Systematic Study of Aluminum Nanoclusters and Anion Adsorbates

Abstract: The interactions between aqueous aluminum (Al) nanoclusters and ions in solution influence the reactivity of nanomaterials in natural waters and are crucial to the targeted syntheses of aluminum oxides. To contribute to the fundamental understanding of how both anion and Al-nanocluster properties affect the interactions, we carry out systematic modeling studies that employ density functional theory calculations embedded in a continuum solvent model. Energetic and electronic structure analysis is applied toward… Show more

“…As done previously, we calculated changes in the Mulliken population(Dq m ) of the sulfate before and after adsorption and relate the results to deprotonation events. [20] Of the four e-Keggin interactions, only Site-1 sulfate interactions with e-GeAl 12 (Table S6 and Figure 3) result in deprotonation and an associated Dq m value greater than 0.50 e. All other interactions have Dq m values of less than 0.50 e and did not exhibit deprotonation, similar to previous observations on Keggin-anion interactions. [3c, 15, 20] To bridge the understanding between isomers and heteroatom identity for condensation reactions, we also assessed the d-isomers for GeAl 12 and Al 13 using the sulfate anion as our probe adsorbate (Table S7 and Figure S8).…”

“…When modeled as isolated clusters, the DFT calculations do not yield evidence of site‐specific acidic groups on the cluster surface. However, as done in previous studies, a strong base probe molecule can be used to elicit perturbations to cluster functional groups and ultimately identify labile protons [20] . Specifically, outer‐sphere adsorption modeled in different locations above the cluster surface can induce deprotonation of certain functional groups over the course of geometry optimization, thus identifying relatively labile protons.…”

“…In Site‐2, the sulfate anion can engage with a mixture of η 1 ‐H 2 O and μ 2 ‐OH groups on the surface of one Al 3 (OH) 6 (H 2 O) 3 trimer unit. As done previously, we calculated changes in the Mulliken population(Δ q m ) of the sulfate before and after adsorption and relate the results to deprotonation events [20] . Of the four ϵ‐Keggin interactions, only Site‐1 sulfate interactions with ϵ‐GeAl 12 (Table S6 and Figure 3) result in deprotonation and an associated Δ q m value greater than 0.50 e. All other interactions have Δ q m values of less than 0.50 e and did not exhibit deprotonation, similar to previous observations on Keggin‐anion interactions [3c, 15, 20] …”

“…However, as done in previous studies, a strong base probe molecule can be used to elicit perturbations to cluster functional groups and ultimately identify labile protons. [20] Specifically, outer-sphere adsorption modeled in different locations above the cluster surface can induce deprotonation of certain functional groups over the course of geometry optimization, thus identifying relatively labile protons. We hypothesize that if functional groups at specific locations on the cluster surface have a greater tendency to deprotonate, as revealed by the adsorbate probe modeling, then that could enable tridecamer units to connect through those sites and explain the formation of this tetramer.…”

Formation of Nanoscale [Ge₄O₁₆Al₄₈(OH)₁₀₈(H₂O)₂₄]²⁰⁺ from Condensation of ϵ‐GeAl₁₂⁸⁺ Keggin Polycations**

“…As done previously, we calculated changes in the Mulliken population(Dq m ) of the sulfate before and after adsorption and relate the results to deprotonation events. [20] Of the four e-Keggin interactions, only Site-1 sulfate interactions with e-GeAl 12 (Table S6 and Figure 3) result in deprotonation and an associated Dq m value greater than 0.50 e. All other interactions have Dq m values of less than 0.50 e and did not exhibit deprotonation, similar to previous observations on Keggin-anion interactions. [3c, 15, 20] To bridge the understanding between isomers and heteroatom identity for condensation reactions, we also assessed the d-isomers for GeAl 12 and Al 13 using the sulfate anion as our probe adsorbate (Table S7 and Figure S8).…”

“…When modeled as isolated clusters, the DFT calculations do not yield evidence of site‐specific acidic groups on the cluster surface. However, as done in previous studies, a strong base probe molecule can be used to elicit perturbations to cluster functional groups and ultimately identify labile protons [20] . Specifically, outer‐sphere adsorption modeled in different locations above the cluster surface can induce deprotonation of certain functional groups over the course of geometry optimization, thus identifying relatively labile protons.…”

“…In Site‐2, the sulfate anion can engage with a mixture of η 1 ‐H 2 O and μ 2 ‐OH groups on the surface of one Al 3 (OH) 6 (H 2 O) 3 trimer unit. As done previously, we calculated changes in the Mulliken population(Δ q m ) of the sulfate before and after adsorption and relate the results to deprotonation events [20] . Of the four ϵ‐Keggin interactions, only Site‐1 sulfate interactions with ϵ‐GeAl 12 (Table S6 and Figure 3) result in deprotonation and an associated Δ q m value greater than 0.50 e. All other interactions have Δ q m values of less than 0.50 e and did not exhibit deprotonation, similar to previous observations on Keggin‐anion interactions [3c, 15, 20] …”

“…However, as done in previous studies, a strong base probe molecule can be used to elicit perturbations to cluster functional groups and ultimately identify labile protons. [20] Specifically, outer-sphere adsorption modeled in different locations above the cluster surface can induce deprotonation of certain functional groups over the course of geometry optimization, thus identifying relatively labile protons. We hypothesize that if functional groups at specific locations on the cluster surface have a greater tendency to deprotonate, as revealed by the adsorbate probe modeling, then that could enable tridecamer units to connect through those sites and explain the formation of this tetramer.…”

Formation of Nanoscale [Ge₄O₁₆Al₄₈(OH)₁₀₈(H₂O)₂₄]²⁰⁺ from Condensation of ϵ‐GeAl₁₂⁸⁺ Keggin Polycations**

“…Al is also widely used in formulations of propellants and explosives; thus, it is of great importance to explore its reactions with energetic molecules. 25 Ammunition composed of TATB and aluminum powder shows excellent performance. To understand the interaction mode of TATB/Al systems, comprehensive knowledge about the interface and electronic structure of the system is necessary.…”

Dissociative adsorption modes of TATB on the Al (111) surface: a DFT investigation

Formation of Nanoscale [Ge₄O₁₆Al₄₈(OH)₁₀₈(H₂O)₂₄]²⁰⁺ from Condensation of ϵ‐GeAl₁₂⁸⁺ Keggin Polycations**