Active Complexes on Engineered Crystal Facets of MnOx–CeO2 and

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Remediation and Control Technologies

Active Complexes on Engineered Crystal Facets of MnOx–CeO2 and Scaleup Demonstration on an Air Cleaner for Indoor Formaldehyde Removal Haiwei Li, Wing Kei Ho, Jun-ji Cao, Duckshin Park, Shun Cheng Lee, and Yu Huang Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.9b03197 • Publication Date (Web): 23 Aug 2019 Downloaded from pubs.acs.org on August 23, 2019

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Active Complexes on Engineered Crystal Facets of MnOx–CeO2 and Scale-up

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Demonstration on an Air Cleaner for Indoor Formaldehyde Removal

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Haiwei Li,† Wingkei Ho,‡,§ Junji Cao,‖ Duckshin Park,‖‖ Shun-cheng Lee,*,† Yu Huang *,‖

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†Department

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Hong Kong, China.

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‡Department

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Hong Kong, China.

of Civil and Environmental Engineering, The Hong Kong Polytechnic University,

of Science and Environmental Studies, The Education University of Hong Kong,

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§State

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China.

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‖State

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Aerosol Chemistry and Physics, Institute of Earth Environment, Chinese Academy of Sciences,

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Xi’an 710061, China.

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‖‖Transportation

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Gyeonggi-do, South Korea.

Key Laboratory of Marine Pollution, The City University of Hong Kong, Hong Kong,

Key Laboratory of Loess and Quaternary Geology (SKLLQG) and Key Laboratory of

Environmental Research Team, The Korea Railroad Research Institute,

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*Corresponding Authors: Prof. Shuncheng Lee, E-mail: [email protected]; Prof. Yu Huang,

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E-mail: [email protected].

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TOC Art

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ABSTRACT: Crystal facet-dominated surfaces determine the formation of surface-active

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complexes, and engineering specific facets is desirable for improving the catalytic activity of

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routine transition metal oxides that often deactivate at low temperatures. Herein, MnOx–CeO2

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was synthetically administered to tailor the exposure of three major facets, and their distinct

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surface-active complexes concerning the formation and quantitative effects of oxygen vacancies,

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catalytically active zones, and active-site behaviors were unraveled. Compared with two other

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low-index facets {110} and {001}, MnOx–CeO2 with exposed {111} facet showed higher

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activity for formaldehyde oxidation and CO2 selectivity. However, the {110} facet did not

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increase activity despite generating additional oxygen vacancies. Oxygen vacancies were highly

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stable on the {111} facet and its bulk lattice oxygen at rapid migration rates could replenish the

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consumption of surface lattice oxygen, which was associated with activity and stability. High

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catalytically active regions were exposed at the {111}-dominated surfaces, wherein the

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predominated Lewis acid–base properties facilitated oxygen mobility and activation. The

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mineralization pathways of formaldehyde were examined by a combination of in situ X-ray

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photoemission spectroscopy and diffuse reflectance infrared Fourier transform spectrometry. The

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MnOx–CeO2-111 catalysts were subsequently scaled up to work as filter substrates in a

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household air cleaner. In in-field pilot tests, 8 h of exposure to an average concentration of

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formaldehyde after start-up of the air cleaner attained the Excellent Class of Indoor Air Quality

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Objectives in Hong Kong.

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INTRODUCTION

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Catalytic oxidation processes at low temperatures using either supported noble metals (e.g.,

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Au, Ag, or Pt)1-3 or non-noble transition metal oxides (containing Mn, Co, or Zr)4-6 have been

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extensively studied for air pollution control. Earth-abundant MnOx is often modified in hybrid

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fabrications due to its high reversible capacitance and structural flexibility4, and an ensuing

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redox loop with cyclic electron transfer can be sustained via a Mn dismutation when reduced

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oxidation states of Mn are periodically remediated by the oxygen-carrier materials such as

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CeO27, 8, Fe2O39, or Al2O310. Among them, MnOx–CeO2 mixed oxides have been examined in the

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catalytic oxidation of priority gaseous pollutants, such as formaldehyde (HCHO)11-14, carbon

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monoxide (CO)15, and nitrogen oxides (NOx)16, 17. Given reactive metal–particle interfaces, the

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promoting effect of noble metal nanoparticles on MnOx–CeO2 mixed oxides (e.g., Ag/MnOx–

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CeO218 and Pt/MnOx–CeO219) has been obtained during the nearly complete oxidation of HCHO

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at low temperatures. To date, the industrial development of relatively inexpensive but effective

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noble metal-free catalysts is needed, and catalyst deactivation occurs at ambient temperature11, 20.

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Surface-active complexes concerning defect formation, activation of reactive oxygen

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species, molecule adsorption, and heterogeneous oxidation are proportional to exposed crystal

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facets. Engineering crystal facets induces distinct oxygen vacancy clusters within different

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exposed facets and possesses various physical and chemical performances of structured crystal

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atoms21, 22. From an industrial perspective, engineering surface structures for binary transition

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metal oxides is more apt to their scale-up production relative than either single nanostructured

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oxidized metals or ternary junctions4,

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uncertain in the Mars–Van Krevelen redox mechanisms of heterogeneous catalysis11, 23 or in a

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solid solution containing complex solvents or additives12,

23, 24,

because the reactivity and facet control are often

4

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As such, ceria with a fluorite

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structure has three major low-index facets: nanocubes preferentially dominated by the {110}

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facet and nanorods dominated by the {111} and {100} facets25, 26. The exposed {110} and {100}

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facets can facilitate the migration of lattice oxygen from the bulk to the surface, but the process

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is restricted on the {111} surfaces27. However, the dominant {110} and {100} facets are inclined

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to deactivate with reaction time because of the low stability of the oxygen vacancies employed25-

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28.

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Mn, Ti, or Zr12, 27, 29, 30. By contrast, when manganese ions (Mnn+) with small ionic radius and

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low compositions are stabilized in MnOx–CeO2 mixed oxides, the oxygen mobility is strongly

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improved, and higher catalytic activities are achieved at low temperatures than single oxidized

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metals4, 11-13, 19. In MnOx–CeO2, ceria is not directly involved in catalytic oxidation but functions

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as an oxygen carrier to keep high-valence manganese oxide via a Mn dismutation reaction.

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Moreover, the enhancement of reactivity is ascribed to the mobility and activation of lattice

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oxygen26, 31. Exposing specific crystal facets remains challenges. The exposed facets with high

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surface energy can decline with a fast growth rate in the bulk of crystals; hence, the

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thermodynamically stable facets predominated on crystal surfaces could minimize the total

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surface energy21. Key factors, such as solvents, additives, and impurities in a solid solution, can

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also influence the final shape of crystals. Therefore, appropriate surfactant-assisted/capping

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agents (e.g., citric acid and cetyltrimethylammonium bromide) have been chosen to tailor the

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exposure of crystal facets11, 12, 21, 26. For example, the ceria {001} facet with fast growth was well

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administered using decanoic acid as an organic ligand molecules32. Aside from the facet

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reforming and growth, a large amplitude of catalytically active regions is indispensable for

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exposed surface-active complexes within facet-dominated surfaces33, 34.

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The stability of CeO2 nanocrystals can be maintained by doping with stable metals, such as

Translating laboratory work into commercial value at large is the focus of our research. The

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situation of indoor air pollution is aggravated by numerous factors, including high-rise living,

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subdivided flats, and lack of windows and ventilation in most enclosed areas. Considering the

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toxicity of HCHO at very low concentrations, standards for the emission levels of HCHO have

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become stringent in the Indoor Air Quality Certification Scheme in Hong Kong, i.e., Excellent

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Class with 30 µg·m−3 and Good Class with 100 µg·m−3 for an 8 h of exposure35, 36. To eliminate

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HCHO in indoor air, our group developed various collosol-film coating, purifier filter substrates,

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or honeycomb-like reactors based on heterogeneous catalysis to use in different environments37,

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38.

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case scenario for the formulation and development of mitigation strategies.

Knowledge gained from laboratory tests and field campaigns can be used to estimate the best-

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Herein, MnOx–CeO2 catalysts with different major exposed facets were synthesized using

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varying morphology-controlling methods. The exposed three major {111}, {110}, and {001}

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facet-dominated surfaces were systematically studied in terms of activity and selectivity,

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formation and quantitative effects of oxygen vacancies, identification of catalytically active

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regions, and intermediate pathways. Efficient MnOx–CeO2-111 catalysts were scaled up to

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function as filter substrates of a household air cleaner. The materials obtained from the

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laboratory-scale experiments were examined and validated in in-field pilot tests of the air cleaner

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to evaluate their actual removal effectiveness.

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MATERIALS AND METHODS

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Catalyst Synthesis. MnOx–CeO2-111 (denoted as MCO-111) was synthesized by a

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hydrothermal redox reaction containing 50 wt% Mn(NO3)2 ( 8 mM) solution, Ce(NO3)3·6H2O (8

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mM), and (NH4)2S2O8 (16 mM). The resulting mixture was transferred into a 50 mL Teflon-lined

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stainless-steel autoclave after stirring for 2 h and then heated at 140 °C for 12 h. The

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hydrothermal products were washed with ultrapure water (Milli-Q system, Millipore Inc.), dried

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at 70 °C, and calcined at 350 °C for 6 h. Finally, the calcined products were treated with 100 mL

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of citric acid solution (2 mM) before washing and drying.

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MnOx–CeO2-110 (MCO-110) was prepared by co-precipitation. A mixture of the same 50

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wt% Mn(NO3)2 (8 mM) solution and NH4Ce(NO3)4·6H2O (8 mM) solution was dissolved in

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ultrapure water followed by the dropwise addition of the precipitant NaOH solution (20 mM).

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The resulting solution was added to an aqueous solution of cetyltrimethylammonium bromide

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(CTAB, Sigma ≥ 98%) under stirring for 2 h and then heated at 70 °C for 12 h. The harvested gel

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precipitates were washed and filtered before drying at 70 °C and calcining at 500 °C for 6 h.

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MnOx–CeO2-001 (MCO-001) was prepared with the synthesis route similar to that of MCO-

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111 but the mixture was added with organic ligand molecules, i.e., decanoic acid (50 mg). After

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the hydrothermal reaction at 400 °C for 1 h and quenching in a water bath to room temperature,

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the organic ligand-modified products were extracted from a mixture of 3 mL of hexane and 15

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mL of ethanol. The molar ratio of decanoic acid to ceria precursor did not generally exceed 6:1

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to overcome the surfaces enclosed by the {111} planes. Considering that the precursor CeO2

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{001} surface is less stable than the {111} surface, the organic ligand molecules can lead to the

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formation of the exposed {001} surface toward the crystal growth in the [111] direction instead

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of the [001] direction32.

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Characterizations. The as-prepared catalysts were characterized by the following

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techniques: X-ray powder diffraction (XRD; Philips X’pert Pro Super diffractometer), high-

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resolution transmission electron microscopy (HRTEM; JEOL JEM-2010), Brunauer–Emmett–

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Teller analysis (BET; Micromeritics Gemini VII 2390 Norcross, GA), thermogravimetric

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analysis (TGA; Setaram Setsys 16/18 thermoanalyzer), inductively coupled plasma atomic

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emission spectroscopy (ICP-AES; Varian), H2 temperature-programmed reduction (H2–TPR), O2

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temperature-programmed desorption (O2–TPD), X-ray photoemission spectroscopy (XPS;

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Thermo ESCALAB 250Xi) calibrated with C 1s at 284.8 eV, and pyridine adsorbed IR

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spectroscopy (Py-IR; Tensor 27, Bruker). The detailed characterization instruments and methods

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are provided in Supporting Information (SI), and the schematic diagram and operating

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parameters infrared thermography (IRT; FLIR camera SC7000 system) are demonstrated in SI

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Figures S1–S2 and Table S1.

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Laboratory Activity Test. Under the reaction condition of 5 ppm HCHO/21 vol% O2/N2

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and gas hourly space velocity (GHSV) = 4 × 104 h–1, the catalytic activity for the conversion of

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HCHO into CO2 was tested in a thermostatic fixed-bed reaction system, as described in SI. The

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recycling catalytic activity was conducted in 5 batch modes of 90 minute measurements under

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the similar reaction condition, each of which continued when the HCHO concentration was back

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to its initial level.

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Designed H2–TPR Experiments. The quantitative effects of oxygen vacancies within

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different exposed facets were evaluated through the consumption of reductant H2 with lattice

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oxygen in two types of designed H2–TPR experiments, i.e., the migration of bulk lattice oxygen

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treated at 600 °C and the consumption of surface lattice oxygen treated at 450 °C, wherein the

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two types of lattice oxygen of MCO catalysts were ran into release and decline, consistent with

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the TGA profile (SI Figure S3). The samples were pretreated similarly to the H2–TPR

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measurements (see in SI) and heated to 600 °C at a heating rate of 10 °C·min–1 for various

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treatment periods (1, 5, and 10 h) under 10 vol% H2/Ar gas flow. The corresponding H2

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consumption was monitored by using an online thermal conductivity detector to calculate the

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migration amount of bulk lattice oxygen after reheating to 950 °C. The pretreated samples in the

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second experiment were treated at 450 °C under identical treatment conditions and then cooled to

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100 °C under ultra-pure Ar feed. After reheating to 950 °C, the corresponding H2 consumption

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was recorded in a similar manner to calculate the consumption amount of surface lattice oxygen.

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In Situ XPS and Diffuse Reflectance Infrared Fourier Transform Spectrometry

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(DRIFT) Analysis. The detailed in situ XPS and DRIFT experiments are described in SI. The

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assignment of C 1s XPS photopeaks is listed in SI Table S2 in accordance with the binding

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energies (BEs) of different possible chemical bonds.

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RESULTS AND DISCUSSION

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Structural Characterizations. As shown in Figure 1a, the entire characteristic peaks of

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MCO with different exposed facets shifted toward lower 2θ angles relative to those of precursor

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ceria {111}, {110}, and {001} (see also SI Figure S4), which was due to the facet growth after

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some Ce4+ ions (0.087 nm) of ceria were replaced with Mnn+ of a small ionic radius (i. e., Mn4+

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of 0.053 nm and Mn3+ of 0.065 nm) in the mixed oxides. The intensities of diffraction patterns

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for MnOx within the three exposed facets, i.e., main Mn3O4 hausmannite phase (JCPDS 07-1841)

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together with small Mn2O3 (JCPDS 07-0856) and Mn5O8 (JCPDS 39-1218), became weak

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because their individual facet growth in lattice plane of ceria was restricted and the Mn2+ and

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Mn3+ ions of Mn3O4 were partially oxidized into Mn4+ ions after acid treatment.12, 14, 26

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The successful fabrications of the three major exposed facets were examined and validated

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in HRTEM images (Figure 1b). In compliance with the downward shift of XRD patterns, the d-

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spacings of MCO (110) and (110) planes were estimated at 0.49 and 0.31 nm, larger than those

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of pristine ceria (111) and (110) of 0.31 and 0.19 nm (SI Figure S5), respectively. The increases

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in d-spacings were associated with the formation of defect sites (e.g., oxygen vacancies or Ce4+

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reductions)26, 31 within the exposed MCO facets (Figure 1c). The corresponding SAED pattern

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shows a similar angle at 45o between (111) and (100) planes for MCO-111 compared to

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precursor ceria {111}, which agrees with the {111} surfaces were regularly displayed along a

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direction. MCO-110 was identified according to an angle of 45o between (100) and (110)

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planes, while the {001} facet exposure was related to an angle at 90o of between (001) and

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(110)26,

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unchanged despite increased facet growth, indicating that the facet and size control for the

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engineered MCO surfaces were well regulated. These results could be correlated with the molar

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ratio of Mn/(Mn+Ce) administered below 0.512,

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specific surface areas but affect their immobility in the mixed oxides after rigorous aging

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treatment4.

27.

The angle between specific crystal planes for the three exposed facets remained

14, 19.

High Mn contents could enlarge the

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Mnn+ doping reformed the surfaces and improved the crystal structures (SI Table S3)

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compared with pristine MnOx and CeO2. An apparent plane (211) with d-spacings of 0.38 nm

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was assigned to Mn3O4 phase preferentially immobilized within the stable MCO {111} surfaces

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after citric acid treatment12. Relative to the pristine {111} facet dominated in ceria nanoparticles

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and the pristine {110} facet in ceria nanorods (see also SI Figure S5), the MCO-111 and MCO-

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110 surfaces became cylindrical, and their framework architectures changed from facetted pores

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and channels to smooth pores and channels within the well-defined {111} and {100}-dominated

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surfaces (Figure 1b). Since Mn contents in the mixed oxides were approaching (SI Table S3),

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both MCO-111 and MCO-110 demonstrated similar size with a diameter of approximately 50

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nm. By contrast, engineering MCO {001} facets is often uncontrolled. The crystal growth of

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MCO-001 was along the [111] direction became predominant and was confined to transform an

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irregular cylindrical shape with the exposed {001} facets. MCO-001 exhibited a small diameter

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of approximately 30 nm, but it was much less stable than the two other facets, because the crystal

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growth of ceria {001} surfaces was quite fast in the [001] direction27. The synthesis and control

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of high-quality crystal facet {001} depend on organic ligand-assisted liquid-solid-solution phase

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synthetic transfer routes32. Considering that the reversible transition of Mn4+ and Mn3+ is directly

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coupled with the localization/delocalization of the 4f electron of cerium, a high percentage of

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unsaturated atoms in the MnOx−CeO2 mixed oxides can possess superior reactivity. However,

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this effect could increase the challenge in engineering high-purity and well-defined crystal

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surfaces.

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Figure 1. XRD patterns of pristine MnO2, pristine CeO2, and MCO catalysts with different

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exposed facets (a); TEM and HRTEM images of MCO catalysts with different exposed facets

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(b); and atomic structure of MCO-111, MCO-110, and MCO-001 (c).

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TPR and TPD Profiles. Two reduction peaks were detected in a broad temperature range

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of 250 °C–500 °C, as shown in Figure 2a, indicating a reduction/oxidation cycle between

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transition-metal oxides with high valence and those with low valence during the ensuing redox

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loops of the oxidized Mn–Ce ions. By using ceria as oxygen carrier, oxygen migration was

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improved, and the redox-looping processes were sustained by ceria in the cyclic valence

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transitions of Ce4+–Mn3+ ↔ Ce3+–Mn4+12,

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XPS results (SI Figures S6a–d). The catalytic activity and stability, highly correlated with high

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oxidation states in the Mn dismutation reaction, would be affected by the reduced Mn oxides if

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they cannot be timely remediated. The consumption of lattice oxygen species could be

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replenished periodically in the ensuing redox loop of transition-metal oxides. In comparisons

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with the two other facets, the first reduction peak of MCO-111 moved to 267 °C, which

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corresponded to the consumption of surface oxygen species (Oads), because the adsorbed oxygen

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species are easily dissociated on the catalyst surface31. The reduction of cerium and manganese

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ions did not largely result in a downward shift of the reduction peaks for all the three MCO

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samples. By contrast, more apparent downward shift to low temperatures of the two reduction

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peaks of MCO-111 was due to the continuous reduction of Mn4+ to Mn2+40, 41. The intensities of

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the reduction peaks at low temperatures for MCO-111 were the highest, ascribing to the mobility

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of oxygen species and the generation of –OH species40. Larger mobility and consumption of

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lattice oxygen within MCO-111 were observed relative to MCO-110 and MCO-001. Mn4+ and

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Mn3+ were the two main Mn oxidation states in Mn 3s spectra obtained in SI Figure S7. Hence,

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the contribution of the high-temperature peak to the total reduction profile was associated with

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the manganese ions with high oxidation states (Mn4+) in the recycling redox loops. The central

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position of the reduction peaks of MCO-111 approached those of the reported Pt/MCO19, whose

14.

These findings matched with the corresponding

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catalytic activity often stands out from the majority of room-temperature catalytic oxidation

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(RCO) catalysts.

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Figure 2. H2–TPR (a) and O2–TPD (b) profiles of MCO catalysts with different exposed facets.

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The O2–TPD spectra (Figure 2b) were analyzed to initially understand the roles of oxygen

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species within the different exposed facets, which corresponded to the formation of oxygen

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vacancies and subsequently access the HCHO oxidation mechanisms. A large amount of O2

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desorbs from the catalyst at T600 °C is named as γ-O2, indicating that the remaining lattice oxygen species

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continue to decline, and high oxidation states in metal oxides are completely reduced at the high-

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temperature range41-43. Here, the O2 desorption temperature of the three facets generally shifted

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toward the low-temperature region, indicating that the MCO catalysts were favorable in low-

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temperature activity stemming from the desirable BET performance and bulk lattice oxygen

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migration of cerium-based oxygen carriers27, 31. The adsorbed O2 could be readily transformed

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into atomic oxygen (O*) and continue to form surface active oxygen (O– and O2–) at the catalyst

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surfaces40. A large amount of oxygen adsorption and migration at low temperature could benefit

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the conversion of O2 into O*, leading to HCHO oxidation. MCO-110 possessed strong O2

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desorption at the α-O2 peak range, which corresponded to the increased formation of oxygen

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vacancies on the surface relative to MCO-111 and MCO-001 and were consistent with the

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corresponding O 1s XPS spectra (SI Figure S8).

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RCO Activity and Selectivity. Figure 3a shows the turnover frequencies (TOFs), defined

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as the HCHO consumption rates per unit of surface area (molHCHO·s−1·mcat−2), over the MCO

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with different exposed facets. Under a GHSV of 4 × 104 h–1, the activities presented facet

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dependence and followed the sequence of MCO-111>MCO-110>MCO-001. The consumption

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rates of MCO-111 of approximately 7.5 × 10−4 μmol·s−1·m−2 at a low temperature range of

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25 °C–45 °C were higher than those of MCO-110 (approximately 4.5 × 10−4 μmol·s−1·m−2) and

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MCO-001 (3.0×10−4 μmol·s−1·m−2). In comparison with some typical transition metal-based

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catalysts in SI Table S4, the temperatures for complete HCHO oxidation must exceed 70 °C.

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The increase in reaction temperature can increase the selectivity toward CO2 and decrease the

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production of formic acid intermediates19. The consumption rates of MCO-111 and MCO-110

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catalysts at low temperatures were parallel with those of reported transition metal oxides at high

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temperatures. The catalytic activity of MCO-111 even approached that of some Ag-supported

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catalysts2, 44. Notably, noble metal-supported catalysts (e.g., Pt/TiO245 and Pd/TiO246) can result

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in complete HCHO conversion at near-room temperature. Considering the limitations in the

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scaling-up cost and mass dispersion control of the noble metal, transition metal oxides may be

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promising substitutes if lattice defects or oxygen vacancies are engineered to act as additional

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active sites. The recycling activity and stability of MCO with the different exposed facets were

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determined in Figure 3b. MCO-111 converted 56% HCHO into CO2 at 35 °C, followed by

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MCO-110 (50%) and MCO-001 (42%). No apparent deactivation was observed in 360 min

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reaction periods. In addition, the half reaction time (t50%) was independent on the initial reactant

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concentration (SI Figure S9), suggesting that HCHO catalytic oxidation followed a pseudo-first-

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order reaction and the RCO system could be adapted to HCHO removal at the sub-ppm level47,

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48.

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Oxygen vacancy sites are responsible for adsorption and catalytic activity. Interestingly, the

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formation of oxygen vacancies was feasible on the {110} and {001} facets but did not incur

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comparatively high activity (Figure 3). Except for the distorted electronic structure of crystals

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with different exposed facets, the activity was also influenced by the migration of definite

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surface oxygen and stability of the formed oxygen vacancies31. The quantitative effects of

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oxygen vacancies regarding to oxygen storage capacity are analyzed to demonstrate the

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migration of bulk lattice oxygen in the following section.

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Figure 3. HCHO consumption rate as a function of reaction temperature (a) and recycling

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catalytic activity and stability in 90 min of each run (b) over MCO catalysts with different

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exposed facets at 35 °C

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Quantitative Effects of Oxygen Vacancies. The oxygen vacancy defects were engineered

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to work as active centers that were correlated with adsorption, catalytic activity, and stability.

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The O2–TPD and O 1s XPS (SI Figure S8) studies roughly demonstrated oxygen speciation in

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the chemical-looping processes of metal oxides but failed to clearly elucidate the roles and

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oxygen storage capacity of definite lattice oxygen, i.e., surface lattice oxygen OS–L and bulk

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lattice oxygen OB–L31. The OS–L, rather than the surface adsorbed oxygen, was found to be

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responsible for the catalytic activity and replenished from the migration of OB–L31. Understanding

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the quantitative effects of oxygen vacancies is of practical importance in the catalyst design

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based on high-performance oxygen mobility. The mobility between the migration and

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consumption of lattice oxygen and the formation of oxygen vacancies within the exposed facets

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were investigated through the designed H2–TPR experiments.

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The corresponding H2 consumption amounts of OB–L at 600 °C for different treatment times

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are summarized in SI Table S5. The H2 consumption amounts of OB–L were approaching to a

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minimum level when the MCO samples were treated beyond 5 h. MCO-110 had the lowest H2

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consumption during the whole treatment, which was correlated with the formation of the

309

maximum oxygen vacancies within MCO-110 obtained in the O2–TPD profiles (Figure 2b). The

310

corresponding migration rate was the slowest at 8.0 × 10−3 µmol·g−1·s−1. The fastest migration

311

rate up to 1.1 × 10–2 µmol·g−1·s−1 was found for MCO-001 but failed to result in the highest

312

catalytic activity, because the {001} facet growth was somewhat suppressed by the ceria (111)

313

and (200) planes32. Oxygen vacancies were more stable within pristine ceria {111} facet than

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within pristine ceria {110} and {001}, they occurred more easily within the {110} and {001}

315

though25, 27. Aside from the stable defect structure of crystal facet, improvements in catalytic

316

activity were ascribed to the fact that the OB–L mobility at faster migration rate can replenish OS–L,

317

but the excessively fast rate within the {001} facet can decrease activity31. Oxygen vacancies

318

could result in excellent catalytic activity and stability if they were more stable on catalyst

319

surfaces.

320

As shown in Table 1, the designed H2–TPR experiment at 450 °C was performed and

321

examined at different treatment times to demonstrate the total consumption based on the

322

migration of OB–L to OS–L. The actual consumption rates of OS–L within MCO-111 were larger

323

than those within MCO-110 and MCO-001 and remained stable after 5 h treatment relative to the

324

migration rate of OB–L. However, the consumptions of OS–L cannot be completely ruled out from

325

the migration of OB–L, possibly because of some mass loss in OB–L mobility. Thus, the largest

326

consumption amounts of OS–L were not well associated with the largest consumption amounts of

327

OB–L. Therefore, OB–L through its faster migration can not only participate in the catalytic

328

reaction but also replenish the consumed OS–L. These events directly supported the importance of

329

stable oxygen vacancies within the MCO-111 facet.

330

Table 1. H2 consumption of OB–L and OS–L of MCO samples treated at 450 °C with 10% H2/Ar

331

for different treatment times. H2 consumption Samples of OB–L

Actual H2 consumption of OS–L

OB–L migration

OS–L

(µmol·g−1)

(µmol·g−1) a

(µmol·g−1) b

(µmol·g−1) Untreated MCO-111

645

consumption rate

consumption of OS–L (µmol·g−1·s−1) c

568

0

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Untreated MCO-110

549

516

0

0

0

Untreated MCO-001

676

593

0

0

0

Treated MCO-111 (1 h)

633

409

6

79.5

2.0 × 10–2

Treated MCO-110 (1 h)

539

373

5

71.5

1.8 × 10–2

Treated MCO-001 (1 h)

661

441

7.5

76

1.9 × 10–2

Treated MCO-111 (5 h)

315

166

165

201

2.0 × 10–3

Treated MCO-110 (5 h)

241

159

154

178.5

1.4 × 10–3

Treated MCO-001 (5 h)

279

163

198.5

215

0.9 × 10–3

332

a

333

300 °C–600 °C.

334

b

335

treated sample)/2.

336

c

337

L)/treatment

H2 consumption of OS–L was calculated according to TPR profiles at temperature range of

Consumption amount of OS–L = (H2 consumption of untreated sample−H2 consumption of

Actual consumption rate of OS–L = (consumption amount of OS–L−migration amount of OB– time.

338

Identification of Catalytically Active Regions and Active-Site Behaviors at Low

339

Temperatures. The activation of oxygen species and catalytic oxidation are favorable to high

340

reaction temperatures. However, the performance of the temperature-dependent catalysts that can

341

trigger their activity at low temperatures has been rarely studied. Here high-throughput screening

342

studies with IR thermography were performed to distinguish and identify catalytically active

343

regions33, 34. As shown in Figure 4, the catalytically active regions corresponding to temperature

344

variations were characterized and compared in various isothermal feeds. First, the IR absorbance

345

intensities of the different exposed facets were obtained from 25 °C–175 °C, which were closely

346

consistent with different surface active regions at varying feed temperatures (Figure 4a). The IR

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absorbance was monitored under the average of the emerging temperatures when a hot spot

348

region of IR thermography was formed on the catalyst surfaces. Small changes in the IR

349

absorbance were observed in a high temperature range of 125 °C–175 °C, despite a gradual

350

decline with increasing feed temperatures. Moreover, no huge difference in the IR absorbance

351

and retention was found among the three exposed facets at the high-temperature range. Below

352

75°C, comparatively large IR absorbance intensities were attained at MCO-111 compared with

353

MCO-110 and MCO-001. MCO-111 maintained enhanced intensity and retention of the IR

354

absorbance under the emerging temperatures at 25 °C–50 °C. The IR thermography images were

355

then recorded to visualize the active regions at low temperatures after the emerging temperature

356

reached 50 °C in Figure 4b. The amplitude (i.e., retention of the maximum emerging

357

temperature after hot spot formation) of the temperature gradient could be clearly compared at

358

the different crystal facets. The amplitude of the maximum temperature gradient was broader and

359

stronger at MCO-111 than at the two other facets, although the IR absorbance was released and

360

extinguished during cooling to 25°C. The highly active zones displayed at MCO-111 could act as

361

a reactive catalytic bed to sustain the exposure of abundant active sites and participation of

362

oxygen species at low temperatures, thereby providing the enhanced catalytic activity of MCO-

363

111 under ambient conditions.

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Figure 4. IR absorbance intensities of MCO catalysts with different exposed facets at varying

366

feed temperatures from 25 °C to 175 °C (a) and identification of catalytically active zones after

367

the emerging temperatures reached 50 °C via IR thermography images (b).

368

The types and properties of surface active sites at different exposed facets were investigated

369

through Py-IR measurements49,

50.

370

kinds of surface metal sites, i.e., Lewis acid (L-acid) and Brønsted acid (B-acid) sites, are related

371

to free electron and proton exchange at metal oxides. For transition-metal oxides, the Lewis

372

acid–base properties depend on cyclic electron transfer in the chemical-looping processes and

373

play a major role in the activation of reactive oxygen species51. As shown in Figures 5, the peaks

374

at ca. 1456 and 1610 cm−1 bands originated from pyridine adsorbed onto L-acid sites, whereas

375

the peaks at ca. 1545 and 1635 cm−1 bands were related to B-acid sites. The peak at ca. 1489

376

cm−1 originated from pyridine adsorbed onto L-acid and B-acid sites. The exposure of

Metal oxides are used for their acid–base properties. Two

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predominant L-acid sites was observed at the three major exposed facets. The Lewis/Brønsted

378

(L/B) ratio at MCO-111 was 2.85 larger than that at MCO-110 and MCO-001 with 2.11 and

379

1.94, respectively. A high degree of nucleophilic substitution was assigned to an exchange of

380

surface metal sites and atomic O*, and the hopping of hydrocarbon compounds to atomic O* was

381

preferential onto L-acid sites. B-acid sites acted as predominant active sites in favor of high

382

reaction temperatures52. Furthermore, the exposure of L-acid and B-acid sites was influenced by

383

high ambient humidity49, 50. However, many routine metallic catalysts were water-repellent that

384

affects HCHO adsorption and catalytic oxidation under ambient conditions to a certain extent.

385

Therefore, Lewis acid sites involving the superior selective adsorption of electrolyte cations were

386

presented for polar HCHO molecules induced by cyclic electron transfer. The acid–base

387

properties provided explicit evidence of strength and distribution of surface-active sites. The

388

predominance of L-acid sites at low temperatures could facilitate the activation of surface

389

oxygen species to reactive oxygen species and catalytic activity of RCO catalysts.

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390 391

Figure 5. Py-IR measurements of acid–base active sites at MCO with different exposed facets.

392

In Situ XPS and DRIFT Studies. The adsorption and reaction of HCHO over MCO

393

catalysts with different exposed facets were studied using in situ C 1s XPS measurements. As

394

shown in Figure 6a, the XPS peaks in the C 1s region were more precisely deconvoluted to

395

adventitious carbon (CA) at 284.5 eV from C–C species and at 285.5 eV from C–O–C species, to

396

formaldehyde/mono-dentate formate species (CF) at 288.2 eV, and O–C=O (carboxylate species

397

= CCB) at 289.1 eV53, 54. These peaks were consistent with the assignment of chemical bonds to

398

the BE of C 1s peaks in SI Table S2. CF signals were retained on the three exposed facets, and

399

more evolutions of CA were found for MCO-111. The C 1s core level envelope presented an

400

important contribution at the BE of CF at temperatures below 50 °C. The intensities of CCB 22

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photopeaks were lower than those of CF and CA photopeaks for the three samples. The formation

402

of CA favored increased reaction temperatures, which was preferential to CO oxidation and CO2

403

yield. Both formaldehyde and formate species were bonded end-on through the oxygen atom,

404

and the rapid conversion of CCB species continued. Therefore, physisorption was an initial

405

preadsorption step, chemisorption started with physisorption, and the strong interaction between

406

the adsorbate and sorbent surface created new types of electronic bonds (ionic or covalent). The

407

chemisorption and oxidation of HCHO were derived from H bonding of formaldehyde and

408

formate groups and bridging of CCB preferentially with oxygen atom in the MCO surfaces50, 55.

409

These findings matched well with the quantitative effects of oxygen vacancies in which excess

410

defects could not sustain the oxygen species-oriented active sites involved in the adsorption and

411

oxidation.

412

The formation of intermediate species for HCHO decomposition at 35 °C was examined

413

through in situ DRIFT spectra (Figure 6b). All transient reaction results represented the main

414

intermediates that were ascribed to formate species (including carboxylate), carbonate, CO2, and

415

water vapor. The absorbance intensities of the CO2 peak (ca. 2380 cm−1) and surface hydroxyl

416

species (a broad OH stretching region located at ca. 3580 cm−1, denoted as υs [OH]) increased

417

significantly for MCO-111 compared with exposure of MCO-110 and MCO-001 to HCHO/O2.

418

The symmetric stretching OH possesses a strongly hydrogen bonded water structure and could

419

facilitate the chemisorption of HCHO in terms of hydroxyl bonding preferable with the methyl

420

groups under low temperature and relative humidity50. MCO-111 achieved comparatively high

421

catalytic activity for HCHO conversion, producing CO2 and water vapor as final products. In

422

brief, HCHO peaks (ca. 1680 cm−1) weakened with reaction time and new typical bands

423

indicated the gradual generation of formate species (quite weak at ca. 2840 cm−1 for υs [CH], ca.

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1466 cm−1 for δ [CH2], ca. 1601 cm−1 for υs [COO], and ca. 1350 and 1314 cm−1 for υas

425

[COO])55,

426

attack of the reactive oxygen atom. The intensities of –CH2 and –OH were stronger than those of

427

the –CH match. In fact, the ensuing conversions from the intermediate CH2OO are more

428

complex than those from HCHO initially, because distinct and complex chemical speciation and

429

reactivity pathways of the CH2OO isomers (i.e., formic acid, dioxirane, and CH2OO Criegee)

430

have been found50. The conversions of HCHO into formic acid and dioxirane preferentially occur

431

through monodentate binding and bidentate coordination with metal sites of catalysts,

432

respectively. The production and removal of CH2OO Criegee are rather complex and probably

433

involved in side or secondary processes. CH2OO Criegee has some single bond characters, which

434

are assumed to a rapid dissociation of C–C and O–O bonds from the oxidation of unsaturated

435

carboxyl groups.

56.

The decomposition of –COO and –CH2 species resulted from the nucleophilic

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Figure 6. In situ C 1s XP spectra as a function of reaction temperature of the HCHO-exposed

438

MCO catalysts with different exposed facets (a) and in situ DRIFT spectra of bond cleavage at

439

35 °C (b).

440

Practical Application in Household Air Cleaner and In-field Pilot Test. MnOx–CeO2 25

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samples with the exposed {111} facet were examined with respect to room-temperature catalytic

442

activity in laboratory scale and were about to be validated in an in-field test for actual HCHO

443

removal. First, a prototype of a household air cleaner was designed and equipped with a filter

444

cylinder cartridge in Figure 7, whose main dimensions and operating conditions are listed in SI

445

Table S6. The cylinder cartridge consisted of five sets of porous filtration units, that is, non-

446

woven fabric filter, high efficiency particulate air (HEPA) filter, two layers of nylon fabric filter,

447

and polytetrafluoroethylene (PTFE) keel shirt, and operated through outside-in filtration. Test

448

MCO-111 particles in a sieve fraction of 140 meshes (approximately 106 μm) were scaled-up

449

and immobilized with a loading density of approximately 0.30 g·cm−2 between two layers of

450

nylon fabric filter. The fabric filter mainly removed fine particulate matter and priority gaseous

451

pollutants in indoor air (e.g., HCHO and NOx). Airflow was controlled with a built-in air pump

452

(maximum airflow, 400 m3·h−1), and purified air was released from the outlet at the top of the air

453

cleaner. After the majority of particulate matter was pre-filtered through the multi-layer

454

filtration, gaseous pollutants were in contact with the catalyst and then oxidized into harmless

455

substances under ambient conditions.

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Figure 7. Scaling-up MCO-111 filter substrates filled in the filter cylinder cartridge of a

458

household air cleaner.

459

To evaluate the HCHO removal efficiency of the MCO-111 catalyst, we conducted an in-

460

field pilot test of the household air cleaner at a newly decorated office without the use of

461

ventilation under the ambient condition of averaging RH = 68% and T = 27.5 oC, as shown in

462

Figure 8. The concentration of HCHO during a round switch-on (8 h) and -off (8 h) of the air

463

cleaner was continuously measured using a portable analyzer (Interscan 4160, USA) and double-

464

checked in the on-site measurement for 5 days. According to the air cleaner standard (GB/T

465

18801–2015, China), the sampling inlet of the analyzer was kept at a vertical distance higher

466

than 0.8 m with the ground and a horizontal distance of 1.75 m from the purified air outlet of the

467

air cleaner in a 30 m3 test site. When the air cleaner started to work, the concentration of HCHO

468

dramatically decreased and remained as low as 20 ppb over an 8 h period, which satisfied with

469

the Excellent Class (30 µg·m−3, equal with std. 24 ppb of an 8 h average) of Indoor Air Quality

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Certification Scheme for Offices and Public Places issued in Hong Kong. By contrast, when

471

switched off, the concentration of HCHO gradually recovered to its initial level at approximately

472

120 ppb, exceeding a maximum exposure of 100 ppb (equal with std. 81 ppb of an 8 h average)

473

indoors. HCHO emissions in indoor air are long-lasting and result from a source complex, such

474

as building materials, furnishings, and occupant activities. The situation is aggravated during a

475

lack of ventilation in most enclosed areas, thereby seriously burdening long-term removal

476

efficiency. The routine household air cleaner, mainly equipped with porous-media filters, shows

477

a very insufficient ability in removing gaseous pollutants. A very few commercial air cleaners

478

are available in the combined use of catalytic oxidation and mechanical filtration. Therefore, the

479

test MCO-111 catalyst can work synergically to optimize and maximize the air cleaner

480

performance for the removal of HCHO. Furthermore, this work has a proper strategy

481

recommendation for translating laboratory research into commercial value in large scale to

482

eliminate HCHO in indoor air via the efficient and cost-effective catalytic oxidation to attain the

483

standard protocols of indoor air quality.

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Figure 8. In-filed pilot tests of the household air cleaner for HCHO removal in 5 days. Inset

486

photo images: on-site measurements at a newly decorated office (approximately 30 m3) without

487

ventilation.

488

ASSOCIATED CONTENT

489

Supporting Information. The Supporting Information associated with this article can be found

490

in this section, including the detailed methods of characterizations by H2–TPR, O2–TPD, Py-IR,

491

infrared thermography, in situ XPS and DRIFT, catalytic activity measurement, assignment of

492

chemical bonds to BEs of C 1s peaks, BET performance, TGA of MCO-111, TEM and HRTEM

493

of precursor ceria {111} and {110}, survey of catalytic activity for HCHO oxidation over typical

494

RCO catalysts, migration of OB–L, high-resolution XPS spectra of surface chemical compositions,

495

determination of the half reaction time (t50%), and specification of the filter cylinder cartridge in a

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test prototype of the household air cleaner.

497

AUTHOR INFORMATION

498

Corresponding Authors

499

*Prof. Shun-cheng Lee (Email: [email protected])

500

*Prof. Yu Huang (Email: [email protected])

501

Notes

502

The authors declare no competing interests.

503

Acknowledgements

504

This work was supported by the National Key Research and Development Program of China

505

(2016YFA0203000), the Research Grants Council of Hong Kong Government (Project No.

506

T24/504/17), the Research Grants Council of Hong Kong Government (Project No.

507

PolyU152083/14E, PolyU152090/15E, and 18301117), and the Hong Kong RGC Collaborative

508

Research Fund (C5022-14G). Yu Huang was also supported by the “Hundred Talent Program”

509

of the Chinese Academy of Sciences.

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Figure 1 127x101mm (600 x 600 DPI)

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Figure 2 152x76mm (600 x 600 DPI)

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Figure 4 88x63mm (600 x 600 DPI)

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Figure 5 84x65mm (600 x 600 DPI)

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