, Germany).
BET specific surface area and mesoporous properties of as-prepared samples at diverse temperatures were tested using nitrogen adsorption measurements (ASIC-2 Quantachrome Instruments, USA). Boehmite nanoparticles were sonicated for 15-20 5 mins and then deposited onto a copper electron microscope grid to observe its morphology using Transmission Electronic Microscopy (TEM, S-5500, Hitachi, Japan).
The microstructure of the obtained foams was observed by scanning electron microscope (SEM, MERLIN VP Compact, Carl Zeiss, Jena, Germany). The adsorption equilibrium isotherm of methanal at room temperature (25ºC ) was measured by Static Volume Adsorption Instrument (Belsorp-Max, Bel, Japan).

Results and discussion
Other than commonly chosen micro-scale raw particles, nanoparticles would make for the improvement of porosity and specific surface area meanwhile lowering the sintering temperature [17] . Boehmite nanoparticles were selected in this research with their morphology present in Fig. 1(a). The particle size shown in Fig. 1(b) with bimodal distributions indicates that individual particle exhibits size ranging from 4 nm to 10 nm, while the higher size distribution from 25 nm to 250 nm corresponds to the size of agglomerate. In view of preparing stable particle-stabilized emulsions, the hydrophobic modification of initial particles is very critical. As illustrated in Fig. 1(c), the zeta potential of boehmite suspension is positive with a relatively high zeta potential value of 66 mV at pH of 4.0, which features strongly positive charge as a consequence of the protonation of hydroxyls [18] . Herein, pentanoic acid was selected to modify the surface of boehmite particles by absorbing on their cationic surface via electrostatic attraction effect, which render boehmite particles capacity to exist stably on the interface of oil/water after emulsification. Owing to the increasing pH-induced gelation process, the modified boehmite particles would aggregate together and form network at the oil/water interface 6 in the three-dimensional space. After the evaporation of both water and oil solvent, porous structure constructed by the connected particles could be generated, as well illustrated in Fig. 1(d). Owing to the stable Pickering emulsions prepared via hydrophobic modification of boehmite particles as colloidal armor, and rapid gelation of emulsions, porous green bodies with uniform pore distribution were obtained after the consecutive drying process, as shown in Fig. 2(a). After sintering process, ceramic foams with uniform pore distribution as well as excellent interconnected pores were synthesized (see Fig. 2 later. In addition, the nanoscale boehmite particles assembled particle layer on the oil/water interface could account for the nanoscale pore wall of ceramic foams (see Fig.   2(c)), leading to the low bulk density of 0.106 g/cm 3 . It is worth mentioning that the highly connected pores from emulsions as templates is a considerable alternative approach for open-cell ceramic foams due to the low-cost, simplicity, universality and eco-friendliness, having an advantage over the commonly used replica method which would lead to the microcracks from the template-removal process and cause problems like energy-consuming as well as environmental pollution [19] . 8

Fig. 2 SEM images of (a) green body and (b, c) ceramic foams sintered at 1000℃
Attributed to the open channels derived from emulsions and the employment of nanoscale boehmite particles, hierarchical porous structure is fabricated in this work, as schematically illustrated in Fig. 3(a). Generally, three scale levels of pore size in the asprepared ceramic foams were fabricated, that is, first level of pores originated from oil droplets assembled by nanoparticles, second level of pores mainly caused by the densification of nanoparticles and the coalescence of inter-particle voids and the following grain growth process, and third level of pores derived from the residual gaps 9 from the nanograins that forms mesoporous in the strut. The foam pore size ranges from 7.9 μm to 27.2 μm with an average pore size of 15.7 μm (Fig. 3(b)). The open channels exhibit pore size ranging from 3.2 μm to 9.3 μm, and the average pore size is 6.1 μm (Fig.   3(c)). The mesoporous strut possesses average pore size around 20 nm (Fig. 3(d)). XRD results states that the initial boehmite transforms into γ-Al 2 O 3 when sintered at relatively low temperature of 400ºC or 800ºC , and finally form α-Al 2 O 3 as the major phase accompanied by small amount of θ-Al 2 O 3 phase generated as the sintering temperature increase to 1200ºC . Notably, owing to the nanoparticles of as-received boehmite particles, the cellular green body present relatively high specific surface area of 362.6 m 2 /g. Along with the increase of sintering temperature from 450ºC to 1100ºC , the specific surface area of ceramic foams tends to decrease from 389.4 m 2 /g to 252.6 m 2 /g, which is still equivalent to the reported aerogels [20][21][22][23] . Such kind of material with large 10 specific surface area could supply accurate catalytic selectivity or reactive sites for guest matters, and facilitate the diffusion of gas or fluid through the interconnected skeleton. [16] While further increasing the sintering temperature would have a negative influence on the specific surface area, and ceramic foams obtained at 1200ºC only possess low specific surface area of 92.3 m 2 /g, which could be attributed to the larger grains and reduced voids on the pore wall.
The as-prepared ceramic foams are featured by the interconnected pores that provide passages for the transportation of gas/liquid. The foams with high open channel and large specific surface area make them potential candidates for adsorption materials, as shown in Fig. 4(c). The maximum methanal adsorption amount is around 210 cm 3 /g. Furthermore, we also demonstrate the possibility of 3D printing the gel emulsions into lattice-shape ceramics with multiple-levels open channels, large specific surface area, and low density, with the aid of direct ink writing method. As shown in Fig. 4(d), the macrostructure could be designed and constructed by the path of nozzles, which enable the formation of ceramic foams with complex shape on demand that could satisfy the gradually increasing needs in the catalysts, filters fields.

Conclusions
The preparation of 3D hierarchical porous ceramics particularly with interconnected pores through gelation of particle-stabilized emulsions armored by boehmite nanoparticles are proposed here. The gelation via increasing the pH of suspension endows the gelled emulsions printability to conduct direct ink writing process, which enable the formation of ceramics with complex shape on demand. The hierarchical structure is featured by four levels of pore distribution, that is, filament-assembled structure, spherical pores from emulsion droplets as templates, open windows on the cell wall and nanoscale pores from the voids among grains. This highly interconnected ceramic foams possess high specific surface area up to 389.4 m 2 /g, which is comparable to aerogels, and also show excellent capacity for the adsorption of methanal. The reported material with low bulk density, high interconnectivity, high specific surface area and outstanding adsorption capacity for organic solvent opens up the possibility of adsorptions, filtrations, catalyst supports, etc.