Results 221 to 230 of about 2,232,659 (281)
Predicting Atomic Charges in MOFs by Topological Charge Equilibration
Advanced Functional Materials, EarlyView.An atomic charge prediction method is presented that is able to accurately reproduce ab‐initio‐derived reference charges for a large number of metal–organic frameworks. Based on a topological charge equilibration scheme, static charges that fulfill overall neutrality are quickly generated.
Babak Farhadi Jahromi +2 more
wiley +1 more source
Advanced Functional Materials, EarlyView.This study presents a new hole transporting material (HTM) mechanism for self‐assembled monolayers in near‐infrared organic photodetectors. The formation of zwitterions induces a strong electric field that significantly increases the work function of HTM‐coated indium tin oxide substrates. The devices exhibit low dark current and noise, along with high
Jiyoung Shin +9 more
wiley +1 more source
Atomic‐Scale Light Coupling Control in Ultrathin Photonic Membranes
Advanced Functional Materials, EarlyView.Ultrathin photonic nanomembranes provide atomic‐scale control over the coupling between incident light and high‐Q photonic modes, enabling angstrom‐level resonance tuning and strong field confinement. When integrated with TMD monolayers, they further yield enhanced light–matter interactions, offering a versatile platform for advancing quantum photonics,
Chih‐Zong Deng +8 more
wiley +1 more source
Meta‐Rod Mechanical Metamaterials With Programmable Reconfiguration
Advanced Functional Materials, EarlyView.Existing mechanical metamaterials achieve programmable large deformations in planar square or cubic configurations, restricted by required complex boundary conditions. This research proposes a 1D metamaterial, Meta‐rod, with linear, bending, twisting, area, and volume deformation modes.
Atharva Pande, Lyes Kadem, Hang Xu
wiley +1 more source
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1992
Abstract It has already been shown in (1.1.23) in the Introduction how to use the Stein–Chen method for sums of independent random variables. In Section 2.3, the upper bounds so far derived are applied to dissociated indicator random variables.
A D Barbour, Lars Holst, Svante Janson
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Abstract It has already been shown in (1.1.23) in the Introduction how to use the Stein–Chen method for sums of independent random variables. In Section 2.3, the upper bounds so far derived are applied to dissociated indicator random variables.
A D Barbour, Lars Holst, Svante Janson
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How many minimal upper bounds of minimal upper bounds
Computing, 1996zbMATH Open Web Interface contents unavailable due to conflicting licenses.
openaire +2 more sources
2012
Plastic limit analysis is a convenient tool to find approximate solutions of boundary value problems. In general, this analysis is based on two principles associated with the lower bound and upper bound theorems. The latter is used in the present monograph to estimate the limit load for welded structures with and with no crack.
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Plastic limit analysis is a convenient tool to find approximate solutions of boundary value problems. In general, this analysis is based on two principles associated with the lower bound and upper bound theorems. The latter is used in the present monograph to estimate the limit load for welded structures with and with no crack.
openaire +1 more source
2002
In Chapter 2, we investigated techniques for proving size lower bounds for restricted classes of circuits (monotonic or constant depth) . Returning to the circuit synthesis problem of Chapter 1, recall that in Section 1.8.4, we showed an O(n) upper bound for circuit size for symmetric boolean functions f ∈ 𝓑 n .
Peter Clote, Evangelos Kranakis
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In Chapter 2, we investigated techniques for proving size lower bounds for restricted classes of circuits (monotonic or constant depth) . Returning to the circuit synthesis problem of Chapter 1, recall that in Section 1.8.4, we showed an O(n) upper bound for circuit size for symmetric boolean functions f ∈ 𝓑 n .
Peter Clote, Evangelos Kranakis
openaire +1 more source