Your search keyword '"Chinmayee V. Subban"' showing total 22 results

1. Ocean Deacidification Technologies for Marine Aquaculture

Author

Christopher R. Myers and Chinmayee V. Subban

Subjects

CO2 removal, aquaculture, mCDR, Naval architecture. Shipbuilding. Marine engineering, VM1-989, Oceanography, GC1-1581

Abstract

The increase in partial pressure of CO2 in the oceans directly affects the productivity and survival of coastal industries and ecosystems. For marine aquaculture, the decreased alkalinity of seawater results in reduced availability of carbonates for marine organisms to build their shells, leading to decreased aquaculture quality and productivity. The industry has been implementing recirculating aquaculture systems (RASs) to reduce CO2 in feedwaters, but recent interest in ocean-based CO2 capture has led to additional strategies that may be relevant. The new methods in addition to CO2 removal offer capture options for enhanced aquaculture sustainability. Here, we review and compare early-stage and commercially available technologies for deacidification of seawater and their suitability for aquaculture. Most methods considered rely on a voltage-induced pH swing to shift the carbonate/bicarbonate equilibrium toward the release of CO2, with subsequent capture of the released CO2 as a gas or as solid mineral carbonates. The modular design and distributed deployment potential of these systems offers promise, but current demonstrations are limited to bench scale, highlighting the need for sustained research and development before they can be implemented for marine aquaculture.

Published

2022

2. Mixing and dilution controls on marine CO2 removal using alkalinity enhancement

Author

Tarang Khangaonkar, Brendan R Carter, Lakshitha Premathilake, Su Kyong Yun, Wenfei Ni, Mary Margaret Stoll, Nicholas D Ward, Lenaïg G Hemery, Carolina Torres Sanchez, Chinmayee V Subban, Mallory C Ringham, Matthew D Eisaman, Todd Pelman, Krti Tallam, and Richard A Feely

Subjects

ocean alkalinity enhancement, modeling, marine carbon dioxide removal, zone of influence, mixing, dilution, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350, Science, Physics, QC1-999

Abstract

Marine CO _2 removal (CDR) using enhanced-alkalinity seawater discharge was simulated in the estuarine waters of the Salish Sea, Washington, US. The high-alkalinity seawater would be generated using bipolar membrane electrodialysis technology to remove acid and the alkaline stream returned to the sea. Response of the receiving waters was evaluated using a shoreline resolving hydrodynamic model with biogeochemistry, and carbonate chemistry. Two sites, and two deployment scales, each with enhanced TA of 2997 mmol m ^−3 and a pH of 9 were simulated. The effects on air-sea CO _2 flux and pH in the near-field as well as over the larger estuary wide domain were assessed. The large-scale deployment (addition of 164 Mmoles TA yr ^−1 ) in a small embayment (Sequim Bay, 12.5 km ^2 ) resulted in removal of 2066 T of CO _2 (45% of total simulated) at rate of 3756 mmol m ^−2 yr ^−1 , higher than the 63 mmol m ^−2 yr ^−1 required globally to remove 1.0 GT CO _2 yr ^−1 . It also reduced acidity in the bay, ΔpH ≈ +0.1 pH units, an amount comparable to the historic impacts of anthropogenic acidification in the Salish Sea. The mixing and dilution of added TA with distance from the source results in reduced CDR rates such that comparable amount 2176 T CO _2 yr ^−1 was removed over >1000 fold larger area of the rest of the model domain. There is the potential for more removal occurring beyond the region modeled. The CDR from reduction of outgassing between October and May accounts for as much as 90% of total CDR simulated. Of the total, only 375 T CO _2 yr ^−1 (8%) was from the open shelf portion of the model domain. With shallow depths limiting vertical mixing, nearshore estuarine waters may provide a more rapid removal of CO _2 using alkalinity enhancement relative to deeper oceanic sites.

Published

2024

3. Flow-Assisted Selective Mineral Extraction from Seawater

Author

Qingpu Wang, Elias Nakouzi, Elisabeth A. Ryan, and Chinmayee V. Subban

Subjects

Ecology, Health, Toxicology and Mutagenesis, Environmental Chemistry, Pollution, Waste Management and Disposal, Water Science and Technology

Published

2022

4. Reply to the ‘Comment on 'Techno-economic analysis of capacitive and intercalative water deionization'’ by S. K. Patel, L. Wang and M. Elimelech, Energy Environ. Sci., 2021, 10.1039/D0EE03321A

Author

Hellstrom Sondra, Saravanan Kuppan, Soo Kim, Jake Christensen, Elias Sebti, Chinmayee V. Subban, Münir M. Besli, and Michael Metzger

Subjects

Materials science, Renewable Energy, Sustainability and the Environment, Capacitive sensing, Environmental engineering, Techno economic, 02 engineering and technology, 021001 nanoscience & nanotechnology, Pollution, Energy (psychological), 020401 chemical engineering, Nuclear Energy and Engineering, Environmental Chemistry, 0204 chemical engineering, 0210 nano-technology

Abstract

This reply provides updated energy consumption estimates at clearly defined separation conditions for electrochemical desalination concepts.

Published

2021

5. Techno-economic analysis of capacitive and intercalative water deionization

Author

Hellstrom Sondra, Soo Kim, Jake Christensen, Elias Sebti, Münir M. Besli, Saravanan Kuppan, Chinmayee V. Subban, and Michael Metzger

Subjects

Materials science, Renewable Energy, Sustainability and the Environment, Capacitive deionization, Capacitive sensing, Intercalation (chemistry), 02 engineering and technology, 010501 environmental sciences, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, Pollution, Nuclear Energy and Engineering, Chemical engineering, Electrode, medicine, Environmental Chemistry, Gravimetric analysis, 0210 nano-technology, Reverse osmosis, 0105 earth and related environmental sciences, Activated carbon, medicine.drug

Abstract

We conduct a techno-economic analysis of electrochemical water deionization technologies. The objective of the analysis is to compare cost, volume, and energy consumption of membrane capacitive deionization (mCDI) to intercalative deionization techniques. Here, we first explore the concept of hybrid capacitive deionization (HCDI), i.e., a cation intercalation electrode paired with an activated carbon capacitive electrode. Then we explore in detail a novel device concept, fully intercalative water deionization (IDI), which relies entirely on the cation intercalation principle. The intercalation host materials in our study are Prussian blue analogs (PBAs), e.g., NiFe(CN)6 or CuFe(CN)6, that offer ∼3–5× higher gravimetric salt removal capacities than typical activated carbon. Our analysis shows that IDI should be superior to mCDI in module cost, volume, and energy efficiency, despite a more complex module architecture. Making careful assumptions on material costs, we provide a cost breakdown for mCDI, HCDI, and IDI modules and show that IDI is the only concept that is not dominated by ion exchange membrane costs. The environmental impact of electrochemical water deionization is illustrated by estimating the carbon footprint of currently installed reverse osmosis capacity in different world regions and comparing it to the respective carbon footprint of mCDI, HCDI, and IDI at similar capacity.

Published

2020

6. Electrically regenerated ion-exchange technology for desalination of low-salinity water sources

Author

Ashok J. Gadgil and Chinmayee V. Subban

Subjects

Low salinity, Ion exchange, business.industry, Mechanical Engineering, General Chemical Engineering, Water source, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, Desalination, Water softening, 020401 chemical engineering, Environmental science, General Materials Science, 0204 chemical engineering, 0210 nano-technology, Process engineering, business, Ion-exchange resin, Functional composite, Water Science and Technology

Abstract

A promising approach to increasing freshwater availability is the effective desalination of widely available and abundant low-salinity water sources. Here we report a new approach to desalinate low-salinity water sources using inexpensive ion exchange resins (IER) which are commonly used for water softening and require regular chemical regeneration. We incorporate IER into a functional composite material that enables electrical regeneration of IER, eliminating the need for regular use of corrosive chemicals. These proof-of-concept results demonstrate reliable regeneration of IER-composite electrodes using a lab-scale prototype device. With further characterization and development, this new approach offers a path to sustainable use of conventional IER for desalination of low-salinity water sources.

Published

2019

7. Extracting energy from ocean thermal and salinity gradients to power unmanned underwater vehicles: State of the art, current limitations, and future outlook

Author

Hyunjun Jung, Chinmayee V. Subban, Joshua Dominic McTigue, Jayson J. Martinez, Andrea E. Copping, Julian Osorio, Jian Liu, and Z. Daniel Deng

Subjects

Renewable Energy, Sustainability and the Environment

Published

2022

8. Developing Novel Electrode Materials for Aqueous Battery

Author

Chinmayee V. Subban

Subjects

Battery (electricity), Electrode material, Aqueous solution, Materials science, Nanotechnology

Published

2020

9. Removal of Na+ and Ca2+ with Prussian blue analogue electrodes for brackish water desalination

Author

Jake Christensen, Judith Alvarado, Chinmayee V. Subban, Marca M. Doeff, Münir M. Besli, Saravanan Kuppan, Morgan J. Schultz-Neu, Hellstrom Sondra, Michael Metzger, and Elias Sebti

Subjects

chemistry.chemical_classification, Prussian blue, Mechanical Engineering, General Chemical Engineering, Inorganic chemistry, Intercalation (chemistry), Salt (chemistry), chemistry.chemical_element, 02 engineering and technology, General Chemistry, Zinc, Manganese, 021001 nanoscience & nanotechnology, Copper, Desalination, chemistry.chemical_compound, 020401 chemical engineering, chemistry, General Materials Science, 0204 chemical engineering, 0210 nano-technology, Dissolution, Water Science and Technology

Abstract

Desalination of brackish water sources is critical to addressing the growing global freshwater demand. One promising approach is electrically driven desalination using intercalation electrodes. While intercalation electrodes have been widely researched for energy storage applications, only a small subset of those materials is suitable for desalination. Here we report the synthesis, characterization, and in-device testing of three Prussian blue analogue intercalation compounds: copper, manganese, and zinc hexacyanoferrate with formulas KxM[Fe(CN)6]z·nH2O (M = Cu, Mn, Zn). The desalination performance for each of these materials against carbon electrodes is reported for Na+ intercalation and for Ca2+ intercalation using 1000 ppm NaCl and 1000 ppm CaCl2 feed solutions, respectively. While the copper and manganese analogs showed promising performance for Na+ and Ca2+ intercalation, the zinc compound was unstable and underwent rapid dissolution. Manganese hexacyanoferrate showed the best desalination performance in terms of salt removal capacities and salt removal rates with NaCl while copper hexacyanoferrate performed the best with CaCl2. The manganese analog proved to be the most stable intercalation material, retaining 83% and 72% of its salt removal capacity after 280 cycles in NaCl and CaCl2 feed solutions respectively.

Published

2020

10. A Road Map for Small-Scale Desalination: An overview of existing and emerging technology solutions for cost-efficient and low-energy desalination in South and Southeast Asia

Author

Kathryn Boden and Chinmayee V. Subban

Subjects

Consumption (economics), Cost efficiency, Emerging technologies, Environmental science, Climate change, Road map, Scale (map), Water resource management, Desalination, Southeast asia

Abstract

In Asia, access to drinking water is a major issue because of the intrusion of saline groundwater in many areas. Water containing a high concentration of salts is unsuitable for human consumption. The situation is expected to get worse as a result of climate change. This report suggests the development of a ‘road map’ for scalable, low energy-input solutions for small-scale desalination.

Published

2018

11. Polymorphism in Bi2(SO4)3

Author

Philippe Barboux, Matthieu Courty, Chinmayee V. Subban, Gwenaëlle Rousse, and Jean-Marie Tarascon

Subjects

Crystallography, Materials science, Polymorphism (materials science), General Materials Science, General Chemistry, Crystal structure, Condensed Matter Physics, Powder diffraction, Layered structure

Abstract

A new polymorph of Bi 2 (SO 4 ) 3 was prepared by reaction of LiBiO 2 with H 2 SO 4 and its crystal structure was solved from X-ray powder diffraction. This new polymorph crystallizes in C 2/ c space group with lattice parameters a = 17.3383(3) A, b = 6.77803(12) A, c = 8.30978(13) A, β = 101.4300(12)°. Bi 2 (SO 4 ) 3 presents a layered structure made of SO 4 sulfate groups and signs of stereochemically active Bi 3+ lone pairs. The new Bi 2 (SO 4 ) 3 absorbs water to form Bi 2 (H 2 O) 2 (SO 4 ) 2 (OH) 2 through an intermediate Bi 2 O(OH) 2 SO 4 phase, and the transition is reversible when heated under vacuum.

Published

2014

12. Interconversion of Inverse Opals of Electrically Conducting Doped Titanium Oxides and Nitrides

Author

Chinmayee V. Subban, Francis J. DiSalvo, and Ian C. P. Smith

Subjects

Materials science, Catalyst support, Doping, chemistry.chemical_element, Nanoparticle, Nanotechnology, General Chemistry, Crystal structure, Nitride, Amorphous solid, Biomaterials, chemistry, Chemical engineering, Rutile, General Materials Science, Biotechnology, Titanium

Abstract

There is a need for conducting, porous, and chemically stable materials for technologies including, but not limited to, fuel cells, solar cells, and batteries. The need for catalyst support materials that are more durable than carbon black in fuel cells motivated previous studies of the synthesis, characterization, and corrosion resistance of Ti(0.7) W(0.3) O(2) nanoparticles. However, because even higher porosity and increased electrical conductivity are desired, processes were developed to prepare rutile phase Ti(0.7) W(0.3) O(2) and cubic Ti(0.7) W(0.3) N in inverse opal morphologies from a precursor inverse opal of very poorly conducting, amorphous Ti(0.7) W(0.3) O(2.3) . Inverse opals have been explored for a variety of applications from catalysis to photonics, and inverse opals of both oxides and nitrides have been reported. By synthesizing highly conducting mixed-metal oxides and mixed-metal nitrides, the applications of inverse opals can be broadened. Herein, the synthesis and characterization of polystyrene-templated, single-phase, crystalline inverse opals of Ti(0.7) W(0.3) O(2) are reported. These conducting inverse opals can subsequently be converted to inverse opals of Ti(0.7) W(0.3) N and then fully oxidized back to inverse opals of the original insulating, amorphous Ti(0.7) W(0.3) O(2.3) . Such changes in composition and crystal structure, while successfully retaining the inverse opal morphology without the use of a supporting template during the conversion, have not been previously reported.

Published

2012

13. Search for Li-electrochemical activity and Li-ion conductivity among lithium bismuth oxides

Author

Chinmayee V. Subban, Philippe Barboux, Rose-Noëlle Vannier, Christel Laberty-Robert, Gwenaëlle Rousse, Jean-Marie Tarascon, Institut de minéralogie, de physique des matériaux et de cosmochimie (IMPMC), Muséum national d'Histoire naturelle (MNHN)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut de recherche pour le développement [IRD] : UR206-Centre National de la Recherche Scientifique (CNRS), Collège de France - Chaire Chimie du solide et énergie, Chimie du solide et de l'énergie (CSE), Collège de France (CdF (institution))-Institut de Chimie du CNRS (INC)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Collège de France (CdF (institution))-Institut de Chimie du CNRS (INC)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Unité de Catalyse et Chimie du Solide - UMR 8181 (UCCS), Université d'Artois (UA)-Centrale Lille-Institut de Chimie du CNRS (INC)-Université de Lille-Centre National de la Recherche Scientifique (CNRS), Laboratoire de Chimie de la Matière Condensée de Paris (LCMCP), Université Pierre et Marie Curie - Paris 6 (UPMC)-Collège de France (CdF (institution))-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS), Advanced Lithium Energy Storage Systems - ALISTORE-ERI (ALISTORE-ERI), Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS), Réseau sur le stockage électrochimique de l'énergie (RS2E), Université de Nantes (UN)-Aix Marseille Université (AMU)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Collège de France (CdF (institution))-Université de Picardie Jules Verne (UPJV)-Ecole Nationale Supérieure de Chimie de Montpellier (ENSCM)-Ecole Nationale Supérieure de Chimie de Paris - Chimie ParisTech-PSL (ENSCP), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université de Pau et des Pays de l'Adour (UPPA)-Institut de Chimie du CNRS (INC)-Université de Montpellier (UM)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Institut National Polytechnique (Toulouse) (Toulouse INP), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP ), Université Grenoble Alpes (UGA)-Université Grenoble Alpes (UGA), Reseau sur le Stockage Electrochimique de l'Energie (RS2E), Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut de recherche pour le développement [IRD] : UR206-Muséum national d'Histoire naturelle (MNHN)-Centre National de la Recherche Scientifique (CNRS), Chaire Chimie du solide et énergie, Centre National de la Recherche Scientifique (CNRS)-Collège de France (CdF (institution))-Institut de Chimie du CNRS (INC)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Collège de France (CdF (institution))-Institut de Chimie du CNRS (INC)-Sorbonne Université (SU), Centrale Lille Institut (CLIL)-Université d'Artois (UA)-Centrale Lille-Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC)-Université de Lille, Université Pierre et Marie Curie - Paris 6 (UPMC)-Centre National de la Recherche Scientifique (CNRS)-Collège de France (CdF (institution))-Institut de Chimie du CNRS (INC), Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC), Université de Picardie Jules Verne (UPJV)-Institut de Chimie du CNRS (INC)-Aix Marseille Université (AMU)-Université de Pau et des Pays de l'Adour (UPPA)-Université de Nantes (UN)-Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS)-Sorbonne Université (SU)-Ecole Nationale Supérieure de Chimie de Paris - Chimie ParisTech-PSL (ENSCP), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Collège de France (CdF (institution))-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP ), Université Grenoble Alpes (UGA)-Université Grenoble Alpes (UGA)-Institut National Polytechnique (Toulouse) (Toulouse INP), and Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Ecole Nationale Supérieure de Chimie de Montpellier (ENSCM)

Subjects

Materials science, Lithium vanadium phosphate battery, Cathode materials, Inorganic chemistry, chemistry.chemical_element, 02 engineering and technology, Conductivity, 010402 general chemistry, Electrochemistry, 7. Clean energy, 01 natural sciences, Bismuth, Hydrothermal synthesis, Ionic conductivity, General Materials Science, Valence (chemistry), General Chemistry, [CHIM.MATE]Chemical Sciences/Material chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Lithium battery, 0104 chemical sciences, chemistry, Lithium ion batteries, Lithium bismuth oxides, 0210 nano-technology

Abstract

International audience; Previously reported lithium bismuth oxides, LiBiO2, LiBiO3, Li3BiO3, Li3BiO4, Li5BiO5, and Li7BiO6 were prepared either via ceramic or hydrothermal synthesis methods, and their feasibility as lithium battery cathode materials was tested. None of the oxides showed any desirable electrochemical activity at higher potentials, except for the limited capacity observed during the first discharge in LiBiO3. In contrast, these phases uptake large amounts of Li+ via conversion reactions when cycled down to zero volt, but the reversibility is poor. The transformation of LiBiO3 to LiBiO2 and Li3BiO3 to Li3BiO4 observed via X-ray diffraction showed absence of intermediate phases with mixed Bi3+/Bi5+ oxidation states. Among the materials studied, the highest ionic conductivity of 3.8 x 10(-8) S/cm at 25 degrees C was measured for LiBiO2. The Li+ conduction pathways deduced from bond valence energy landscape approach suggest the best Li diffusion characteristics in Li7BiO6 among the Li-Bi-O phases studied. (C) 2015 Published by Elsevier B.V.

Published

2015

14. Silver delafossite nitride, AgTaN2?

Author

Richard Dronskowski, Shinichi Kikkawa, Michael A. Lowe, Richard G. Hennig, Chinmayee V. Subban, Yuji Masubuchi, Héctor D. Abruña, Brian M. Leonard, Francis J. DiSalvo, and Akira Miura

Subjects

Inorganic chemistry, Analytical chemistry, Crystal structure, Nitride, engineering.material, Condensed Matter Physics, Electron spectroscopy, Electronic, Optical and Magnetic Materials, Inorganic Chemistry, chemistry.chemical_compound, Silver nitrate, Delafossite, X-ray photoelectron spectroscopy, chemistry, Materials Chemistry, Ceramics and Composites, engineering, Silver nitride, Physical and Theoretical Chemistry, Stoichiometry

Abstract

A new silver nitride, AgTaN 2 , was synthesized from NaTaN 2 by a cation-exchange reaction, using a AgNO 3 –NH 4 NO 3 flux at 175 °C. Its crystal structure type is delafossite (R3¯m) with hexagonal lattice parameters of a =3.141(3) A, c =18.81(2) A, in which silver is linearly coordinated to nitrogen. Energy dispersive X-ray analysis and combustion nitrogen/oxygen analysis gave a composition with atomic ratios of Ag:Ta:N:O as 1.0:1.2(1):2.1(1):0.77(4), which is somewhat Ta rich and indicates some oxide formation. The X-ray photoelectron spectroscopy analysis showed a Ta- and O-rich surface and transmission electron microscope observation exhibited aggregates of ca. 4–5 nm-sized particles on the surface, which are probably related to the composition deviation from a AgTaN 2 . The lattice parameters of stoichiometric AgTaN 2 calculated by density functional theory agree with the experimental ones, but the possibility of some oxygen incorporation and/or silver deficiency is not precluded.

Published

2011

15. ChemInform Abstract: Polymorphism in Bi2(SO4)3

Author

Matthieu Courty, Philippe Barboux, Gwenaëlle Rousse, Chinmayee V. Subban, and Jean-Marie Tarascon

Subjects

Crystallography, Polymorphism (materials science), Chemistry, Inorganic chemistry, General Medicine, Crystal structure, Powder diffraction, Layered structure

Abstract

A new polymorph of Bi 2 (SO 4 ) 3 was prepared by reaction of LiBiO 2 with H 2 SO 4 and its crystal structure was solved from X-ray powder diffraction. This new polymorph crystallizes in C 2/ c space group with lattice parameters a = 17.3383(3) A, b = 6.77803(12) A, c = 8.30978(13) A, β = 101.4300(12)°. Bi 2 (SO 4 ) 3 presents a layered structure made of SO 4 sulfate groups and signs of stereochemically active Bi 3+ lone pairs. The new Bi 2 (SO 4 ) 3 absorbs water to form Bi 2 (H 2 O) 2 (SO 4 ) 2 (OH) 2 through an intermediate Bi 2 O(OH) 2 SO 4 phase, and the transition is reversible when heated under vacuum.

Published

2015

16. Highly Stable and CO-Tolerant Pt/Ti0.7W0.3O2 Electrocatalyst for Proton-Exchange Membrane Fuel Cells

Author

Chinmayee V. Subban, Deli Wang, Eric D. Rus, Francis J. DiSalvo, Hongsen Wang, and Héctor D. Abruña

Subjects

Chemistry, Hydrogen oxidation, Inorganic chemistry, Proton exchange membrane fuel cell, Nanoparticle, General Chemistry, Electrocatalyst, Electrochemistry, Mass spectrometry, Biochemistry, Catalysis, Colloid and Surface Chemistry, Membrane

Abstract

The current materials used in proton-exchange membrane fuel cells (PEMFCs) are not sufficiently durable for commercial deployment. One of the major challenges lies in the development of an inexpensive, efficient, and CO-tolerant anode catalyst. Here we report the unique CO-tolerant property of Pt nanoparticles supported on Ti(0.7)W(0.3)O(2). The Ti(0.7)W(0.3)O(2) nanoparticles (50 nm) were synthesized via a sol-gel process and platinized using an impregnation-reduction technique. Electrochemical studies of Pt/Ti(0.7)W(0.3)O(2) show unique CO-tolerant electrocatalytic activity for hydrogen oxidation compared to commercial E-TEK PtRu/C catalysts. Differential electrochemical mass spectrometry measurements show the onset potential for CO oxidation on Pt/Ti(0.7)W(0.3)O(2) to be below 0.1 V (vs RHE). Pt/Ti(0.7)W(0.3)O(2) is a promising new anode catalyst for PEMFC applications.

Published

2010

17. ChemInform Abstract: Preparation, Structure, and Electrochemistry of Layered Polyanionic Hydroxysulfates: LiMSO4OH (M: Fe, Co, Mn) Electrodes for Li-Ion Batteries

Author

Chinmayee V. Subban, Gwenaëlle Rousse, Artem M. Abakumov, Raphaël Janot, Gustaaf Van Tendeloo, Jean-Marie Tarascon, and Mohamed Ati

Subjects

Transition metal, Chemistry, Inorganic chemistry, Electrode, Anhydrous, General Medicine, Electrochemistry, Ball mill, Ion

Abstract

The title compounds are prepared by ball milling of mixtures of LiOH and anhydrous MSO4 (M: Fe, Co, Mn) precursors.

Published

2013

18. Preparation, Structure, and Electrochemistry of Layered Polyanionic Hydroxysulfates: LiMSO4OH (M = Fe, Co, Mn) Electrodes for Li-Ion Batteries

Author

Gustaaf Van Tendeloo, Mohamed Ati, Jean-Marie Tarascon, Artem M. Abakumov, Chinmayee V. Subban, Gwenaëlle Rousse, Raphaël Janot, Laboratoire réactivité et chimie des solides - UMR CNRS 7314 (LRCS), Université de Picardie Jules Verne (UPJV)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS), Réseau sur le stockage électrochimique de l'énergie (RS2E), Université de Nantes (UN)-Aix Marseille Université (AMU)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Collège de France (CdF (institution))-Université de Picardie Jules Verne (UPJV)-Ecole Nationale Supérieure de Chimie de Montpellier (ENSCM)-Ecole Nationale Supérieure de Chimie de Paris - Chimie ParisTech-PSL (ENSCP), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université de Pau et des Pays de l'Adour (UPPA)-Institut de Chimie du CNRS (INC)-Université de Montpellier (UM)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Institut National Polytechnique (Toulouse) (Toulouse INP), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP ), Université Grenoble Alpes (UGA)-Université Grenoble Alpes (UGA), Advanced Lithium Energy Storage Systems - ALISTORE-ERI (ALISTORE-ERI), Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS), Institut de minéralogie et de physique des milieux condensés (IMPMC), Université Pierre et Marie Curie - Paris 6 (UPMC)-Université Paris Diderot - Paris 7 (UPD7)-Institut de Physique du Globe de Paris (IPG Paris)-Centre National de la Recherche Scientifique (CNRS), EMAT, University of Antwerp, University of Antwerp (UA), Université de Picardie Jules Verne (UPJV)-Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC), Université de Picardie Jules Verne (UPJV)-Institut de Chimie du CNRS (INC)-Aix Marseille Université (AMU)-Université de Pau et des Pays de l'Adour (UPPA)-Université de Nantes (UN)-Université de Montpellier (UM)-Centre National de la Recherche Scientifique (CNRS)-Sorbonne Université (SU)-Ecole Nationale Supérieure de Chimie de Paris - Chimie ParisTech-PSL (ENSCP), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Collège de France (CdF (institution))-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP ), Université Grenoble Alpes (UGA)-Université Grenoble Alpes (UGA)-Institut National Polytechnique (Toulouse) (Toulouse INP), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Ecole Nationale Supérieure de Chimie de Montpellier (ENSCM), and Université Pierre et Marie Curie - Paris 6 (UPMC)-IPG PARIS-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Battery (electricity), Chemistry, Inorganic chemistry, Nanotechnology, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, 7. Clean energy, Biochemistry, Catalysis, 0104 chemical sciences, Ion, Colloid and Surface Chemistry, [PHYS.COND.CM-GEN]Physics [physics]/Condensed Matter [cond-mat]/Other [cond-mat.other], Electrode, Energy density, Electronics, 0210 nano-technology

Abstract

International audience; The Li-ion rechargeable battery, due to its high energy density, has driven remarkable advances in portable electronics. Moving toward more sustainable electrodes could make this technology even more attractive to large-volume applications. We present here a new family of 3d-metal hydroxysulfates of general formula LiMSO4OH (M = Fe, Co, and Mn) among which (i) LiFeSO4OH reversibly releases 0.7 Li+ at an average potential of 3.6 V vs Li+/Li0, slightly higher than the potential of currently lauded LiFePO4 (3.45 V) electrode material, and (ii) LiCoSO4OH shows a redox activity at 4.7 V vs Li+/Li0. Besides, these compounds can be easily made at temperatures near 200 °C via a synthesis process that enlists a new intermediate phase of composition M3(SO4)2(OH)2 (M = Fe, Co, Mn, and Ni), related to the mineral caminite. Structurally, we found that LiFeSO4OH is a layered phase unlike the previously reported 3.2 V tavorite LiFeSO4OH. This work should provide an impetus to experimentalists for designing better electrolytes to fully tap the capacity of high-voltage Co-based hydroxysulfates, and to theorists for providing a means to predict the electrochemical redox activity of two polymorphs.

Published

2012

19. Sol-gel synthesis, electrochemical characterization, and stability testing of Ti(0.7)W(0.3)O2 nanoparticles for catalyst support applications in proton-exchange membrane fuel cells

Author

Francis J. DiSalvo, Frederick T. Wagner, Chinmayee V. Subban, Anthony Hu, Qin Zhou, and Thomas E. Moylan

Subjects

Catalyst support, Inorganic chemistry, Oxide, Proton exchange membrane fuel cell, Nanoparticle, General Chemistry, Biochemistry, Catalysis, chemistry.chemical_compound, Colloid and Surface Chemistry, Membrane, chemistry, Nafion, Oxidizing agent

Abstract

The materials currently used in proton-exchange membrane fuel cells (PEMFCs) require complex control of operating conditions to make them sufficiently durable to permit commercial deployment. One of the major materials challenges to allow simplification of fuel cell operating strategies is the discovery of catalyst supports that are much more stable to oxidative decomposition than currently used carbon blacks. Here we report the synthesis and characterization of Ti(0.7)W(0.3)O2 nanoparticles (approximately 50 nm diameter), a promising doped metal oxide that is a candidate for such a durable catalyst support. The synthesized nanoparticles were platinized, characterized by electrochemical testing, and evaluated for stability under PEMFC and other oxidizing acidic conditions. Ti(0.7)W(0.3)O2 nanoparticles show no evidence of decomposition when heated in a Nafion solution for 3 weeks at 80 °C. In contrast, when heated in sulfuric, nitric, perchloric, or hydrochloric acid, the oxide reacts to form salts such as titanylsulfatehydrate from sulfuric acid. Electrochemical tests show that rates of hydrogen oxidation and oxygen reduction by platinum nanoparticles supported on Ti(0.7)W(0.3)O2 are comparable to those of commercial Pt on carbon black.

Published

2010

20. Catalyst supports for polymer electrolyte fuel cells

Author

Francis J. DiSalvo, Janet L. Hunting, Brian M. Leonard, Qin Zhou, Semeret Munie, Heather M. Edvenson, Chinmoy Ranjan, and Chinmayee V. Subban

Subjects

Conservation of Natural Resources, Energy-Generating Resources, Materials science, Hydrogen, Polymers, General Mathematics, Oxide, General Physics and Astronomy, chemistry.chemical_element, Proton exchange membrane fuel cell, Electrolyte, Electrochemistry, Catalysis, chemistry.chemical_compound, Electric Power Supplies, Electricity, X-Ray Diffraction, Materials Testing, Nanotechnology, Electrodes, Platinum, Titanium, General Engineering, Carbon black, Hydrogen-Ion Concentration, chemistry, Chemical engineering, Biofuels, Nanoparticles, Carbon

Abstract

A major challenge in obtaining long-term durability in fuel cells is to discover catalyst supports that do not corrode, or corrode much more slowly than the current carbon blacks used in today’s polymer electrolyte membrane fuel cells. Such materials must be sufficiently stable at low pH (acidic conditions) and high potential, in contact with the polymer membrane and under exposure to hydrogen gas and oxygen at temperatures up to perhaps 120°C. Here, we report the initial discovery of a promising class of doped oxide materials for this purpose: Ti1−xMxO2, where M=a variety of transition metals. Specifically, we show that Ti0.7W0.3O2is electrochemically inert over the appropriate potential range. Although the process is not yet optimized, when Pt nanoparticles are deposited on this oxide, electrochemical experiments show that hydrogen is oxidized and oxygen reduced at rates comparable to those seen using a commercial Pt on carbon black support.

Published

2010

21. Chronic in utero Buprenorphine Exposure Causes Prolonged Respiratory Effects in the Guinea Pig Neonate

Author

Michael Wallisch, Rosemary T. Nettleton, George D. Olsen, and Chinmayee V. Subban

Subjects

Narcotic Antagonists, Guinea Pigs, Gestational Age, Motor Activity, Toxicology, Article, Cellular and Molecular Neuroscience, Oxygen Consumption, Developmental Neuroscience, Pregnancy, Toxicity Tests, medicine, Animals, Respiratory function, Dose-Response Relationship, Drug, business.industry, Respiration, Carbon Dioxide, medicine.disease, Buprenorphine, Respiratory Function Tests, Plethysmography, Opioid, Animals, Newborn, In utero, Anesthesia, Prenatal Exposure Delayed Effects, Morphine, Gestation, Female, business, Methadone, medicine.drug

Abstract

Our laboratory studies the effects of in utero opioid exposure on the neonate. In this work we test the effects of chronic in utero exposure to buprenorphine on the neonate. Buprenorphine is a promising candidate for treatment of opioid addiction during pregnancy and it has been suggested to decrease the neonatal abstinence syndrome in human infants. In our guinea pig model, we focused not only on the respiratory effects of in utero exposure on the neonate, but also studied withdrawal signs in the neonate, a major concern of all opioid treatment during pregnancy. Pregnant guinea pigs were treated with daily subcutaneous injections of 0.1 mg/kg buprenorphine during the second half of gestation. We measured weight, locomotor activity and respiratory function in pups of ages 3 to 14 days. Respiratory response was recorded using a two-chamber plethysmograph, while pups were breathing either room air or 5% CO 2 . Our results show that chronic in utero exposure to buprenorphine induces respiratory effects up to day 14 after birth, while earlier studies have shown that effects of either in utero methadone or morphine only persist in the first week after birth in the guinea pig model. These data provide important information for clinical trials of buprenorphine treatment suggesting that duration and severity of respiratory effects of in utero buprenorphine exposure should be monitored.

Published

2009

22. Inverse Opals: Interconversion of Inverse Opals of Electrically Conducting Doped Titanium Oxides and Nitrides (Small 18/2012)

Author

Francis J. DiSalvo, Chinmayee V. Subban, and Ian C. P. Smith

Subjects

Materials science, Doping, chemistry.chemical_element, Mineralogy, Nanoparticle, Inverse, General Chemistry, Conductivity, Nitride, OPALS (Ogren Plant Allergy Scale), Biomaterials, chemistry, Chemical engineering, General Materials Science, Biotechnology, Titanium

Published

2012