8 results on '"Ray, Debmalya"'
Search Results
2. Experimental and Quantum Mechanical Characterization of an Oxygen‐Bridged Plutonium(IV) Dimer.
- Author
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Ray, Debmalya, Xie, Jing, White, Jacob, Sigmon, Ginger E., Gagliardi, Laura, and Hixon, Amy E.
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PLUTONIUM , *CHEMICAL bond lengths , *ELECTRON density , *CHEMICAL bonds - Abstract
We report the synthesis and characterization of K4{[PuCl2(NO3)3]2(μ2‐O)}⋅H2O, which contains the first known μ2‐oxo bridge between two PuIV metal centers. Adding to its uniqueness is the Pu−(μ2‐O) bond length of 2.04 Å, which is the shortest of other analogous compounds. The Pu−(μ2‐O)−Pu bridge is characterized by the mixing of s‐, d‐, and p‐orbitals from Pu with the p‐orbitals of O; the 5f‐orbitals do not participate in bonding. Natural bond orbital analysis indicates that Pu and O interact through one 3c‐2e σPu‐O‐Pu and two 3c‐2e πPu‐O‐Pu bonding orbitals and that the electron density is highly polarized on the μ2‐O. Bond topology properties analysis indicates that the Pu−(μ2‐O) bond shares both ionic and covalent character. Quantum mechanical calculations also show that the dimer has multiconfigurational ground states, where the nonet, septet, quintet, triplet, and singlet are close in energy. This work demonstrates the interplay between experimental and computational efforts that is required to understand the chemical bonding of Pu compounds. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
3. Flying onto global minima on potential energy surfaces: A swarm intelligence guided route to molecular electronic structure.
- Author
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Shukla, Rishabh, Ray, Debmalya, Sarkar, Kanchan, Kumar Dixit, Mayank, and Prasad Bhattacharyya, Shankar
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MOLECULAR electronics , *ELECTRONIC structure , *POTENTIAL energy surfaces , *SWARM intelligence , *ELECTRON density , *HAMILTONIAN systems - Abstract
A novel quantum-classical recipe for locating the global minimum on the potential energy surface of a large molecule and simultaneously predicting the associated electronic charge distribution is developed by interfacing the classical particle swarm optimization with a near optimal unitary evolution scheme for the trial one electron density matrix. The unitary transformation is generated by an antihermitian matrix linked to the molecular electronic Hamiltonian at the instantaneous nuclear configurations discovered by the swarm as it flies. The algorithm is used to predict the extensive reorganization of electronic charge distribution and bond lengths in polythiophene oligomers on doping at various levels. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
4. Chloride and Hydride Transfer as Keys to Catalytic Upcycling of Polyethylene into Liquid Alkanes.
- Author
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Zhang, Wei, Yao, Hai, Khare, Rachit, Zhang, Peiran, Yang, Boda, Hu, Wenda, Ray, Debmalya, Hu, Jianzhi, Camaioni, Donald M., Wang, Huamin, Kim, Sungmin, Lee, Mal‐Soon, Sarazen, Michele L., Chen, Jingguang G., and Lercher, Johannes A.
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CARBENIUM ions , *LOW density polyethylene , *ALKANES , *LEWIS acids , *POLYOLEFINS , *HYDRIDES , *POLYETHYLENE , *ARYL chlorides - Abstract
Transforming polyolefin waste into liquid alkanes through tandem cracking‐alkylation reactions catalyzed by Lewis‐acid chlorides offers an efficient route for single‐step plastic upcycling. Lewis acids in dichloromethane establish a polar environment that stabilizes carbenium ion intermediates and catalyzes hydride transfer, enabling breaking of polyethylene C−C bonds and forming C−C bonds in alkylation. Here, we show that efficient and selective deconstruction of low‐density polyethylene (LDPE) to liquid alkanes is achieved with anhydrous aluminum chloride (AlCl3) and gallium chloride (GaCl3). Already at 60 °C, complete LDPE conversion was achieved, while maintaining the selectivity for gasoline‐range liquid alkanes over 70 %. AlCl3 showed an exceptional conversion rate of 5000 gLDPEmolcat-1h-1 ${{{\rm g}}_{{\rm L}{\rm D}{\rm P}{\rm E}}{{\rm \ }{\rm m}{\rm o}{\rm l}}_{{\rm c}{\rm a}{\rm t}}^{-1}{{\rm \ }{\rm h}}^{-1}}$ , surpassing other Lewis acid catalysts by two orders of magnitude. Through kinetic and mechanistic studies, we show that the rates of LDPE conversion do not correlate directly with the intrinsic strength of the Lewis acids or steric constraints that may limit the polymer to access the Lewis acid sites. Instead, the rates for the tandem processes of cracking and alkylation are primarily governed by the rates of initiation of carbenium ions and the subsequent intermolecular hydride transfer. Both jointly control the relative rates of cracking and alkylation, thereby determining the overall conversion and selectivity. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
5. Chloride and Hydride Transfer as Keys to Catalytic Upcycling of Polyethylene into Liquid Alkanes.
- Author
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Zhang, Wei, Yao, Hai, Khare, Rachit, Zhang, Peiran, Yang, Boda, Hu, Wenda, Ray, Debmalya, Hu, Jianzhi, Camaioni, Donald M., Wang, Huamin, Kim, Sungmin, Lee, Mal‐Soon, Sarazen, Michele L., Chen, Jingguang G., and Lercher, Johannes A.
- Subjects
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CARBENIUM ions , *HYDRIDES , *LOW density polyethylene , *ALKANES , *LEWIS acids , *POLYOLEFINS , *POLYETHYLENE , *ARYL chlorides - Abstract
Transforming polyolefin waste into liquid alkanes through tandem cracking‐alkylation reactions catalyzed by Lewis‐acid chlorides offers an efficient route for single‐step plastic upcycling. Lewis acids in dichloromethane establish a polar environment that stabilizes carbenium ion intermediates and catalyzes hydride transfer, enabling breaking of polyethylene C−C bonds and forming C−C bonds in alkylation. Here, we show that efficient and selective deconstruction of low‐density polyethylene (LDPE) to liquid alkanes is achieved with anhydrous aluminum chloride (AlCl3) and gallium chloride (GaCl3). Already at 60 °C, complete LDPE conversion was achieved, while maintaining the selectivity for gasoline‐range liquid alkanes over 70 %. AlCl3 showed an exceptional conversion rate of 5000 gLDPEmolcat-1h-1 ${{{\rm g}}_{{\rm L}{\rm D}{\rm P}{\rm E}}{{\rm \ }{\rm m}{\rm o}{\rm l}}_{{\rm c}{\rm a}{\rm t}}^{-1}{{\rm \ }{\rm h}}^{-1}}$ , surpassing other Lewis acid catalysts by two orders of magnitude. Through kinetic and mechanistic studies, we show that the rates of LDPE conversion do not correlate directly with the intrinsic strength of the Lewis acids or steric constraints that may limit the polymer to access the Lewis acid sites. Instead, the rates for the tandem processes of cracking and alkylation are primarily governed by the rates of initiation of carbenium ions and the subsequent intermolecular hydride transfer. Both jointly control the relative rates of cracking and alkylation, thereby determining the overall conversion and selectivity. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
6. Tuning aminopolycarboxylate chelators for efficient complexation of trivalent actinides.
- Author
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Pilgrim, Corey D., Grimes, Travis S., Smith, Clayn, Heathman, Colt R., Mathew, Jopaul, Jansone-Popova, Santa, Roy, Santanu, Ray, Debmalya, Bryantsev, Vyacheslav S., and Zalupski, Peter R.
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ACTINIDE elements , *MOLECULAR dynamics , *LIQUID-liquid extraction , *IONIC strength , *POLYETHYLENE glycol , *RARE earth metals - Abstract
The complexation of trivalent lanthanides and minor actinides (Am3+, Cm3+, and Cf3+) by the acyclic aminopolycarboxylate chelators 6,6′-((ethane-1,2-diylbis–((carboxymethyl)azanediyl))bis–(methylene))dipicolinic acid (H4octapa) and 6,6'-((((4-(1-(2-(2-(2-hydroxyethoxy)ethoxy)ethyl)-1H-1,2,3-triazol-4-yl)pyridine-2,6-diyl)bis–(methylene))bis–((carboxymethyl)azanediyl))bis–(methylene)) dipicolinic acid (H4pypa-peg) were studied using potentiometry, spectroscopy, competitive complexation liquid–liquid extraction, and ab initio molecular dynamics simulations. Two studied reagents are strong multidentate chelators, well-suited for applications seeking radiometal coordination for in-vivo delivery and f-element isolation. The previously reported H4octapa forms a compact coordination packet, while H4pypa-peg is less sterically constrained due to the presence of central pyridine ring. The solubility of H4octapa is limited in a non-complexing high ionic strength perchlorate media. However, the introduction of a polyethylene glycol group in H4pypa-peg increased the solubility without influencing its ability to complex the lanthanides and minor actinides in solution. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
7. Tuning aminopolycarboxylate chelators for efficient complexation of trivalent actinides.
- Author
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Pilgrim, Corey D., Grimes, Travis S., Smith, Clayn, Heathman, Colt R., Mathew, Jopaul, Jansone-Popova, Santa, Roy, Santanu, Ray, Debmalya, Bryantsev, Vyacheslav S., and Zalupski, Peter R.
- Subjects
- *
ACTINIDE elements , *MOLECULAR dynamics , *LIQUID-liquid extraction , *IONIC strength , *POLYETHYLENE glycol , *RARE earth metals - Abstract
The complexation of trivalent lanthanides and minor actinides (Am3+, Cm3+, and Cf3+) by the acyclic aminopolycarboxylate chelators 6,6′-((ethane-1,2-diylbis–((carboxymethyl)azanediyl))bis–(methylene))dipicolinic acid (H4octapa) and 6,6'-((((4-(1-(2-(2-(2-hydroxyethoxy)ethoxy)ethyl)-1H-1,2,3-triazol-4-yl)pyridine-2,6-diyl)bis–(methylene))bis–((carboxymethyl)azanediyl))bis–(methylene)) dipicolinic acid (H4pypa-peg) were studied using potentiometry, spectroscopy, competitive complexation liquid–liquid extraction, and ab initio molecular dynamics simulations. Two studied reagents are strong multidentate chelators, well-suited for applications seeking radiometal coordination for in-vivo delivery and f-element isolation. The previously reported H4octapa forms a compact coordination packet, while H4pypa-peg is less sterically constrained due to the presence of central pyridine ring. The solubility of H4octapa is limited in a non-complexing high ionic strength perchlorate media. However, the introduction of a polyethylene glycol group in H4pypa-peg increased the solubility without influencing its ability to complex the lanthanides and minor actinides in solution. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
8. Single-step conversion of ethanol into n-butene-rich olefins over metal catalysts supported on ZrO2-SiO2 mixed oxides.
- Author
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Dagle, Vanessa Lebarbier, Collinge, Gregory, Rahman, Mohammed, Winkelman, Austin, Hu, Wenda, Hu, Jian Zhi, Kovarik, Libor, Engelhard, Mark, Jocz, Jennifer, Wang, Yong, Lee, Mal-Soon, Glezakou, Vassiliki-Alexandra, Ray, Debmalya, Rousseau, Roger, and Dagle, Robert
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METAL catalysts , *CATALYST supports , *ETHANOL , *ALKENES , *ALUMINUM silicates , *JET fuel , *COPPER - Abstract
With airlines committed to drastically reduce their carbon footprint by 2050, producing jet fuel from renewable ethanol is of particular interest. Recently, we reported on an Ag/ZrO 2 /SBA-16 catalyst that is very effective for directly converting ethanol into to n-butene-rich olefins jet fuel precursors (i.e., 88% at full conversion). Here, we report on a Cu/ZrO 2 /SBA-16 catalyst that presents remarkable olefins selectivity (i.e., 89% at 96% conversion) and enhanced stability as compared to Ag/ZrO 2 /SBA-16 catalyst. Under severe operating conditions a conversion loss < 10% was observed with the Cu/ZrO 2 /SBA-16 catalyst as compared to a 50% loss of conversion with the Ag/ZrO 2 /SBA-16 catalyst. Combined experimental and computational tools revealed that replacing Ag with Cu shifts the reaction pathway of crotonaldehyde hydrogenation from 1,3-butadiene (i.e., coke precursor) production to butyraldehyde formation. Experiments conducted with 4%Cu/4%ZrO 2 supported on SBA-16, dealuminated zeolite Beta, and aluminum silicate revealed the performance and stability advantage of the SBA-16-supported catalyst. For direct conversion of ethanol to n-butene-rich olefins, replacing Ag with Cu shifts the reaction mechanism from crotonaldehyde hydrogenation to butadiene (coke precursor) to butyraldehyde formation resulting in improved catalyst stability. [Display omitted] • For direct conversion of ethanol to n-butene Cu/ZrO2/SBA-16 provides enhanced stability as compared to Ag/ZrO2/SBA-16. • Replacing Ag with Cu shifts the reaction pathway of crotonaldehyde hydrogenation from butadiene to butyraldehyde formation. • 89% olefins selectivity can be achieved at 96% conversion with 2% Cu/4%ZrO2/SBA-16 catalyst. • The SBA-16 supported catalyst benefits from a notable stability as compared to the dealuminated zeolite Beta supported one. • Cu/ZrO2/SBA-16 is also very effective for converting aldehydes directly into butenes-rich olefins. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
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