Showing total 22 results

1. Quantitative 3D structural analysis of small colloidal assemblies under native conditions by liquid-cell fast electron tomography.

Author

Arenas Esteban D, Wang D, Kadu A, Olluyn N, Sánchez-Iglesias A, Gomez-Perez A, González-Casablanca J, Nicolopoulos S, Liz-Marzán LM, and Bals S

Abstract

Electron tomography has become a commonly used tool to investigate the three-dimensional (3D) structure of nanomaterials, including colloidal nanoparticle assemblies. However, electron microscopy is typically done under high-vacuum conditions, requiring sample preparation for assemblies obtained by wet colloid chemistry methods. This involves solvent evaporation and deposition on a solid support, which consistently alters the nanoparticle organization. Here, we suggest using electron tomography to study nanoparticle assemblies in their original colloidal liquid environment. To address the challenges related to electron tomography in liquid, we devise a method that combines fast data acquisition in a commercial liquid-cell with a dedicated alignment and reconstruction workflow. We present the advantages of this methodology in accurately characterizing two different systems. 3D reconstructions of assemblies comprising polystyrene-capped Au nanoparticles encapsulated in polymeric shells reveal less compact and more distorted configurations for experiments performed in a liquid medium compared to their dried counterparts. A similar expansion can be observed in quantitative analysis of the surface-to-surface distances of self-assembled Au nanorods in water rather than in a vacuum, in agreement with bulk measurements. This study, therefore, emphasizes the importance of developing high-resolution characterization tools that preserve the native environment of colloidal nanostructures., (© 2024. The Author(s).)

Published

2024

2. Ag-thiolate interactions to enable an ultrasensitive and stretchable MXene strain sensor with high temporospatial resolution.

Author

Liu Y, Xu Z, Ji X, Xu X, Chen F, Pan X, Fu Z, Chen Y, Zhang Z, Liu H, Cheng B, and Liang J

Abstract

High-sensitivity strain sensing elements with a wide strain range, fast response, high stability, and small sensing areas are desirable for constructing strain sensor arrays with high temporospatial resolution. However, current strain sensors rely on crack-based conductive materials having an inherent tradeoff between their sensing area and performance. Here, we present a molecular-level crack modulation strategy in which we use layer-by-layer assembly to introduce strong, dynamic, and reversible coordination bonds in an MXene and silver nanowire-matrixed conductive film. We use this approach to fabricate a crack-based stretchable strain sensor with a very small sensing area (0.25 mm 2 ). It also exhibits an ultrawide working strain range (0.001-37%), high sensitivity (gauge factor ~500 at 0.001% and >150,000 at 35%), fast response time, low hysteresis, and excellent long-term stability. Based on this high-performance sensing element and facile assembly process, a stretchable strain sensor array with a device density of 100 sensors per cm 2 is realized. We demonstrate the practical use of the high-density strain sensor array as a multichannel pulse sensing system for monitoring pulses in terms of their spatiotemporal resolution., (© 2024. The Author(s).)

Published

2024

3. Artificial cellulosic leaf with adjustable enzymatic CO 2 sequestration capability.

Author

Zhu X, Du C, Gao B, and He B

Subjects

Ecosystem, Plant Stomata metabolism, Photosynthesis, Light, Carbon Dioxide metabolism, Carbon Dioxide chemistry, Plant Leaves metabolism, Cellulose metabolism, Cellulose chemistry, Carbon Sequestration

Abstract

Developing artificial leaves to address the environmental burden of CO 2 is pivotal for advancing our Net Zero Future. In this study, we introduce EcoLeaf, an artificial leaf that closely mimics the characteristics of natural leaves. It harnesses visible light as its sole energy source and orchestrates the controlled expansion and contraction of stomata and the exchange of petiole materials to govern the rate of CO 2 sequestration from the atmosphere. Furthermore, EcoLeaf has a cellulose composition and mechanical strength similar to those of natural leaves, allowing it to seamlessly integrate into the ecosystem during use and participate in natural degradation and nutrient cycling processes at the end of its life. We propose that the carbon sequestration pathway within EcoLeaf is adaptable and can serve as a versatile biomimetic platform for diverse biogenic carbon sequestration pathways in the future., (© 2024. The Author(s).)

Published

2024

4. Exciton polariton condensation from bound states in the continuum at room temperature.

Author

Wu X, Zhang S, Song J, Deng X, Du W, Zeng X, Zhang Y, Zhang Z, Chen Y, Wang Y, Jiang C, Zhong Y, Wu B, Zhu Z, Liang Y, Zhang Q, Xiong Q, and Liu X

Abstract

Exciton-polaritons (polaritons) resulting from the strong exciton-photon interaction stimulates the development of novel low-threshold coherent light sources to circumvent the ever-increasing energy demands of optical communications 1-3 . Polaritons from bound states in the continuum (BICs) are promising for Bose-Einstein condensation owing to their theoretically infinite quality factors, which provide prolonged lifetimes and benefit the polariton accumulations 4-7 . However, BIC polariton condensation remains limited to cryogenic temperatures ascribed to the small exciton binding energies of conventional material platforms. Herein, we demonstrated room-temperature BIC polariton condensation in perovskite photonic crystal lattices. BIC polariton condensation was demonstrated at the vicinity of the saddle point of polariton dispersion that generates directional vortex beam emission with long-range coherence. We also explore the peculiar switching effect among the miniaturized BIC polariton modes through effective polariton-polariton scattering. Our work paves the way for the practical implementation of BIC polariton condensates for integrated photonic and topological circuits., (© 2024. The Author(s).)

Published

2024

5. Aqueous amine enables sustainable monosaccharide, monophenol, and pyridine base coproduction in lignocellulosic biorefineries.

Author

Xu L, Cao M, Zhou J, Pang Y, Li Z, Yang D, Leu SY, Lou H, Pan X, and Qiu X

Abstract

Thought-out utilization of entire lignocellulose is of great importance to achieving sustainable and cost-effective biorefineries. However, there is a trade-off between efficient carbohydrate utilization and lignin-to-chemical conversion yield. Here, we fractionate corn stover into a carbohydrate fraction with high enzymatic digestibility and reactive lignin with satisfactory catalytic depolymerization activity using a mild high-solid process with aqueous diethylamine (DEA). During the fractionation, in situ amination of lignin achieves extensive delignification, effective lignin stabilization, and dramatically reduced nonproductive adsorption of cellulase on the substrate. Furthermore, by designing a tandem fractionation-hydrogenolysis strategy, the dissolved lignin is depolymerized and aminated simultaneously to co-produce monophenolics and pyridine bases. The process represents the viable scheme of transforming real lignin into pyridine bases in high yield, resulting from the reactions between cleaved lignin side chains and amines. This work opens a promising approach to the efficient valorization of lignocellulose., (© 2024. The Author(s).)

Published

2024

6. A general large-scale synthesis approach for crystalline porous materials.

Author

Liu X, Wang A, Wang C, Li J, Zhang Z, Al-Enizi AM, Nafady A, Shui F, You Z, Li B, Wen Y, and Ma S

Abstract

Crystalline porous materials such as covalent organic frameworks (COFs), metal-organic frameworks (MOFs) and porous organic cages (POCs) have been widely applied in various fields with outstanding performances. However, the lack of general and effective methodology for large-scale production limits their further industrial applications. In this work, we developed a general approach comprising high pressure homogenization (HPH), which can realize large-scale synthesis of crystalline porous materials including COFs, MOFs, and POCs under benign conditions. This universal strategy, as illustrated in the proof of principle studies, has prepared 4 COFs, 4 MOFs, and 2 POCs. It can circumvent some drawbacks of existing approaches including low yield, high energy consumption, low efficiency, weak mass/thermal transfer, tedious procedures, poor reproducibility, and high cost. On the basis of this approach, an industrial homogenizer can produce 0.96 ~ 580.48 ton of high-performance COFs, MOFs, and POCs per day, which is unachievable via other methods., (© 2023. The Author(s).)

Published

2023

7. Author Correction: Non-solvent post-modifications with volatile reagents for remarkably porous ketone functionalized polymers of intrinsic microporosity.

Author

Wongwilawan S, Nguyen TS, Nguyen TPN, Alhaji A, Lim W, Hong Y, Park JS, Atilhan M, Kim BJ, Eddaoudi M, and Yavuz CT

Published

2023

8. Non-solvent post-modifications with volatile reagents for remarkably porous ketone functionalized polymers of intrinsic microporosity.

Author

Wongwilawan S, Nguyen TS, Nguyen TPN, Alhaji A, Lim W, Hong Y, Park JS, Atilhan M, Kim BJ, Eddaoudi M, and Yavuz CT

Abstract

Chemical modifications of porous materials almost always result in loss of structural integrity, porosity, solubility, or stability. Previous attempts, so far, have not allowed any promising trend to unravel, perhaps because of the complexity of porous network frameworks. But the soluble porous polymers, the polymers of intrinsic microporosity, provide an excellent platform to develop a universal strategy for effective modification of functional groups for current demands in advanced applications. Here, we report complete transformation of PIM-1 nitriles into four previously inaccessible functional groups - ketones, alcohols, imines, and hydrazones - in a single step using volatile reagents and through a counter-intuitive non-solvent approach that enables surface area preservation. The modifications are simple, scalable, reproducible, and give record surface areas for modified PIM-1s despite at times having to pass up to two consecutive post-synthetic transformations. This unconventional dual-mode strategy offers valuable directions for chemical modification of porous materials., (© 2023. The Author(s).)

Published

2023

9. Atomic design of dual-metal hetero-single-atoms for high-efficiency synthesis of natural flavones.

Author

Zhao X, Fang R, Wang F, Kong X, and Li Y

Abstract

Single-atom (SA) catalysts provide extensive possibilities in pursuing fantastic catalytic performances, while their preparation still suffers from metal aggregation and pore collapsing during pyrolysis. Here we report a versatile medium-induced infiltration deposition strategy for the fabrication of SAs and hetero-SAs (M a N 4 /M b N 4 @NC; M a  = Cu, Co, Ni, Mn, M b  = Co, Cu, Fe, NC = N-doped carbon). In-situ and control experiments reveal that the catalyst fabrication relies on the "step-by-step" evolution of M a -containing metal-organic framework (MOF) template and M b -based metal precursor, during which molten salt acts as both pore generator in the MOF transformation, and carrier for the oriented infiltration and deposition of the latter to eventually yield metal SAs embedded on hierarchically porous support. The as-prepared hetero-SAs show excellent catalytic performances in the general synthesis of 33 kinds of natural flavones. The highly efficient synthesis is further strengthened by the reliable durability of the catalyst loaded in a flow reactor. Systematic characterizations and mechanism studies suggest that the superior catalytic performances of CuN 4 /CoN 4 @NC are attributed to the facilitated O 2 activating-splitting process and significantly reduced reaction energy barriers over CoN 4 due to the synergetic interactions of the adjacent CuN 4 ., (© 2022. The Author(s).)

Published

2022

10. Constructing molecular bridge for high-efficiency and stable perovskite solar cells based on P3HT.

Author

Xu D, Gong Z, Jiang Y, Feng Y, Wang Z, Gao X, Lu X, Zhou G, Liu JM, and Gao J

Abstract

Poly (3-hexylthiophene) (P3HT) is one of the most attractive hole transport materials (HTMs) for the pursuit of stable, low-cost, and high-efficiency perovskite solar cells (PSCs). However, the poor contact and the severe recombination at P3HT/perovskite interface lead to a low power conversion efficiency (PCE). Thus, we construct a molecular bridge, 2-((7-(4-(bis(4-methoxyphenyl)amino)phenyl)-10-(2-(2-ethoxyethoxy)ethyl)-10H-phenoxazin-3-yl)methylene)malononitrile (MDN), whose malononitrile group can anchor the perovskite surface while the triphenylamine group can form π-π stacking with P3HT, to form a charge transport channel. In addition, MDN is also found effectively passivate the defects and reduce the recombination to a large extent. Finally, a PCE of 22.87% has been achieved with MDN-doped P3HT (M-P3HT) as HTM, much higher than the efficiency of PSCs with pristine P3HT. Furthermore, MDN gives the un-encapsulated device enhanced long-term stability that 92% of its initial efficiency maintain even after two months of aging at 75% relative humidity (RH) follow by one month of aging at 85% RH in the atmosphere, and the PCE does not change after operating at the maximum power point (MPP) under 1 sun illumination (~45 o C in N 2 ) over 500 hours., (© 2022. The Author(s).)

Published

2022

11. A biomimetic laminated strategy enabled strain-interference free and durable flexible thermistor electronics.

Author

Hao S, Fu Q, Meng L, Xu F, and Yang J

Subjects

Biomimetics, Elastomers, Electronics, Temperature, Nacre chemistry

Abstract

The development of flexible thermistor epidermal electronics (FTEE) to satisfy high temperature resolution without strain induced signal distortion is of great significance but still challenging. Inspired by the nacre microstructure capable of restraining the stress concentration, we exemplify a versatile MXene-based thermistor elastomer sensor (TES) platform that significantly alleviates the strain interference by the biomimetic laminated strategy combining with the in-plane stress dissipation and nacre-mimetic hierarchical architecture, delivering competitive advantages of superior thermosensitivity (-1.32% °C -1 ), outstanding temperature resolution (~0.3 °C), and unparalleled mechanical durability (20000 folding fatigue cycles), together with considerable improvement in strain-tolerant thermosensation over commercial thermocouple in exercise scenario. By a combination of theoretical model simulation, microstructure observation, and superposed signal detection, the authors further reveal the underlying temperature and strain signal decoupling mechanism that substantiate the generality and customizability of the nacre-mimetic strategy, possessing insightful significance of fabricating FTEE for static and dynamic temperature detection., (© 2022. The Author(s).)

Published

2022

12. Author Correction: Traps and transport resistance are the next frontiers for stable non-fullerene acceptor solar cells.

Author

Wöpke C, Göhler C, Saladina M, Du X, Nian L, Greve C, Zhu C, Yallum KM, Hofstetter YJ, Becker-Koch D, Li N, Heumüller T, Milekhin I, Zahn DRT, Brabec CJ, Banerji N, Vaynzof Y, Herzig EM, MacKenzie RCI, and Deibel C

Published

2022

13. Traps and transport resistance are the next frontiers for stable non-fullerene acceptor solar cells.

Author

Wöpke C, Göhler C, Saladina M, Du X, Nian L, Greve C, Zhu C, Yallum KM, Hofstetter YJ, Becker-Koch D, Li N, Heumüller T, Milekhin I, Zahn DRT, Brabec CJ, Banerji N, Vaynzof Y, Herzig EM, MacKenzie RCI, and Deibel C

Abstract

Stability is one of the most important challenges facing material research for organic solar cells (OSC) on their path to further commercialization. In the high-performance material system PM6:Y6 studied here, we investigate degradation mechanisms of inverted photovoltaic devices. We have identified two distinct degradation pathways: one requires the presence of both illumination and oxygen and features a short-circuit current reduction, the other one is induced thermally and marked by severe losses of open-circuit voltage and fill factor. We focus our investigation on the thermally accelerated degradation. Our findings show that bulk material properties and interfaces remain remarkably stable, however, aging-induced defect state formation in the active layer remains the primary cause of thermal degradation. The increased trap density leads to higher non-radiative recombination, which limits the open-circuit voltage and lowers the charge carrier mobility in the photoactive layer. Furthermore, we find the trap-induced transport resistance to be the major reason for the drop in fill factor. Our results suggest that device lifetimes could be significantly increased by marginally suppressing trap formation, leading to a bright future for OSC., (© 2022. The Author(s).)

Published

2022

14. Promoting biomass electrooxidation via modulating proton and oxygen anion deintercalation in hydroxide.

Author

He Z, Hwang J, Gong Z, Zhou M, Zhang N, Kang X, Han JW, and Chen Y

Subjects

Biomass, Glycerol, Hydroxides chemistry, Oxygen chemistry, Protons

Abstract

The redox center of transition metal oxides and hydroxides is generally considered to be the metal site. Interestingly, proton and oxygen in the lattice recently are found to be actively involved in the catalytic reactions, and critically determine the reactivity. Herein, taking glycerol electrooxidation reaction as the model reaction, we reveal systematically the impact of proton and oxygen anion (de)intercalation processes on the elementary steps. Combining density functional theory calculations and advanced spectroscopy techniques, we find that doping Co into Ni-hydroxide promotes the deintercalation of proton and oxygen anion from the catalyst surface. The oxygen vacancies formed in NiCo hydroxide during glycerol electrooxidation reaction increase d-band filling on Co sites, facilitating the charge transfer from catalyst surface to cleaved molecules during the 2 nd C-C bond cleavage. Consequently, NiCo hydroxide exhibits enhanced glycerol electrooxidation activity, with a current density of 100 mA/cm 2 at 1.35 V and a formate selectivity of 94.3%., (© 2022. The Author(s).)

Published

2022

15. Subnanometric Cu clusters on atomically Fe-doped MoO 2 for furfural upgrading to aviation biofuels.

Author

Zhao X, Wang F, Kong X, Fang R, and Li Y

Subjects

Alcohols chemistry, Biofuels, Catalysis, Aviation, Furaldehyde chemistry

Abstract

Single cluster catalysts (SCCs) are considered as versatile boosters in heterogeneous catalysis due to their modifiable single cluster sites and supports. In this work, we report subnanometric Cu clusters dispersed on Fe-doped MoO 2 support for biomass-derived furfural upgrading. Systematical characterizations suggest uniform Cu clusters (composing four Cu atoms in average) are homogeneously immobilized on the atomically Fe-doped ultrafine MoO 2 nanocrystals (Cu 4 /Fe 0.3 Mo 0.7 O 2 @C). The atomic doping of Fe into MoO 2 leads to significantly modified electronic structure and consequently charge redistribution inside the supported Cu clusters. The as-prepared Cu 4 /Fe 0.3 Mo 0.7 O 2 @C shows superior catalytic performance in the oxidative coupling of furfural with C 3 ~C 10 primary/secondary alcohols to produce C 8 ~C 15 aldehydes/ketones (aviation biofuel intermediates), outperforming the conventionally prepared counterparts. DFT calculations and control experiments are further carried out to interpret the structural and compositional merits of Cu 4 /Fe 0.3 Mo 0.7 O 2 @C in the oxidative coupling reaction, and elucidate the reaction pathway and related intermediates., (© 2022. The Author(s).)

Published

2022

16. Activating lattice oxygen in NiFe-based (oxy)hydroxide for water electrolysis.

Author

He Z, Zhang J, Gong Z, Lei H, Zhou D, Zhang N, Mai W, Zhao S, and Chen Y

Abstract

Transition metal oxides or (oxy)hydroxides have been intensively investigated as promising electrocatalysts for energy and environmental applications. Oxygen in the lattice was reported recently to actively participate in surface reactions. Herein, we report a sacrificial template-directed approach to synthesize Mo-doped NiFe (oxy)hydroxide with modulated oxygen activity as an enhanced electrocatalyst towards oxygen evolution reaction (OER). The obtained MoNiFe (oxy)hydroxide displays a high mass activity of 1910 A/g metal at the overpotential of 300 mV. The combination of density functional theory calculations and advanced spectroscopy techniques suggests that the Mo dopant upshifts the O 2p band and weakens the metal-oxygen bond of NiFe (oxy)hydroxide, facilitating oxygen vacancy formation and shifting the reaction pathway for OER. Our results provide critical insights into the role of lattice oxygen in determining the activity of (oxy)hydroxides and demonstrate tuning oxygen activity as a promising approach for constructing highly active electrocatalysts., (© 2022. The Author(s).)

Published

2022

17. Tuning proton-coupled electron transfer by crystal orientation for efficient water oxidization on double perovskite oxides.

Author

Zhu Y, He Z, Choi Y, Chen H, Li X, Zhao B, Yu Y, Zhang H, Stoerzinger KA, Feng Z, Chen Y, and Liu M

Abstract

Developing highly efficient and cost-effective oxygen evolution reaction (OER) electrocatalysts is critical for many energy devices. While regulating the proton-coupled electron transfer (PCET) process via introducing additive into the system has been reported effective in promoting OER activity, controlling the PCET process by tuning the intrinsic material properties remains a challenging task. In this work, we take double perovskite oxide PrBa 0.5 Sr 0.5 Co 1.5 Fe 0.5 O 5+δ (PBSCF) as a model system to demonstrate enhancing OER activity through the promotion of PCET by tuning the crystal orientation and correlated proton diffusion. OER kinetics on PBSCF thin films with (100), (110), and (111) orientation, deposited on single crystal LaAlO 3 substrates, were investigated using electrochemical measurements, density functional theory (DFT) calculations, and synchrotron-based near ambient X-ray photoelectron spectroscopy. The results clearly show that the OER activity and the ease of deprotonation depend on orientation and follow the order of (100) > (110) > (111). Correlated with OER activity, proton diffusion is found to be the fastest in the (100) film, followed by (110) and (111) films. Our results point out a way of boosting PCET and OER activity, which can also be successfully applied to a wide range of crucial applications in green energy and environment.

Published

2020

18. Author Correction: Indirect tail states formation by thermal-induced polar fluctuations in halide perovskites.

Author

Wu B, Yuan H, Xu Q, Steele JA, Giovanni D, Puech P, Fu J, Ng YF, Jamaludin NF, Solanki A, Mhaisalkar S, Mathews N, Roeffaers MBJ, Grätzel M, Hofkens J, and Sum TC

Abstract

The original version of this article incorrectly listed the present address of Bo Wu as 'Present address: Institute of Electronic Paper Displays, South China Academy of Advanced Optoelectronics, South China Normal University, Guangzhou, Guangdong Province 510006, China'. This is the author's primary affiliation. This has been corrected in both the PDF and HTML versions of the article.

Published

2019

19. Engineered microbial biofuel production and recovery under supercritical carbon dioxide.

Author

Boock JT, Freedman AJE, Tompsett GA, Muse SK, Allen AJ, Jackson LA, Castro-Dominguez B, Timko MT, Prather KLJ, and Thompson JR

Subjects

Bacillus megaterium metabolism, Butanols metabolism, Fermentation, Hemiterpenes, Keto Acids metabolism, Pentanols metabolism, Biofuels, Carbon Dioxide metabolism

Abstract

Culture contamination, end-product toxicity, and energy efficient product recovery are long-standing bioprocess challenges. To solve these problems, we propose a high-pressure fermentation strategy, coupled with in situ extraction using the abundant and renewable solvent supercritical carbon dioxide (scCO 2 ), which is also known for its broad microbial lethality. Towards this goal, we report the domestication and engineering of a scCO 2 -tolerant strain of Bacillus megaterium, previously isolated from formation waters from the McElmo Dome CO 2 field, to produce branched alcohols that have potential use as biofuels. After establishing induced-expression under scCO 2 , isobutanol production from 2-ketoisovalerate is observed with greater than 40% yield with co-produced isopentanol. Finally, we present a process model to compare the energy required for our process to other in situ extraction methods, such as gas stripping, finding scCO 2 extraction to be potentially competitive, if not superior.

Published

2019

20. Indirect tail states formation by thermal-induced polar fluctuations in halide perovskites.

Author

Wu B, Yuan H, Xu Q, Steele JA, Giovanni D, Puech P, Fu J, Ng YF, Jamaludin NF, Solanki A, Mhaisalkar S, Mathews N, Roeffaers MBJ, Grätzel M, Hofkens J, and Sum TC

Abstract

Halide perovskites possess enormous potential for various optoelectronic applications. Presently, a clear understanding of the interplay between the lattice and electronic effects is still elusive. Specifically, the weakly absorbing tail states and dual emission from perovskites are not satisfactorily described by existing theories based on the Urbach tail and reabsorption effect. Herein, through temperature-dependent and time-resolved spectroscopy on metal halide perovskite single crystals with organic or inorganic A-site cations, we confirm the existence of indirect tail states below the direct transition edge to arise from a dynamical Rashba splitting effect, caused by the PbBr 6 octahedral thermal polar distortions at elevated temperatures. This dynamic effect is distinct from the static Rashba splitting effect, caused by non-spherical A-site cations or surface induced lattice distortions. Our findings shed fresh perspectives on the electronic-lattice relations paramount for the design and optimization of emergent perovskites, revealing broad implications for light harvesting/photo-detection and light emission/lasing applications.

Published

2019

21. In vivo transplantation of 3D encapsulated ovarian constructs in rats corrects abnormalities of ovarian failure.

Author

Sittadjody S, Saul JM, McQuilling JP, Joo S, Register TC, Yoo JJ, Atala A, and Opara EC

Subjects

Alginates chemistry, Animals, Bone Density, Calcium chemistry, Cell Transplantation methods, Estrogens metabolism, Female, Hormones blood, Osteocalcin blood, Primary Ovarian Insufficiency therapy, Rats, Inbred F344, Strontium chemistry, Theca Cells transplantation, Uterus physiology, Granulosa Cells transplantation, Hormone Replacement Therapy methods, Ovary cytology

Abstract

Safe clinical hormone replacement (HR) will likely become increasingly important in the growing populations of aged women and cancer patients undergoing treatments that ablate the ovaries. Cell-based HRT (cHRT) is an alternative approach that may allow certain physiological outcomes to be achieved with lower circulating hormone levels than pharmacological means due to participation of cells in the hypothalamus-pituitary-ovary feedback control loop. Here we describe the in vivo performance of 3D bioengineered ovarian constructs that recapitulate native cell-cell interactions between ovarian granulosa and theca cells as an approach to cHRT. The constructs are fabricated using either Ca ++ or Sr ++ to crosslink alginate. Following implantation in ovariectomized (ovx) rats, the Sr ++ -cross-linked constructs achieve stable secretion of hormones during 90 days of study. Further, we show these constructs with isogeneic cells to be effective in ameliorating adverse effects of hormone deficiency, including bone health, uterine health, and body composition in this rat model.

Published

2017

22. Optimization of hierarchical structure and nanoscale-enabled plasmonic refraction for window electrodes in photovoltaics.

Author

Han B, Peng Q, Li R, Rong Q, Ding Y, Akinoglu EM, Wu X, Wang X, Lu X, Wang Q, Zhou G, Liu JM, Ren Z, Giersig M, Herczynski A, Kempa K, and Gao J

Abstract

An ideal network window electrode for photovoltaic applications should provide an optimal surface coverage, a uniform current density into and/or from a substrate, and a minimum of the overall resistance for a given shading ratio. Here we show that metallic networks with quasi-fractal structure provides a near-perfect practical realization of such an ideal electrode. We find that a leaf venation network, which possesses key characteristics of the optimal structure, indeed outperforms other networks. We further show that elements of hierarchal topology, rather than details of the branching geometry, are of primary importance in optimizing the networks, and demonstrate this experimentally on five model artificial hierarchical networks of varied levels of complexity. In addition to these structural effects, networks containing nanowires are shown to acquire transparency exceeding the geometric constraint due to the plasmonic refraction.

Published

2016