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3. Water-based 2-dimensional anatase TiO2 inks for printed diodes and transistors

Author

Omar Kassem, Lorenzo Pimpolari, Chaochao Dun, Dmitry K. Polyushkin, Marco Zarattini, Elisabetta Dimaggio, Liming Chen, Giovanni Basso, Federico Parenti, Jeffrey J. Urban, Thomas Mueller, Gianluca Fiori, and Cinzia Casiraghi

Subjects
General Materials Science
Abstract

TiO2 nanosheets are produced with a mass scalable and F-free bottom-up approach. The material is formulated into a stable water-based ink and exploited in printed diodes and transistors, showing very good dielectric properties.

Published
2023
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7. Iron(III) Dopant Counterions Affect the Charge-Transport Properties of Poly(Thiophene) and Poly(Dialkoxythiophene) Derivatives

Author

Khaled Al Kurdi, Shawn A. Gregory, Madeleine P. Gordon, James F. Ponder Jr, Amalie Atassi, Joshua M. Rinehart, Austin L. Jones, Jeffrey J. Urban, John R. Reynolds, Stephen Barlow, Seth R. Marder, and Shannon K. Yee

Subjects
General Materials Science
Abstract

This study investigates the charge-transport properties of poly(3-hexylthiophene-2,5-diyl) (P3HT) and poly(ProDOT

Published
2022
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8. Dimensional Control over Metal Halide Perovskite Crystallization Guided by Active Learning

Author

Matthias Zeller, Zhi Li, Chaochao Dun, Wissam A. Saidi, Alexander J. Norquist, Jeffrey J. Urban, Mansoor Ani Najeeb, Joshua Schrier, Philip Nega, and Emory M. Chan

Subjects
Materials science, Active learning (machine learning), General Chemical Engineering, Halide, General Chemistry, law.invention, Range (mathematics), Data acquisition, Engineering, law, Phase (matter), Chemical Sciences, Materials Chemistry, Crystallization, Biological system, Materials, Perovskite (structure), Curse of dimensionality
Abstract

Metal halide perovskite (MHP) derivatives, a promising class of optoelectronic materials, have been synthesized with a range of dimensionalities that govern their optoelectronic properties and determine their applications. We demonstrate a data-driven approach combining active learning and high-throughput experimentation to discover, control, and understand the formation of phases with different dimensionalities in the morpholinium (morph) lead iodide system. Using a robot-assisted workflow, we synthesized and characterized two novel MHP derivatives that have distinct optical properties: a one-dimensional (1D) morphPbI3 phase ([C4H10NO][PbI3]) and a two-dimensional (2D) (morph)2PbI4 phase ([C4H10NO]2[PbI4]). To efficiently acquire the data needed to construct a machine learning (ML) model of the reaction conditions where the 1D and 2D phases are formed, data acquisition was guided by a diverse-mini-batch-sampling active learning algorithm, using prediction confidence as a stopping criterion. Querying the ML model uncovered the reaction parameters that have the most significant effects on dimensionality control. Based on these insights, we discuss possible reaction schemes that may selectively promote the formation of morph-Pb-I phases with different dimensionalities. The data-driven approach presented here, including the use of additives to manipulate dimensionality, will be valuable for controlling the crystallization of a range of materials over large reaction-composition spaces.

Published
2022
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10. Selective Pb2+ removal and electrochemical regeneration of fresh and recycled FeOOH

Author

Lei Wang, Lexane Deligniere, Samantha Husmann, Regina Leiner, Carsten Bahr, Shengjie Zhang, Chaochao Dun, Matthew M. Montemore, Markus Gallei, Jeffrey J. Urban, Choonsoo Kim, and Volker Presser

Subjects
General Materials Science, Electrical and Electronic Engineering, Condensed Matter Physics, Atomic and Molecular Physics, and Optics
Abstract

Heavy metal pollution is a key environmental problem. Selectively extracting heavy metals could accomplish water purification and resource recycling simultaneously. Adsorption is a promising approach with a facile process, adaptability for the broad concentration of feed water, and high selectivity. However, the adsorption method faces challenges in synthesizing high-performance sorbents and regenerating adsorbents effectively. FeOOH is an environmentally friendly sorbent with low-cost production on a large scale. Nevertheless, the selectivity behavior and regeneration of FeOOH are seldom studied. Therefore, we investigated the selectivity of FeOOH in a mixed solution of Co2+, Ni2+, and Pb2+ and proposed to enhance the capacity of FeOOH and regenerate it by using external charges. Without charge, the FeOOH electrode shows a Pb2+ uptake capacity of 20 mg/g. After applying a voltage of −0.2/+0.8 V, the uptake capacity increases to a maximum of 42 mg/g and the desorption ratio is 70%–80%. In 35 cycles, FeOOH shows a superior selectivity towards Pb2+ compared with Co2+ and Ni2+, with a purity of 97% ± 3% in the extracts. The high selectivity is attributed to the lower activation energy for Pb2+ sorption. The capacity retentions at the 5th and the 35th cycles are ca. 80% and ca. 50%, respectively, comparable to the chemical regeneration method. With industrially exhausted granular ferric hydroxide as the electrode material, the system exhibits a Pb2+ uptake capacity of 37.4 mg/g with high selectivity. Our work demonstrates the feasibility of regenerating FeOOH by charge and provides a new approach for recycling and upcycling FeOOH sorbent.

Published
2023
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12. Selective hydrogenation via precise hydrogen bond interactions on catalytic scaffolds

Author

Song Shi, Piaoping Yang, Chaochao Dun, Weiqing Zheng, Jeffrey J. Urban, and Dionisios G. Vlachos

Subjects
Multidisciplinary, General Physics and Astronomy, General Chemistry, General Biochemistry, Genetics and Molecular Biology
Abstract

Abstract The active site environment in enzymes has been known to affect catalyst performance through weak interactions with a substrate, but precise synthetic control of enzyme inspired heterogeneous catalysts remains challenging. Here, we synthesize hyper-crosslinked porous polymer (HCPs) with solely -OH or -CH3 groups on the polymer scaffold to tune the environment of active sites. Reaction rate measurements, spectroscopic techniques, along with DFT calculations show that HCP-OH catalysts enhance the hydrogenation rate of H-acceptor substrates containing carbonyl groups whereas hydrophobic HCP- CH3 ones promote non-H bond substrate activation. The functional groups go beyond enhancing substrate adsorption to partially activate the C = O bond and tune the catalytic sites. They also expose selectivity control in the hydrogenation of multifunctional substrates through preferential substrate functional group adsorption. The proposed synthetic strategy opens a new class of porous polymers for selective catalysis.

Published
2023

13. Temperature-adaptive radiative coating for all-season household thermal regulation

Author

Kechao Tang, Kaichen Dong, Jiachen Li, Madeleine P. Gordon, Finnegan G. Reichertz, Hyungjin Kim, Yoonsoo Rho, Qingjun Wang, Chang-Yu Lin, Costas P. Grigoropoulos, Ali Javey, Jeffrey J. Urban, Jie Yao, Ronnen Levinson, and Junqiao Wu

Subjects
Multidisciplinary, Affordable and Clean Energy, General Science & Technology
Abstract

The sky is a natural heat sink that has been extensively used for passive radiative cooling of households. A lot of focus has been on maximizing the radiative cooling power of roof coating in the hot daytime using static, cooling-optimized material properties. However, the resultant overcooling in cold night or winter times exacerbates the heating cost, especially in climates where heating dominates energy consumption. We approached thermal regulation from an all-season perspective by developing a mechanically flexible coating that adapts its thermal emittance to different ambient temperatures. The fabricated temperature-adaptive radiative coating (TARC) optimally absorbs the solar energy and automatically switches thermal emittance from 0.20 for ambient temperatures lower than 15°C to 0.90 for temperatures above 30°C, driven by a photonically amplified metal-insulator transition. Simulations show that this system outperforms existing roof coatings for energy saving in most climates, especially those with substantial seasonal variations.

Published
2021
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14. Synthesis of new<scp>two‐dimensional</scp>titanium carbonitride<scp>Ti2C0</scp>.<scp>5N0</scp>.5Tx<scp>MXene</scp>and its performance as an electrode material for<scp>sodium‐ion</scp>battery

Author

Kun Liang, Anika Tabassum, Ahmad Majed, Chaochao Dun, Feipeng Yang, Jinghua Guo, Kaitlyn Prenger, Jeffrey J. Urban, and Michael Naguib

Subjects
Materials Science (miscellaneous), Materials Chemistry, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials
Published
2021
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16. Morphological Ordering of the Organic Layer for High-Performance Hybrid Thermoelectrics

Author

Lin Yang, Yi Tao, Madeleine P. Gordon, Akanksha K. Menon, Yunfei Chen, Ravi S. Prasher, and Jeffrey J. Urban

Subjects
General Materials Science
Abstract

Inorganic-organic hybrids, such as Te-PEDOT:PSS core/shell nanowires, have emerged as a class of promising thermoelectric materials with combined attributes of mechanical flexibility and low cost. However, the poorly understood structure-property relationship calls for further investigation for performance enhancement. Here, through precise treatments of focused electron beam irradiation and thermal annealing on individual Te-PEDOT:PSS nanowires, new, nonchemical mechanisms are introduced to specifically engineer the organic phase, and the measured results provide an unprecedented piece of evidence, confirming the dominant role of organic shell in charge transport. Paired with the Kang-Snyder model and molecular dynamics simulations, this work provides mechanistic insights in terms of heating-enabled morphological ordering of the polymer chains. The measured results show that thermal annealing on the 42 nm nanowire results in a ZT value of 0.78 at 450 K. Through leveraging the interfacial self-assembly of the organic phase to construct a high electrical conductivity domain, this work lays out a clear framework for the development of next-generation soft thermoelectrics.

Published
2022

17. Tuning Phonon Energies in Lanthanide‐doped Potassium Lead Halide Nanocrystals for Enhanced Nonlinearity and Upconversion

Author

Zhuolei Zhang, Artiom Skripka, Jakob C. Dahl, Chaochao Dun, Jeffrey J. Urban, Daniel Jaque, P. James Schuck, Bruce E. Cohen, and Emory M. Chan

Subjects
General Medicine, General Chemistry, Catalysis
Abstract

Optical applications of lanthanide-doped nanoparticles require materials with low phonon energies to minimize nonradiative relaxation and promote nonlinear processes like upconversion. Heavy halide hosts offer low phonon energies but are challenging to synthesize as nanocrystals. Here, we demonstrate the size-controlled synthesis of low-phonon-energy KPb2X5 (X = Cl, Br) nanoparticles and the ability to tune nanocrystal phonon energies as low as 128 cm-1. KPb2Cl5 nanoparticles are moisture resistant and can be efficiently doped with lighter lanthanides. The low phonon energies of KPb2X5 nanoparticles promote upconversion luminescence from higher lanthanide excited states and enable highly nonlinear, avalanche-like emission from KPb2Cl5:Nd3+ nanoparticles. The realization of nanoparticles with tunable, ultra-low phonon energies facilitates the discovery of nanomaterials with phonon-dependent properties, precisely engineered for applications in nanoscale imaging, sensing, luminescence thermometry and energy conversion.

Published
2022
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18. Hydrogen Storage in Partially Exfoliated Magnesium Diboride Multilayers

Author

Harini Gunda, Keith G. Ray, Leonard E. Klebanoff, Chaochao Dun, Maxwell A. T. Marple, Sichi Li, Peter Sharma, Raymond W. Friddle, Joshua D. Sugar, Jonathan L. Snider, Robert D. Horton, Brendan C. Davis, Jeffery M. Chames, Yi‐Sheng Liu, Jinghua Guo, Harris E. Mason, Jeffrey J. Urban, Brandon C. Wood, Mark D. Allendorf, Kabeer Jasuja, and Vitalie Stavila

Subjects
Biomaterials, General Materials Science, General Chemistry, Biotechnology
Abstract

Metal boride nanostructures have shown significant promise for hydrogen storage applications. However, the synthesis of nanoscale metal boride particles is challenging because of their high surface energy, strong inter- and intraplanar bonding, and difficult-to-control surface termination. Here, it is demonstrated that mechanochemical exfoliation of magnesium diboride in zirconia produces 3-4 nm ultrathin MgB

Published
2022

19. Flexible all-organic nanocomposite films interlayered with in situ synthesized covalent organic frameworks for electrostatic energy storage

Author

He Li, Zongliang Xie, Chongqing Yang, Junpyo Kwon, Antoine Lainé, Chaochao Dun, Alexander V. Galoustian, Xinle Li, Peng Liu, Jeffrey J. Urban, Zongren Peng, Miquel Salmeron, Robert O. Ritchie, Ting Xu, and Yi Liu

Subjects
Renewable Energy, Sustainability and the Environment, General Materials Science, Electrical and Electronic Engineering
Published
2023
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20. Recent developments in filtration media and respirator technology in response to COVID-19

Author

Peter L. Wang, Yuepeng Zhang, Lonnie J. Love, M. Parans Paranthaman, Corson L. Cramer, Chris Zangmeister, Alex Roschli, Jeffrey J. Urban, and Merlin Theodore

Subjects
Manufacturing methods, business.product_category, Coronavirus disease 2019 (COVID-19), Mechanical Engineering, N95 respirators and filter, Supply chain, Stockpile, Economic shortage, Materials Engineering, Review Article, Reuse, Condensed Matter Physics, Manufacturing engineering, Macromolecular and Materials Chemistry, law.invention, law, General Materials Science, Filtration efficiency, Physical and Theoretical Chemistry, Respirator, business, Antiviral properties, Filtration, Applied Physics
Abstract

Abstract The COVID-19 pandemic triggered a surge in demand for N95 or equivalent respirators that the global supply chain was unable to satisfy. This shortage in critical equipment has inspired research that addresses the immediate problems and has accelerated the development of the next-generation filtration media and respirators. This article provides a brief review of the most recent work with regard to face respirators and filtration media. We discuss filtration efficiency of the widely utilized cloth masks. Next, the sterilization of and reuse of existing N95 respirators to extend the existing stockpile is discussed. To expand near-term supplies, optimization of current manufacturing methods, such as melt-blown processes and electrospinning, has been explored. Future manufacturing methods have been investigated to address long-term supply shortages. Novel materials with antiviral and sterilizable properties with the ability for multiple reuses have been developed and will contribute to the development of the next generation of longer lasting multi-use N95 respirators. Finally, additively manufactured respirators are reviewed, which enable a rapidly deployable source of reusable respirators that can use any filtration fabric. Graphic abstract

Published
2021
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21. Insights into the Mechanism of Methanol Steam Reforming Tandem Reaction over CeO2 Supported Single-Site Catalysts

Author

Ji Su, Xinxing Peng, Luning Chen, Jeng-Lung Chen, Jeffrey J. Urban, Xibo Zhang, Jinghua Guo, Melissa Young, Chih-Wen Pao, Chaochao Dun, David Prendergast, Zhiyuan Qi, and Gabor A. Somorjai

Subjects
Reaction mechanism, Chemistry, Inorganic chemistry, General Chemistry, Biochemistry, Catalysis, Water-gas shift reaction, Steam reforming, chemistry.chemical_compound, Colloid and Surface Chemistry, Cascade reaction, Dehydrogenation, Methanol, Hydrogen production
Abstract

We demonstrated how the special synergy between a noble metal single site and neighboring oxygen vacancies provides an "ensemble reaction pool" for high hydrogen generation efficiency and carbon dioxide (CO2) selectivity of a tandem reaction: methanol steam reforming. Specifically, the hydrogen generation rate over single site Ru1/CeO2 catalyst is up to 9360 mol H2 per mol Ru per hour (579 mLH2 gRu-1 s-1) with 99.5% CO2 selectivity. Reaction mechanism study showed that the integration of metal single site and O vacancies facilitated the tandem reaction, which consisted of methanol dehydrogenation, water dissociation, and the subsequent water gas shift (WGS) reaction. In addition, the strength of CO adsorption and the reaction activation energy difference between methanol dehydrogenation and WGS reaction play an important role in determining the activity and CO2 selectivity. Our study paves the way for the further rational design of single site catalysts at the atomic scale. Furthermore, the development of such highly efficient and selective hydrogen evolution systems promises to deliver highly desirable economic and ecological benefits.

Published
2021
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22. A General Route to Flame Aerosol Synthesis and In Situ Functionalization of Mesoporous Silica

Author

Shuo Liu, Chaochao Dun, Junjie Chen, Satyarit Rao, Mihir Shah, Jilun Wei, Kaiwen Chen, Zhengxi Xuan, Eleni A. Kyriakidou, Jeffrey J. Urban, and Mark T. Swihart

Subjects
Methane Reforming, Catalysts, Mesoporous Silica, Affordable and Clean Energy, Chemical Sciences, Organic Chemistry, Flame Aerosol Process, General Medicine, General Chemistry, In Situ Functionalization, Catalysis
Abstract

Mesoporous silica is a versatile material for energy, environmental, and medical applications. Here, for the first time, we report a flame aerosol synthesis method for a class of mesoporous silica with hollow structure and specific surface area exceeding 1000 m2 g-1 . We show its superior performance in water purification, as a drug carrier, and in thermal insulation. Moreover, we propose a general route to produce mesoporous nanoshell-supported nanocatalysts by in situ decoration with active nanoclusters, including noble metal (Pt/SiO2 ), transition metal (Ni/SiO2 ), metal oxide (CrO3 /SiO2 ), and alumina support (Co/Al2 O3 ). As a prototypical application, we perform dry reforming of methane using Ni/SiO2 , achieving constant 97 % CH4 and CO2 conversions for more than 200 hours, dramatically outperforming an MCM-41 supported Ni catalyst. This work provides a scalable strategy to produce mesoporous nanoshells and proposes an in situ functionalization mechanism to design and produce flexible catalysts for many reactions.

Published
2022
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23. Modifying Li+ and Anion Diffusivities in Polyacetal Electrolytes: A Pulsed-Field-Gradient NMR Study of Ion Self-Diffusion

Author

Lorena S. Grundy, Hasan Celik, Nitash P. Balsara, Geoffrey W. Coates, Jeffrey J. Urban, Youngwoo Choo, David Prendergast, Brooks A. Abel, Rachel L. Snyder, K. Gao, Michael D. Galluzzo, Zach J. Hoffman, Madeleine P. Gordon, David M. Halat, Jeffrey A. Reimer, and Siddharth Sundararaman

Subjects
chemistry.chemical_classification, Ethylene oxide, General Chemical Engineering, Diffusion, chemistry.chemical_element, General Chemistry, Polymer, Nuclear magnetic resonance spectroscopy, Electrolyte, Ion, chemistry.chemical_compound, chemistry, Materials Chemistry, Physical chemistry, Lithium, Pulsed field gradient
Abstract

Author(s): Halat, DM; Snyder, RL; Sundararaman, S; Choo, Y; Gao, KW; Hoffman, ZJ; Abel, BA; Grundy, LS; Galluzzo, MD; Gordon, MP; Celik, H; Urban, JJ; Prendergast, D; Coates, GW; Balsara, NP; Reimer, JA | Abstract: Polyacetal electrolytes have been demonstrated as promising alternatives to liquid electrolytes and poly(ethylene oxide) (PEO) for rechargeable lithium-ion batteries; however, the relationship between polymer structure and ion motion is difficult to characterize. Here, we study structure-property trends in ion diffusion with respect to polymer composition for a systematic series of five polyacetals with varying ratios of ethylene oxide (EO) to methylene oxide (MO) units, denoted as P(xEO-yMO), and PEO. We first use 7Li and 19F pulsed-field-gradient NMR spectroscopy to measure cation and anion self-diffusion, respectively, in polymer/lithium bis(trifluoromethanesulfonyl)imide (LiTFSI) salt mixtures. At 90 °C, we observe modest changes in Li+ diffusivity across all polymer compositions, while anion (TFSI-) self-diffusion coefficients decrease significantly with increasing MO content. At a given reduced temperature (T - Tg), all polyacetal electrolytes exhibit faster Li+ self-diffusion than PEO. Intriguingly, P(EO-MO) and P(EO-2MO) also show slower TFSI- anion self-diffusion than PEO at a given reduced temperature. Molecular dynamics simulations reveal that shorter distances between acetal oxygen atoms (O-CH2-O) compared to ether oxygens (O-CH2-CH2-O) promote more diverse, often asymmetric, Li+ coordination environments. Raman spectra reveal that anion-rich ion clusters in P(EO-MO) and P(EO-2MO) lead to decreased anion diffusivity, which along with increased cation diffusivity, support the viability of polyacetals as high-performance polymer electrolytes.

Published
2021
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24. Melting Point Depression and Phase Identification of Sugar Alcohols Encapsulated in ZIF Nanopores

Author

Chris Dames, Jeffrey J. Urban, and Hyungmook Kang

Subjects
Phase transition, Materials science, Nanoporous, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, law.invention, Amorphous solid, General Energy, Thermal conductivity, Chemical engineering, law, Phase (matter), Physical and Theoretical Chemistry, Crystallization, 0210 nano-technology, Melting-point depression, Zeolitic imidazolate framework
Abstract

Author(s): Dames, C; Urban, JJ; Kang, H | Abstract: Sugar alcohols (SAs) have attractive characteristics as phase-change materials, but their relatively high melting temperature limits their application in the real world. Nanoconfinement can be a useful parameter to reduce the melting temperature to pragmatic ranges. Using molecular dynamics simulations, we investigate the phases and behaviors of encapsulated SA in ZIF-8 and ZIF-11, which cannot be experimentally observed. Based on reliable partial charges for the zeolitic imidazolate framework (ZIF) structures calculated by a density functional theory, structural analysis shows that the SA's attractive interaction with the ZIF structure frustrates the SA crystallization and also elucidates the second-order phase transition between amorphous phases. A methodology is suggested to determine the phase transition temperature of confined materials and used to quantify the melting temperature depression of the ZIF-confined SAs. We also explored the thermal conductivity of SA-in-ZIF composites. Phonon frequency analysis verifies that the presence of SA molecules enhances the heat transfer by adding heat pathways between the nanoporous structure of ZIFs.

Published
2021
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25. Solar Desalination Using Thermally Responsive Ionic Liquids Regenerated with a Photonic Heater

Author

Ravi Prasher, Akanksha K. Menon, Robert Kostecki, Jeffrey J. Urban, Andrew Z. Haddad, and Hyungmook Kang

Subjects
Osmosis, Materials science, business.industry, Forward osmosis, Ionic Liquids, Water, General Chemistry, 010501 environmental sciences, 01 natural sciences, Produced water, Desalination, Water Purification, Renewable energy, Heat transfer, Thermal, Heat exchanger, Sunlight, Environmental Chemistry, Solar desalination, Process engineering, business, 0105 earth and related environmental sciences
Abstract

Growing global water demand has brought desalination technologies to the forefront for freshwater production from nontraditional water sources. Among these, forward osmosis (FO) is a promising two-step desalination process (draw dilution and regeneration), but it is often overlooked due to the energy requirements associated with draw regeneration. To address this limiting factor, we demonstrate FO desalination using thermally responsive ionic liquids (ILs) that are regenerated using a renewable energy input, that is, solar heat. To efficiently harness sunlight, a simple photonic heater converts incoming irradiation into infrared wavelengths that are directly absorbed by IL-water mixtures, thereby inducing phase separation to yield clean water. This approach is markedly different as it uses radiative heating, a noncontact mode of heat transfer that couples to chemical functional groups within the IL for rapid energy transfer without a heat exchanger or secondary fluid. Overall, a solar-thermal separation efficiency of 50% is achieved under unconcentrated sunlight, which can be increased to 69% with the thermal design. Successful desalination of produced water from oil wells in Southern California highlights the potential of solar-powered IL-FO for energy-efficient and low-cost desalination of complex brines for beneficial water reuse.

Published
2021
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26. Lightweight wearable thermoelectric cooler with rationally designed flexible heatsink consisting of phase-change material/graphite/silicone elastomer

Author

Chaochao Dun, Madeleine P. Gordon, Jaeyoo Choi, Jeffrey J. Urban, and Carlos Forsythe

Subjects
Materials science, Thermoelectric cooling, Renewable Energy, Sustainability and the Environment, Wearable computer, Mechanical engineering, 02 engineering and technology, General Chemistry, Heat sink, 010402 general chemistry, 021001 nanoscience & nanotechnology, Cooling capacity, Elastomer, 01 natural sciences, Phase-change material, Durability, 0104 chemical sciences, Thermoelectric effect, General Materials Science, 0210 nano-technology
Abstract

In this paper, we propose a lightweight wearable thermoelectric (TE) cooler with a rationally designed flexible heatsink. Heatsinks are commonly designed for use with stationary applications, and are consequently rigid and heavy. These traditional heatsinks are incompatible with wearable applications, which must be durable, mechanically flexible, and lightweight while maintaining performance. This paper presents a flexible heatsink based on a ternary composite of silicone elastomer, phase-change material, and graphite powder; this combination is needed to achieve high flexibility and durability as well as the optimum heat capacity and thermal conductivity. Those factors are key requirements for a heatsink to optimize the cooling performance of a TE cooler and maintain a longer cooling capacity. With our optimized ternary composite flexible heatsink, we achieved a cooling temperature of ∼5 K at 0.5 W input power and kept cooling for more than 5 h under ambient conditions. On-body testing of the wearable TE cooler with flexible heatsink was also performed to demonstrate potential applications in the real-world. Our work provides fundamental insights to designing wearable TE devices and paves the way for innovative solutions for on-body thermal management applications such as clothing, hats, seat cushions, and other portable devices.

Published
2021
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27. Stabilized open metal sites in bimetallic metal–organic framework catalysts for hydrogen production from alcohols

Author

Ji Su, Joshua D. Sugar, Mark D. Allendorf, Chaochao Dun, Luning Chen, Gabor A. Somorjai, Pragya Verma, Vitalie Stavila, Farid El Gabaly, Jonathan L. Snider, David Prendergast, Jeffery M. Chames, A. Alec Talin, and Jeffrey J. Urban

Subjects
Hydrogen, Renewable Energy, Sustainability and the Environment, Inorganic chemistry, chemistry.chemical_element, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Catalysis, chemistry.chemical_compound, chemistry, Hydrogenolysis, General Materials Science, Dehydrogenation, Metal-organic framework, Methanol, 0210 nano-technology, Bimetallic strip, Hydrogen production
Abstract

Liquid organic hydrogen carriers such as alcohols and polyols are a high-capacity means of transporting and reversibly storing hydrogen that demands effective catalysts to drive the (de)hydrogenation reactions under mild conditions. We employed a combined theory/experiment approach to develop MOF-74 catalysts for alcohol dehydrogenation and examine the performance of the open metal sites (OMS), which have properties analogous to the active sites in high-performance single-site catalysts and homogeneous catalysts. Methanol dehydrogenation was used as a model reaction system for assessing the performance of five monometallic M-MOF-74 variants (M = Co, Cu, Mg, Mn, Ni). Co-MOF-74 and Ni-MOF-74 give the highest H2 productivity. However, Ni-MOF-74 is unstable under reaction conditions and forms metallic nickel particles. To improve catalyst activity and stability, bimetallic (NixMg1−x)-MOF-74 catalysts were developed that stabilize the Ni OMS and promote the dehydrogenation reaction. An optimal composition exists at (Ni0.32Mg0.68)-MOF-74 that gives the greatest H2 productivity, up to 203 mL gcat−1 min−1 at 300 °C, and maintains 100% selectivity to CO and H2 between 225–275 °C. The optimized catalyst is also active for the dehydrogenation of other alcohols. DFT calculations reveal that synergistic interactions between the open metal site and the organic linker lead to lower reaction barriers in the MOF catalysts compared to the open metal site alone. This work expands the suite of hydrogen-related reactions catalyzed by MOF-74 which includes recent work on hydroformulation and our earlier reports of aryl-ether hydrogenolysis. Moreover, it highlights the use of bimetallic frameworks as an effective strategy for stabilizing a high density of catalytically active open metal sites.

Published
2021
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28. Copper sulfide as the cation exchange template for synthesis of bimetallic catalysts for CO2electroreduction

Author

Jeffrey J. Urban, Junrui Li, Jiajun Gu, Chaochao Dun, Chen Wenshu, Jinghan Li, Di Zhang, and Joel W. Ager

Subjects
General Chemical Engineering, Inorganic chemistry, 02 engineering and technology, General Chemistry, Overpotential, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrocatalyst, 01 natural sciences, 0104 chemical sciences, Catalysis, Copper sulfide, chemistry.chemical_compound, chemistry, Formate, 0210 nano-technology, Selectivity, Bimetallic strip, Nanosheet
Abstract

Among metals used for CO2 electroreduction in water, Cu appears to be unique in its ability to produce C2+ products like ethylene. Bimetallic combinations of Cu with other metals have been investigated with the goal of steering selectivity via creating a tandem pathway through the CO intermediate or by changing the surface electronic structure. Here, we demonstrate a facile cation exchange method to synthesize Ag/Cu electrocatalysts for CO2 reduction using Cu sulfides as a growth template. Beginning with Cu2−xS nanosheets (C-nano-0, 100 nm lateral dimension, 14 nm thick), varying the Ag+ concentration in the exchange solution produces a gradual change in crystal structure from Cu7S4 to Ag2S, as the Ag/Cu mass ratio varies from 0.3 to 25 (CA-nano-x, x indicating increasing Ag fraction). After cation exchange, the nanosheet morphology remains but with increased shape distortion as the Ag fraction is increased. Interestingly, the control (C-nano-0) and cation exchanged nanosheets have very high faradaic efficiency for producing formate at low overpotential (−0.2 V vs. RHE). The primary effect of Ag incorporation is increased production of C2+ products at −1.0 V vs. RHE compared with C-nano-0, which primarily produces formate. Cation exchange can also be used to modify the surface of Cu foils. A two-step electro-oxidation/sulfurization process was used to form Cu sulfides on Cu foil (C-foil-x) to a depth of a few 10 s of microns. With lower Ag+ concentrations, cation exchange produces uniformly dispersed Ag; however, at higher concentrations, Ag particles nucleate on the surface. During CO2 electroreduction testing, the product distribution for Ag/Cu sulfides on Cu foil (CA-foil-x-y) changes in time with an initial increase in ethylene and methane production followed by a decrease as more H2 is produced. The catalysts undergo a morphology evolution towards a nest-like structure which could be responsible for the change in selectivity. For cation-exchanged nanosheets (CA-nano-x), pre-reduction at negative potentials increases the CO2 reduction selectivity compared to tests of as-synthesized material, although this led to the aggregation of nanosheets into filaments. Both types of bimetallic catalysts are capable of selective reduction of CO2 to multi-carbon products, although the optimal configurations appear to be metastable.

Published
2021
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29. Covalent Organic Frameworks with Irreversible Linkages via Reductive Cyclization of Imines

Author

Sizhuo Yang, Chongqing Yang, Chaochao Dun, Haiyan Mao, Rebecca Shu Hui Khoo, Liana M. Klivansky, Jeffrey A. Reimer, Jeffrey J. Urban, Jian Zhang, and Yi Liu

Subjects
Colloid and Surface Chemistry, Chemical Sciences, General Chemistry, Biochemistry, Catalysis
Abstract

Covalent organic frameworks (COFs) show great potential for many advanced applications on account of their structural uniqueness. To address the synthetic challenges, facile chemical routes to engineer the porosity, crystallinity, and functionality of COFs are highly sought after. Herein, we report a synthetic approach that employs the Cadogan reaction to introduce nitrogen-containing heterocycles as the linkages in the framework. Irreversible indazole and benzimidazolylidene (BIY) linkages are introduced into COFs for the first time via phosphine-induced reductive cyclization of the common imine linkages following either stepwise or one-pot reaction protocols. The successful linkage transformation introduces new functionalities, as demonstrated in the case of BIY-COF, which displays excellent intrinsic proton conductivity without the need of impregnation with external proton transfer reagents. Such a general strategy will open the window to a broader class of functional porous crystalline materials.

Published
2022

30. Enhancing Separation and Mechanical Performance of Hybrid Membranes through Nanoparticle Surface Modification

Author

Hilda G. Buss, Jeffrey J. Urban, Bryan D. McCloskey, and Norman C. Su

Subjects
chemistry.chemical_classification, Thermogravimetric analysis, Materials science, Polymers and Plastics, Organic Chemistry, Nanoparticle, Dynamic mechanical analysis, Polymer, Inorganic Chemistry, chemistry.chemical_compound, Membrane, chemistry, Materials Chemistry, Surface modification, Gas separation, Composite material, Ethylene glycol
Abstract

Membranes with selective gas transport properties and good mechanical integrity are increasingly desired to replace current energy intensive approaches to gas separation. Here, we report on the dual enhancement of transport and mechanical properties of hybrid cross-linked poly(ethylene glycol) membranes with aminopropyl-modified silica nanoparticles. CO2 permeability in hybrid membranes exceeds what can be predicted by Maxwell’s equation and surpasses values of the pure polymer. Furthermore, dynamic mechanical and thermogravimetric analyses reveal increases in both the storage modulus and thermal stability in hybrid membranes, with respect to silica nanoparticle loading.

Published
2022

31. Enhanced Water Vapor Blocking in Transparent Hybrid Polymer-Nanocrystal Films

Author

Megan L. Hoarfrost, Rachel A. Segalman, Miguel A. Modestino, Jeffrey J. Urban, Emily C. Davidson, Christopher M. Evans, and Eun Seon Cho

Subjects
chemistry.chemical_classification, Materials science, Polymers and Plastics, Magnesium, Organic Chemistry, Composite number, Photovoltaic system, chemistry.chemical_element, Polymer, Inorganic Chemistry, chemistry, Nanocrystal, Chemical engineering, Materials Chemistry, Copolymer, Organic chemistry, Molecule, Water vapor
Abstract

Highly transparent and effective encapsulating materials have become increasingly important for photovoltaic (PV) modules to prevent water vapor molecules from permeating PV cells. The composite consists of block copolymer (PS-b-P2VP), comprised of hydrophobic and hydrophilic parts, and hygroscopic nanocrystals (Magnesium Oxide, MgO) incorporated to enhance water vapor blocking by both presenting obstacles for mass transport and also scavenging water molecules. The water vapor transmission rate (WVTR) values were reduced ∼3000 times, compared to homopolymer (PS), for both polymer and composite samples. Achieving both high transparency and low WVTR, it is expected that the composite materials can function as an excellent water vapor blocking layer for PV modules.

Published
2022

32. Hydrogen Storage Performance of Preferentially Oriented Mg/rGO Hybrids

Author

Chaochao Dun, Sohee Jeong, Deok-Hwang Kwon, ShinYoung Kang, Vitalie Stavila, Zhuolei Zhang, Joo-Won Lee, Tracy M. Mattox, Tae Wook Heo, Brandon C. Wood, and Jeffrey J. Urban

Subjects
Engineering, Affordable and Clean Energy, General Chemical Engineering, Chemical Sciences, Materials Chemistry, General Chemistry, Materials
Abstract

Chemical interactions on the surface of a functional nanoparticle are closely related to its crystal facets, which can regulate the corresponding energy storage properties like hydrogen absorption. In this study, we reported a one-step growth of magnesium (Mg) particles with both close- and nonclose-packed facets, that is, {0001} and {21¯ 1¯ 6} planes, on atomically thin reduced graphene oxide (rGO). The detailed microstructures of Mg/rGO hybrids were revealed by X-ray diffraction, selected-area electron diffraction, high-resolution transmission electron microscopy, and fast Fourier transform analysis. Hydrogen storage performance of Mg/rGO hybrids with different orientations varies: Mg with preferential high-index {21¯ 1¯ 6} crystal surface shows remarkably increased hydrogen absorption up to 6.2 wt % compared with the system exposing no preferentially oriented crystal surfaces showing inferior performance of 5.1 wt % within the first 2 h. First-principles calculations revealed improved hydrogen sorption properties on the {21¯ 1¯ 6} surface with a lower hydrogen dissociation energy barrier and higher stability of hydrogen atoms than those on the {0001} basal plane, supporting the hydrogen uptake experiment. In addition, the hydrogen penetration energy barrier is found to be much lower than that of {0001} because of low surface atom packing density, which might be the most critical process to the hydrogenation kinetics. The experimental and calculation results present a new handle for regulating the hydrogen storage of metal hydrides by controlled Mg facets.

Published
2022

33. A self-learning circuit diagram for optimal water and energy management

Author

Jeffrey J. Urban and Ngoc T. Bui

Subjects
Water resources, Water delivery, General Energy, Affordable and Clean Energy, Computer science, Energy management, Bioengineering, Resource management, Environmental economics, Embodied energy, Energy (signal processing), Circuit diagram
Abstract

Computational methods with real-time forecasting of embedded energy and water networks are critical for resource management and conservation. In the August 1, 2021 issue of Energy & Environmental Science, Liu and Mauter propose a high-resolution computational framework of the embedded energy in water delivery systems to guide efficient management of water resources.

Published
2021
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34. Superselective Removal of Lead from Water by Two-Dimensional MoS2 Nanosheets and Layer-Stacked Membranes

Author

Yanghua Duan, Zhongying Wang, Qi Han, Sidney Poon, David L. Sedlak, Julie Yu, Qingsong Tu, Bei Liu, Baoxia Mi, Jeffrey J. Urban, and Alison Sim

Subjects
Aqueous solution, Chemistry, Analytical chemistry, chemistry.chemical_element, General Chemistry, 010501 environmental sciences, 01 natural sciences, Partition coefficient, Membrane, Adsorption, Molybdenum, Environmental Chemistry, Orders of magnitude (speed), Selectivity, 0105 earth and related environmental sciences, Bar (unit)
Abstract

Point-of-use (POU) devices with satisfactory lead (Pb2+) removal performance are urgently needed in response to recent outbreaks of lead contamination in drinking water. This study experimentally demonstrated the excellent lead removal capability of two-dimensional (2D) MoS2 nanosheets in aqueous form and as part of a layer-stacked membrane. Among all materials ever reported in the literature, MoS2 nanosheets exhibit the highest adsorption capacity (740 mg/g), and the strongest selectivity/affinity toward Pb2+ with a distribution coefficient Kd that is orders of magnitude higher than that of other lead adsorption materials (5.2 × 107 mL/g). Density functional theory (DFT) simulation was performed to complement experimental measurements and to help understand the adsorption mechanisms. The results confirmed that the cation selectivity of MoS2 follows the order Pb2+ > Cu2+ ≫ Cd2+ > Zn2+, Ni2+ > Mg2+, K+, Ca2+. The membrane formed with layer-stacked MoS2 nanosheets exhibited a high water flux (145 L/m2/h/bar), while effectively decreasing Pb2+ concentration in drinking water from a few mg/L to less than 10 μg/L. The removal capacity of the MoS2 membrane is a few orders of magnitude higher than that of other literature-reported membrane filters. Therefore, the layer-stacked MoS2 membrane has great potential for POU removal of lead from drinking water.

Published
2020
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35. Robust natural nanocomposites realizing unprecedented ultrafast precise molecular separations

Author

Lu Shao, Xu Jiang, Shaoqin Liu, Jeffrey J. Urban, Yanqiu Zhang, Xi Quan Cheng, and Cher Hon Lau

Subjects
Materials science, chemistry.chemical_element, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Membrane technology, Engineering, Affordable and Clean Energy, General Materials Science, Materials, Aqueous solution, Nanocomposite, Mechanical Engineering, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Interfacial polymerization, 0104 chemical sciences, Membrane, chemistry, Mechanics of Materials, Chemical Sciences, Metal-organic framework, Nanofiltration, 0210 nano-technology, Carbon, Responsible Consumption and Production
Abstract

Synthetic polymer membranes can potentially reduce the large energy and carbon footprints that are typically associated with traditional chemical separation technologies. Unfortunately, current production protocols negate the green benefits of membrane separation. To address this bottleneck, here we report the use of natural materials monosaccharide – glucose and polydopamine and Zr-based metal organic frameworks (MOFs) to fabricate ultrathin nanocomposite membranes via interfacial polymerization reaction. The synergistic effect of these three materials on angstrom-scale molecular transport both in organic solvent and aqueous environment was elucidated using a series of complementary techniques. We demonstrate such nature-inspired nanocomposite membranes enable structural stability even in polar aprotic solvents, and unparalleled ultra-fast, low-pressure, precise separations in both nanofiltration modes, which easily surpass state-of-the-art membranes relying on unsustainable materials. The multi-functionality of saccharide nanocomposites was elegantly harnessed to impact separation applications that contribute towards a better living environment.

Published
2020
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36. In Situ ATR–SEIRAS of Carbon Dioxide Reduction at a Plasmonic Silver Cathode

Author

Elizabeth R. Corson, Ruud Kortlever, Bryan D. McCloskey, Jeffrey J. Urban, Wilson A. Smith, Recep Kas, and Robert Kostecki

Subjects
Absorption spectroscopy, Chemistry, Infrared spectroscopy, General Chemistry, 010402 general chemistry, Photochemistry, 01 natural sciences, Biochemistry, Catalysis, Cathode, 0104 chemical sciences, law.invention, Colloid and Surface Chemistry, law, Chemical Sciences, Thin film, Surface plasmon resonance, Spectroscopy, Plasmon, Electrochemical reduction of carbon dioxide
Abstract

Illumination of a voltage-biased plasmonic Ag cathode during CO2 reduction results in a suppression of the H2 evolution reaction while enhancing CO2 reduction. This effect has been shown to be photonic rather than thermal, but the exact plasmonic mechanism is unknown. Here, we conduct an in situ ATR-SEIRAS (attenuated total reflectance-surface-enhanced infrared absorption spectroscopy) study of a sputtered thin film Ag cathode on a Ge ATR crystal in CO2-saturated 0.1 M KHCO3 over a range of potentials under both dark and illuminated (365 nm, 125 mW cm-2) conditions to elucidate the nature of this plasmonic enhancement. We find that the onset potential of CO2 reduction to adsorbed CO on the Ag surface is -0.25 VRHE and is identical in the light and the dark. As the production of gaseous CO is detected in the light near this onset potential but is not observed in the dark until -0.5 VRHE, we conclude that the light must be assisting the desorption of CO from the surface. Furthermore, the HCO3- wavenumber and peak area increase immediately upon illumination, precluding a thermal effect. We propose that the enhanced local electric field that results from the localized surface plasmon resonance (LSPR) is strengthening the HCO3- bond, further increasing the local pH. This would account for the decrease in H2 formation and increase the CO2 reduction products in the light.

Published
2020
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37. Using Additives to Control the Decomposition Temperature of Sodium Borohydride

Author

Jeffrey J. Urban, Camille Jubert Tomasso, Anne L. Pham, and Tracy M. Mattox

Subjects
Hydrogen storage, Sodium borohydride, chemistry.chemical_compound, Materials science, chemistry, Hydrogen, Chemical engineering, Hydride, Thermal decomposition, chemistry.chemical_element, Borohydride, Fluoride, Liquid hydrogen
Abstract

Hydrogen (H2) shows great promise as zero-carbon emission fuel, but there are several challenges to overcome in regards to storage and transportation to make it a more universal energy solution. Gaseous hydrogen requires high pressures and large volume tanks while storage of liquid hydrogen requires cryogenic temperatures; neither option is ideal due to cost and the hazards involved. Storage in the solid state presents an attractive alternative, and can meet the U.S. Department of Energy (DOE) constraints to find materials containing > 7 % H2 (gravimetric weight) with a maximum H2 release under 125 °C.While there are many candidate hydrogen storage materials, the vast majority are metal hydrides. Of the hydrides, this review focuses solely on sodium borohydride (NaBH4), which is often not covered in other hydride reviews. However, as it contains 10.6% (by weight) H2 that can release at 133 ± 3 JK−1mol−1, this inexpensive material has received renewed attention. NaBH4 should decompose to H2(g), Na(s), and B(s), and could be recycled into its original form. Unfortunately, metal to ligand charge transfer in NaBH4 induces high thermodynamic stability, creating a high decomposition temperature of 530 °C. In an effort make H2 more accessible at lower temperatures, researchers have incorporated additives to destabilize the structure. This review highlights metal additives that have successfully reduced the decomposition temperature of NaBH4, with temperatures ranging from 522 °C (titanium (IV) fluoride) to 379 °C (niobium (V) fluoride). We describe synthetic methods employed, chemical pathways taken, and the challenges of boron derivative formation on H2 cycling. Though no trends can be found across all additives, it is our hope that compiling the data here will enable researchers to gain a better understanding of the additives’ influence and to determine how a new system might be designed to make NaBH4 a more viable H2 fuel source.

Published
2020
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38. Correlating Interlayer Spacing and Separation Capability of Graphene Oxide Membranes in Organic Solvents

Author

Jeffrey J. Urban, Sunxiang Zheng, Baoxia Mi, Monong Wang, and Qingsong Tu

Subjects
Materials science, Oxide, General Physics and Astronomy, 02 engineering and technology, organic solvent nanofiltration, 010402 general chemistry, 01 natural sciences, law.invention, solubility distance, swelling, chemistry.chemical_compound, law, medicine, General Materials Science, Nanoscience & Nanotechnology, Solubility, membrane, Graphene, General Engineering, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Hexane, Solvent, Hildebrand solubility parameter, interlayer spacing, Membrane, chemistry, Chemical engineering, graphene oxide, Swelling, medicine.symptom, 0210 nano-technology
Abstract

Membranes synthesized by stacking two-dimensional graphene oxide (GO) hold great promise for applications in organic solvent nanofiltration. However, the performance of a layer-stacked GO membrane in organic solvent nanofiltration can be significantly affected by its swelling and interlayer spacing, which have not been systematically characterized. In this study, the interlayer spacing of the layer-stacked GO membrane in different organic solvents was experimentally characterized by liquid-phase ellipsometry. To understand the swelling mechanism, the solubility parameters of GO were experimentally determined and used to mathematically predict the Hansen solubility distance between GO and solvents, which is found to be a good predictor for GO swelling and interlayer spacing. Solvents with a small solubility distance (e.g., dimethylformamide, N-methyl-2-pyrrolidone) tend to cause significant GO swelling, resulting in an interlayer spacing of up to 2.7 nm. Solvents with a solubility distance larger than 9.5 (e.g., ethanol, acetone, hexane, and toluene) only cause minor swelling and are thus able to maintain an interlayer spacing of around 1 nm. Correspondingly, GO membranes in solvents with a large solubility distance exhibit good separation performance, for example, rejection of more than 90% of the small organic dye molecules (e.g., rhodamine B and methylene blue) in ethanol and acetone. Additionally, solvents with a large solubility distance result in a high slip velocity in GO channels and thus high solvent flux through the GO membrane. In summary, the GO membrane performs better in solvents that are unlike GO, i.e., solvents with large solubility distance.

Published
2020
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39. Adapting the Electron Beam from SEM as a Quantitative Heating Source for Nanoscale Thermal Metrology

Author

D. Frank Ogletree, Jason Wu, Yanbao Ma, Chris Dames, Jeffrey J. Urban, and Pengyu Yuan

Subjects
Materials science, business.industry, Scanning electron microscope, Mechanical Engineering, Bioengineering, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Metrology, chemistry.chemical_compound, Thermal conductivity, Silicon nitride, chemistry, Thermal, Electron beam processing, Optoelectronics, General Materials Science, 0210 nano-technology, business, Joule heating, Absorption (electromagnetic radiation)
Abstract

The electron beam (e-beam) in the scanning electron microscopy (SEM) provides an appealing mobile heating source for thermal metrology with spatial resolution of ∼1 nm, but the lack of systematic quantification of the e-beam heating power limits such application development. Here, we systemically study e-beam heating in LPCVD silicon nitride (SiNx) thin-films with thickness ranging from 200 to 500 nm from both experiments and complementary Monte Carlo simulations using the CASINO software package. There is good agreement about the thickness-dependent e-beam energy absorption of thin-film between modeling predictions and experiments. Using the absorption results, we then demonstrate adapting the e-beam as a quantitative heating source by measuring the thickness-dependent thermal conductivity of SiNx thin-films, with the results validated to within 7% by a separate Joule heating experiment. The results described here will open a new avenue for using SEM e-beams as a mobile heating source for advanced nanoscale thermal metrology development.

Published
2020
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40. Dynamic Covalent Synthesis of Crystalline Porous Graphitic Frameworks

Author

Jim Ciston, Yawei Liu, Hao Chen, Bing Sun, Qiubo Zhang, Qi Zheng, Haimei Zheng, Madeleine P. Gordon, Haiyan Mao, Xinle Li, Jian Zhang, Yi Liu, Jeffrey J. Urban, Chaochao Dun, Hongxia Wang, Song-Liang Cai, Emory M. Chan, Tianwei Tan, and Jeffrey A. Reimer

Subjects
Aqueous solution, Materials science, Pyrazine, General Chemical Engineering, Biochemistry (medical), Heteroatom, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Ring (chemistry), 01 natural sciences, Biochemistry, 0104 chemical sciences, Amorphous solid, chemistry.chemical_compound, chemistry, Chemical engineering, Covalent bond, Transmission electron microscopy, Materials Chemistry, Environmental Chemistry, 0210 nano-technology, Porosity
Abstract

Summary Porous graphitic framework (PGF) is a two-dimensional (2D) material that has emerging energy applications. An archetype contains stacked 2D layers, the structure of which features a fully annulated aromatic skeleton with embedded heteroatoms and periodic pores. Due to the lack of a rational approach in establishing in-plane order under mild synthetic conditions, the structural integrity of PGF has remained elusive and ultimately limited its material performance. Here, we report the discovery of the unusual dynamic character of the C=N bonds in the aromatic pyrazine ring system under basic aqueous conditions, which enables the successful synthesis of a crystalline porous nitrogenous graphitic framework with remarkable in-plane order, as evidenced by powder X-ray diffraction studies and direct visualization using high-resolution transmission electron microscopy. The crystalline framework displays superior performance as a cathode material for lithium-ion batteries, outperforming the amorphous counterparts in terms of capacity and cycle stability.

Published
2020
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41. Graphene-polyelectrolyte multilayer membranes with tunable structure and internal charge

Author

Andrew J. Ng, Monong Wang, Yangyang Wei, Yang Liu, Sunxiang Zheng, Ping Gu, Jeffrey J. Urban, and Baoxia Mi

Subjects
Materials science, Graphene, Membrane structure, 02 engineering and technology, General Chemistry, Quartz crystal microbalance, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrostatics, 01 natural sciences, Polyelectrolyte, 0104 chemical sciences, law.invention, Membrane, Chemical engineering, law, Ionic strength, General Materials Science, 0210 nano-technology, Selectivity
Abstract

One great advantage of graphene-polyelectrolyte multilayer (GPM) membranes is their tunable structure and internal charge for improved separation performance. In this study, we synthesized GO-dominant GPM membrane with internal negatively-charged domains, polyethyleneimine (PEI)-dominant GPM membrane with internal positively-charged domains and charge-balanced dense/loose GPM membranes by simply adjusting the ionic strength and pH of the GO and PEI solutions used in layer-by-layer membrane synthesis. A combined system of quartz crystal microbalance with dissipation (QCM-D) and ellipsometry was used to analyze the mass deposition, film thickness, and layer density of the GPM membranes. The performance of the GPM membranes were compared in terms of both permeability and selectivity to determine the optimal membrane structure and synthesis strategy. One effective strategy to improve the GPM membrane permeability-selectivity tradeoff is to assemble charge-balanced dense membranes under weak electrostatic interactions. This balanced membrane exhibits the highest MgCl2 selectivity (∼86%). Another effective strategy for improved cation removal is to create PEI-dominant membranes that provide internal positively-charged barrier to enhance cation selectivity without sacrificing water permeability. These findings shine lights on the development of a systematic approach to push the boundary of permeability-selectivity tradeoff for GPM membranes.

Published
2020
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42. Pyrazine-Fused Porous Graphitic Framework-Based Mixed Matrix Membranes for Enhanced Gas Separations

Author

Canghai Ma, Xinle Li, Jian Zhang, Yi Liu, and Jeffrey J. Urban

Subjects
Mixed matrix, separation, Materials science, Pyrazine, Design elements and principles, mixed-matrix membranes, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Crystallinity, chemistry.chemical_compound, Engineering, Affordable and Clean Energy, hydrogen regeneration, porous graphitic frameworks, General Materials Science, Nanoscience & Nanotechnology, Porosity, 021001 nanoscience & nanotechnology, CO2 capture, 0104 chemical sciences, Membrane, Chemical engineering, chemistry, Chemical Sciences, Polymeric membrane, 0210 nano-technology
Abstract

Membrane-based separations can mitigate the capital- and energy-intensive challenges associated with traditional thermally driven processes. To further push the boundary of gas separations, mixed matrix membranes (MMMs) have been extensively exploited; however, identifying an optimal nanofiller to boost the separation performance of MMMs beyond Robeson permeability-selectivity upper bounds remains an ongoing challenge. Here, a new class of MMMs based on pyrazine-fused crystalline porous graphitic frameworks (PGFs) is reported. At a loading of 6 wt % PGFs, the MMMs surpass the current H2/CH4 Robeson upper bound, ideally suited for applications such as H2 regeneration. In addition, the fabricated MMMs exhibit appealing CO2 separation performance, closely approaching the current Robeson upper bounds for CO2 separation. Compared with the pristine polymeric membranes, the PGF-based MMMs display a record-high enhancement of gas permeability over 120% while maintaining intrinsic gas selectivities. Highlighting the crucial role of the crystallinity of nanofillers, this study demonstrates a facile and effective approach in formulating high-performance MMMs, complementing state-of-the-art membrane formation processes. The design principles open the door to energy-efficient separations of gas mixtures with enhanced productivity compatible with the current membrane manufacturing.

Published
2020
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43. A Mechanistic Analysis of Phase Evolution and Hydrogen Storage Behavior in Nanocrystalline Mg(BH4)2 within Reduced Graphene Oxide

Author

Brandon C. Wood, Rongpei Shi, Jeffrey R. Long, Sohee Jeong, Liwen F. Wan, Andreas Schneemann, James L. White, Vitalie Stavila, Julia Oktawiec, Jinghua Guo, Edmond W. Zaia, Tae Wook Heo, ShinYoung Kang, Yi-Sheng Liu, Jeffrey J. Urban, and Keith G. Ray

Subjects
Materials science, Graphene, General Engineering, Nucleation, Oxide, General Physics and Astronomy, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Borohydride, 01 natural sciences, Nanocrystalline material, 0104 chemical sciences, law.invention, Nanomaterials, chemistry.chemical_compound, Hydrogen storage, chemistry, Chemical engineering, law, Gravimetric analysis, General Materials Science, 0210 nano-technology
Abstract

Magnesium borohydride (Mg(BH4)2, abbreviated here MBH) has received tremendous attention as a promising onboard hydrogen storage medium due to its excellent gravimetric and volumetric hydrogen storage capacities. While the polymorphs of MBH-alpha (α), beta (β), and gamma (γ)-have distinct properties, their synthetic homogeneity can be difficult to control, mainly due to their structural complexity and similar thermodynamic properties. Here, we describe an effective approach for obtaining pure polymorphic phases of MBH nanomaterials within a reduced graphene oxide support (abbreviated MBHg) under mild conditions (60-190 °C under mild vacuum, 2 Torr), starting from two distinct samples initially dried under Ar and vacuum. Specifically, we selectively synthesize the thermodynamically stable α phase and metastable β phase from the γ-phase within the temperature range of 150-180 °C. The relevant underlying phase evolution mechanism is elucidated by theoretical thermodynamics and kinetic nucleation modeling. The resulting MBHg composites exhibit structural stability, resistance to oxidation, and partially reversible formation of diverse [BH4]- species during de- and rehydrogenation processes, rendering them intriguing candidates for further optimization toward hydrogen storage applications.

Published
2020
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44. Reduction of carbon dioxide at a plasmonically active copper–silver cathode

Author

Jeffrey J. Urban, Jason K. Cooper, Ananya Subramani, Bryan D. McCloskey, Robert Kostecki, and Elizabeth R. Corson

Subjects
Materials science, Metals and Alloys, chemistry.chemical_element, General Chemistry, Photochemistry, Copper, Catalysis, Cathode, Methane, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, law.invention, chemistry.chemical_compound, chemistry, law, Materials Chemistry, Ceramics and Composites, Formate, Surface plasmon resonance, Selectivity, Carbon, Carbon monoxide
Abstract

Electrochemically deposited copper nanostructures were coated with silver to create a plasmonically active cathode for carbon dioxide (CO2) reduction. Illumination with 365 nm light, close to the peak plasmon resonance of silver, selectively enhanced 5 of the 14 typically observed copper CO2 reduction products while simultaneously suppressing hydrogen evolution. At low overpotentials, carbon monoxide was promoted in the light and at high overpotentials ethylene, methane, formate, and allyl alcohol were enhanced upon illumination; generally C1 products and C2/C3 products containing a double carbon bond were selectively promoted under illumination. Temperature-dependent product analysis in the dark showed that local heating is not the cause of these selectivity changes. While the exact plasmonic mechanism is still unknown, these results demonstrate the potential for enhancing CO2 reduction selectivity at copper electrodes using plasmonics.

Published
2020
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45. Sugar-alcohol@ZIF nanocomposites display suppressed phase-change temperatures

Author

Christopher L. Anderson, Madeleine P. Gordon, Canghai Ma, Jinghua Guo, Chih-Hao Hsu, Lukas Hackl, Peter Ercius, Yi-Sheng Liu, Matthew A. Kolaczkowski, Jeffrey J. Urban, and Kelly Chou

Subjects
Nanocomposite, Materials science, Renewable Energy, Sustainability and the Environment, Composite number, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Thermal energy storage, 01 natural sciences, 0104 chemical sciences, Chemical engineering, Latent heat, Thermal, Surface modification, General Materials Science, 0210 nano-technology, Zeolitic imidazolate framework, Flammability
Abstract

For the sake of water and energy conservation, development of latent heat cooling and thermal storage systems that minimize water consumption and operate with higher efficacy than their water-driven counterparts is a crucial task. Phase change materials (PCMs) present a potential solution, but their integration into real-world systems abounds with scientific challenges such as material toxicity, flammability, low thermal performance and lack of tunable phase-change temperatures. In this study we report on a first-in-class nanocomposite PCM that leverages non-flammable, non-toxic, high latent heat sugar alcohols (SAs) encapsulated within easy-to-synthesize zeolitic imidazolate framework (ZIF) crystals. We also outline a practical route for surface functionalization with hydrophilic and hydrophobic moieties. The SA@ZIF composites display suppressed phase-change temperatures which, together with alterable surface functionality, broadens their applicability to a plethora of working environments. Direct synthesis of the SA@ZIF composite generates nanoconfined SAs with phase-change temperatures as low as 19.8 °C and latent heats as high as 285 J g−1. This nanoconfinement-induced thermal phenomenon is conserved even after functionalization of the SA@ZIF crystal surface. We believe this study will lay the groundwork as a platform for next generation high performing, tunable PCMs to aid in the realization of waterless cooling systems.

Published
2020
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46. Mismatching integration-enabled strains and defects engineering in LDH microstructure for high-rate and long-life charge storage

Author

Wei Guo, Chaochao Dun, Chang Yu, Xuedan Song, Feipeng Yang, Wenzheng Kuang, Yuanyang Xie, Shaofeng Li, Zhao Wang, Jinhe Yu, Guosheng Fu, Jinghua Guo, Matthew A. Marcus, Jeffrey J. Urban, Qiuyu Zhang, and Jieshan Qiu

Subjects
Multidisciplinary, Affordable and Clean Energy, General Physics and Astronomy, General Chemistry, General Biochemistry, Genetics and Molecular Biology
Abstract

Layered double hydroxides (LDH) have been extensively investigated for charge storage, however, their development is hampered by the sluggish reaction dynamics. Herein, triggered by mismatching integration of Mn sites, we configured wrinkled Mn/NiCo-LDH with strains and defects, where promoted mass & charge transport behaviors were realized. The well-tailored Mn/NiCo-LDH displays a capacity up to 518 C g−1 (1 A g−1), a remarkable rate performance (78%@100 A g−1) and a long cycle life (without capacity decay after 10,000 cycles). We clarified that the moderate electron transfer between the released Mn species and Co2+ serves as the pre-step, while the compressive strain induces structural deformation with promoted reaction dynamics. Theoretical and operando investigations further demonstrate that the Mn sites boost ion adsorption/transport and electron transfer, and the Mn-induced effect remains active after multiple charge/discharge processes. This contribution provides some insights for controllable structure design and modulation toward high-efficient energy storage.

Published
2022
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47. Self-Adaptive Radiative Cooler for Maximizing Year-Round Energy Saving of households

Author

Jiachen Li, Kechao Tang, Kaichen Dong, Madeleine P. Gordon, Finnegan G. Reichertz, Hyungjin Kim, Yoonsoo Rho, Qingjun Wang, Chang-Yu Lin, Costas P. Grigoropoulos, Ali Javey, Jeffrey J. Urban, Jie Yao, Ronnen Levinson, and Junqiao Wu

Abstract

We present an approach to household thermal regulation and energy saving from an all-season perspective by developing a mechanically flexible and energy-free coating that automatically adapts its thermal emittance to different ambient temperatures.

Published
2022
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49. Synthesis of new two‐dimensional titanium carbonitride Ti2C0.5N0.5Tx MXene and its performance as an electrode material for sodium‐ion battery

Author

Kun Liang, Anika Tabassum, Ahmad Majed, Chaochao Dun, Feipeng Yang, Jinghua Guo, Kaitlyn Prenger, Jeffrey J. Urban, and Michael Naguib

Subjects
sodium‐ion battery, titanium carbonitride, Affordable and Clean Energy, sodium-ion battery, two-dimensional, two‐dimensional, TA401-492, Information technology, T58.5-58.64, MXene, Materials of engineering and construction. Mechanics of materials
Abstract

Two‐dimensional (2D) layered transition metal carbides/nitrides, called MXenes, are attractive alternative electrode materials for electrochemical energy storage. Owing to their metallic electrical conductivity and low ion diffusion barrier, MXenes are promising anode materials for sodium‐ion batteries (SIBs). Herein, we report on a new 2D carbonitride MXene, viz., Ti2C0.5N0.5Tx (Tx stands for surface terminations), and the only second carbonitride after Ti3CNTx so far. A new type of in situ HF (HCl/KF) etching condition was employed to synthesize multilayer Ti2C0.5N0.5Tx powders from Ti2AlC0.5N0.5. Spontaneous intercalation of tetramethylammonium followed by sonication in water allowed for large‐scale delamination of this new titanium carbonitride into 2D sheets. Multilayer Ti2C0.5N0.5Tx powders showed higher specific capacities and larger electroactive surface area than those of Ti2CTx powders. Multilayer Ti2C0.5N0.5Tx powders show a specific capacity of 182 mAh g−1 at 20 mA g−1, the highest among all reported MXene electrodes as SIBs with excellent cycling stability.

Published
2021

50. Back Cover Image

Author

Kun Liang, Anika Tabassum, Ahmad Majed, Chaochao Dun, Feipeng Yang, Jinghua Guo, Kaitlyn Prenger, Jeffrey J. Urban, and Michael Naguib

Published
2021
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