Combustion, Chemistry, and Carbon Neutrality

Kohse‐Höinghaus, Katharina

doi:10.1021/acs.chemrev.2c00828

Cited by 48 publications

(18 citation statements)

References 734 publications

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“…It is also essential in the separation of materials that are critical for our technological society, such as the rare earth elements. − Heavy Element Chemistry: The f -elements that appear at the bottom of the periodic table (lanthanides and actinides) are relevant for technologies related to energy and national security. f -electron systems are characterized by the simultaneous presence of itinerant (delocalized) and highly localized states and interactions between them. ,− While lanthanide chemistry can be mostly understood by studying the impact of changing the size of the metal atom to tune the properties of a molecular complex, actinides do not exhibit the same periodic trends, a fact that requires the use of advanced electronic structure methods beyond mean-field approaches and accurate treatments of relativistic and correlation effects. , Gas Phase Chemistry: − Most energy production processes involve combustion, a gas-phase chemical process even with liquid and solid fuels; those fuels may be either renewable (e.g., biofuels) or nonrenewable (e.g., fossil fuels). In addition to energy production, the characterizations of soot formation, nitrogen oxides, and other reaction products are also important to a broad range of scientific challenges. Strong Field Physics: Strong field interactions between ultrafast intense fields (attosecond pulses) and matter has led to a plethora of new physical phenomena, such as multiphoton ionization, above-threshold ionization, nonsequential double ionization, high harmonic generation, attosecond pulse generation, coherent X-ray generation, etc.…”

Section: Scientific Challenges and Discoveriesmentioning

confidence: 99%

“…Gas Phase Chemistry: − Most energy production processes involve combustion, a gas-phase chemical process even with liquid and solid fuels; those fuels may be either renewable (e.g., biofuels) or nonrenewable (e.g., fossil fuels). In addition to energy production, the characterizations of soot formation, nitrogen oxides, and other reaction products are also important to a broad range of scientific challenges.…”

Section: Scientific Challenges and Discoveriesmentioning

confidence: 99%

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A Perspective on Sustainable Computational Chemistry Software Development and Integration

Di Felice,

Mayes,

Richard

et al. 2023

J. Chem. Theory Comput.

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The power of quantum chemistry to predict the ground and excited state properties of complex chemical systems has driven the development of computational quantum chemistry software, integrating advances in theory, applied mathematics, and computer science. The emergence of new computational paradigms associated with exascale technologies also poses significant challenges that require a flexible forward strategy to take full advantage of existing and forthcoming computational resources. In this context, the sustainability and interoperability of computational chemistry software development are among the most pressing issues. In this perspective, we discuss software infrastructure needs and investments with an eye to fully utilize exascale resources and provide unique computational tools for next-generation science problems and scientific discoveries.

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Section: Scientific Challenges and Discoveriesmentioning

confidence: 99%

Section: Scientific Challenges and Discoveriesmentioning

confidence: 99%

A Perspective on Sustainable Computational Chemistry Software Development and Integration

Di Felice,

Mayes,

Richard

et al. 2023

J. Chem. Theory Comput.

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“…The increasing greenhouse effect has made carbon neutrality a global concern. , Although using solar energy to convert CO 2 into carbon-based fuels holds significant potential for sustainable development, it is fraught with great challenges. − Formic acid (HCOOH) is one of the most highly productive base chemicals compared with C 2+ fuels and is considered more readily and widely applicable for industrial implementation. , Over the past decades, various electrochemical, , photochemical, , and photoelectrochemical , strategies have been extensively explored for converting CO 2 to HCOOH. However, these strategies have certain disadvantages owing to their low selectivity and inefficiency .…”

Section: Introductionmentioning

confidence: 99%

Photoenzymatic CO₂ Reduction Dominated by Collaborative Matching of Linkage and Linker in Covalent Organic Frameworks

Chen,

Wang,

Luo

2023

J. Am. Chem. Soc.

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Artificial photoenzymatic systems based on covalent organic frameworks (COFs) provide an interesting platform for converting CO 2 to value-added fuels. However, the dual roles of COFs as photocatalysts and enzyme hosts showcase contradictory preferences for structures, which poses a great challenge for their rational design. Herein, we report the collaborative matching of linkages and linkers in COFs on their ability to exert both photocatalytic activity and enzyme loading, which has been neglected until now. The linkage-dependent linker regulation pattern was elucidated, and the optimal match showed a record-breaking apparent quantum efficiency at 420 nm for photocatalytic cofactor regeneration of 13.95% with a high turnover frequency of 5.3 mmol g −1 h −1 , outperforming other reported crystalline framework photocatalysts. Moreover, theoretical calculations and experiments revealed the mechanism underlying the effects of matching the linkage and linker on exciton dissociation and charge migration in photocatalysis. This newfound understanding enabled the construction of COFs with both high photoactivity and large pores closer in size to the formate dehydrogenase, achieving high loading capacity and a suitable confinement effect. Remarkably, the artificial photoenzymatic system constructed according to optimal linkage-linker matching exhibited highly efficient CO 2 reduction, yielding formic acid with a specific activity as high as 1.46 mmol g −1 catalyst h −1 and good reusability, paving the way for sustainable CO 2 conversion driven by visible light.

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“…The intensifying global concerns regarding global warming and energy scarcity have prompted a vigorous surge in carbon neutrality initiatives. [1] However, the current lithiumion batteries, due to limitations such as the scarcity of lithium resources and the flammability of organic electrolytes, are unsuitable for cost-effective and large-scale green energy harvesting. [2] In contrast, rechargeable mild aqueous batteries (RMABs) have garnered increasing attention for their exceptional traits of high safety, affordability, and environmental friendliness.…”

Section: Introductionmentioning

confidence: 99%

Proton/Mg²⁺ Co‐Insertion Chemistry in Aqueous Mg‐Ion Batteries: From the Interface to the Inner

Huang,

Wang,

Wang

et al. 2023

Angew Chem Int Ed

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Co‐insertion of protons happens widely and enables divalent‐ion aqueous batteries to achieve high performances. However, detailed investigations and comprehensive understandings of proton co‐insertion are scarce. Herein, we demonstrate that proton co‐insertion into tunnel materials is determined jointly by interface derivation and inner diffusion: at the interface, hdrated Mg2+ has poor insertion kinetics, and therefore accumulates and hydrolyzes to produce protons; in the tunnels, co‐inserted/lattice H2O molecules block the Mg2+ diffusion while facilitate the proton diffusion. When monoclinic vanadium dioxide (VO2(B)) anode is tested in Mg(CH3COO)2 aqueous solution, the formation of Mg‐rich solid electrolyte interphase on the VO2(B) electrode and co‐insertion of derived protons are probed; in the tunnels, the diffusion energy barrier of Mg2++H2O is 2.7 eV, while that of the protons is 0.37 eV. Thus, protons dominate the subsequent insertion and inner diffusion. As a consequence, the VO2(B) achieves a high capacity of 257.0 mAh g−1 at 1 A g−1, a high rate retention of 59.1 % from 1 to 8 A g−1, and stable cyclability of 3000 times with a capacity retention of 81.5 %. This work provides an in‐depth understanding of the proton co‐insertion and may promote the development of rechargeable aqueous batteries.

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Combustion, Chemistry, and Carbon Neutrality

Cited by 48 publications

References 734 publications

A Perspective on Sustainable Computational Chemistry Software Development and Integration

A Perspective on Sustainable Computational Chemistry Software Development and Integration

Photoenzymatic CO₂ Reduction Dominated by Collaborative Matching of Linkage and Linker in Covalent Organic Frameworks

Proton/Mg²⁺ Co‐Insertion Chemistry in Aqueous Mg‐Ion Batteries: From the Interface to the Inner

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Combustion, Chemistry, and Carbon Neutrality

Cited by 48 publications

References 734 publications

A Perspective on Sustainable Computational Chemistry Software Development and Integration

A Perspective on Sustainable Computational Chemistry Software Development and Integration

Photoenzymatic CO2 Reduction Dominated by Collaborative Matching of Linkage and Linker in Covalent Organic Frameworks

Proton/Mg2+ Co‐Insertion Chemistry in Aqueous Mg‐Ion Batteries: From the Interface to the Inner

Contact Info

Product

Resources

About

Photoenzymatic CO₂ Reduction Dominated by Collaborative Matching of Linkage and Linker in Covalent Organic Frameworks

Proton/Mg²⁺ Co‐Insertion Chemistry in Aqueous Mg‐Ion Batteries: From the Interface to the Inner