Based on one ER model (<i>n</i> = 100, <i>ρ</i> = 0.0606), one WS model (<i>n</i> = 100, <i>K</i> = 6, <i>σ</i> = 0.2), and one BA model (<i>n</i> = 100, <i>M</i>₀ = 4,... by Xi Chen (35903)

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For 1,000 random y(0) on Karate network. by Xi Chen (35903)

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Based on three WS models with different rewiring probabilities (<i>n</i> = 100, <i>K</i> = 6, <i>σ</i> = 0.1, 0.3, 0.8). by Xi Chen (35903)

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<i>β</i>^<i>P</i> for real-world twitter datasets. by Xi Chen (35903)

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For 1,000 random y(0). by Xi Chen (35903)

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For a random opinion vector y(0) with mean −0.0395, on 1,000 ER models with <i>n</i> = 100 and <i>ρ</i> = 0.4. by Xi Chen (35903)

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For a random opinion vector y(0), on ER models with <i>n</i> = 100 and <i>ρ</i> ∈ (0,1]. by Xi Chen (35903)

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<i>x</i>₁(<i>t</i> + 1) as a function of <i>x</i>_2,3,4,5(<i>t</i>). by Xi Chen (35903)

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Add one edge on Karate network to change the consensus opinion—<i>β</i> = 1. by Xi Chen (35903)

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Table 1_Noble Humbug? Hard and soft laws on clinical placebo use.docx by Mélina Richard (20867453)

“…This study employs a multidisciplinary approach, analyzing both binding laws (“hard laws”) and non-binding principles (“soft laws”) related to placebo administration. …”

Nanoscale Origin of the Soft-to-Hard Short-Circuit Transition in Inorganic Solid-State Electrolytes by Chunyang Wang (500547)

“…For the first time, we directly visualize stochastic Li⁰ interconnection-induced soft short circuits, during which the SSEs undergo the transition from a nominal electronic insulator to a state exhibiting memristor-like nonlinear conduction (electronic leakages), ultimately evolving into hard short circuits. Furthermore, we first capture intragranular cracking caused by Li⁰ penetration, demonstrating that fully wetted Li⁰ can fracture polycrystalline oxide SSEs via a liquid-metal embrittlement-like mechanism. …”

Nanoscale Origin of the Soft-to-Hard Short-Circuit Transition in Inorganic Solid-State Electrolytes by Chunyang Wang (500547)

“…For the first time, we directly visualize stochastic Li⁰ interconnection-induced soft short circuits, during which the SSEs undergo the transition from a nominal electronic insulator to a state exhibiting memristor-like nonlinear conduction (electronic leakages), ultimately evolving into hard short circuits. Furthermore, we first capture intragranular cracking caused by Li⁰ penetration, demonstrating that fully wetted Li⁰ can fracture polycrystalline oxide SSEs via a liquid-metal embrittlement-like mechanism. …”

Nanoscale Origin of the Soft-to-Hard Short-Circuit Transition in Inorganic Solid-State Electrolytes by Chunyang Wang (500547)

“…For the first time, we directly visualize stochastic Li⁰ interconnection-induced soft short circuits, during which the SSEs undergo the transition from a nominal electronic insulator to a state exhibiting memristor-like nonlinear conduction (electronic leakages), ultimately evolving into hard short circuits. Furthermore, we first capture intragranular cracking caused by Li⁰ penetration, demonstrating that fully wetted Li⁰ can fracture polycrystalline oxide SSEs via a liquid-metal embrittlement-like mechanism. …”

Nanoscale Origin of the Soft-to-Hard Short-Circuit Transition in Inorganic Solid-State Electrolytes by Chunyang Wang (500547)

“…For the first time, we directly visualize stochastic Li⁰ interconnection-induced soft short circuits, during which the SSEs undergo the transition from a nominal electronic insulator to a state exhibiting memristor-like nonlinear conduction (electronic leakages), ultimately evolving into hard short circuits. Furthermore, we first capture intragranular cracking caused by Li⁰ penetration, demonstrating that fully wetted Li⁰ can fracture polycrystalline oxide SSEs via a liquid-metal embrittlement-like mechanism. …”

Nanoscale Origin of the Soft-to-Hard Short-Circuit Transition in Inorganic Solid-State Electrolytes by Chunyang Wang (500547)

“…For the first time, we directly visualize stochastic Li⁰ interconnection-induced soft short circuits, during which the SSEs undergo the transition from a nominal electronic insulator to a state exhibiting memristor-like nonlinear conduction (electronic leakages), ultimately evolving into hard short circuits. Furthermore, we first capture intragranular cracking caused by Li⁰ penetration, demonstrating that fully wetted Li⁰ can fracture polycrystalline oxide SSEs via a liquid-metal embrittlement-like mechanism. …”

Nanoscale Origin of the Soft-to-Hard Short-Circuit Transition in Inorganic Solid-State Electrolytes by Chunyang Wang (500547)

“…For the first time, we directly visualize stochastic Li⁰ interconnection-induced soft short circuits, during which the SSEs undergo the transition from a nominal electronic insulator to a state exhibiting memristor-like nonlinear conduction (electronic leakages), ultimately evolving into hard short circuits. Furthermore, we first capture intragranular cracking caused by Li⁰ penetration, demonstrating that fully wetted Li⁰ can fracture polycrystalline oxide SSEs via a liquid-metal embrittlement-like mechanism. …”

Nanoscale Origin of the Soft-to-Hard Short-Circuit Transition in Inorganic Solid-State Electrolytes by Chunyang Wang (500547)

“…For the first time, we directly visualize stochastic Li⁰ interconnection-induced soft short circuits, during which the SSEs undergo the transition from a nominal electronic insulator to a state exhibiting memristor-like nonlinear conduction (electronic leakages), ultimately evolving into hard short circuits. Furthermore, we first capture intragranular cracking caused by Li⁰ penetration, demonstrating that fully wetted Li⁰ can fracture polycrystalline oxide SSEs via a liquid-metal embrittlement-like mechanism. …”

Electroporation and knockdown efficiencies in “easy-to-transfect” vs. “hard-to-transfect” MM cell lines. by Torsten Steinbrunn (573455)

Increased inward turn is a result of slowing down and turning hard at the light border. by Liangyu Tao (6186941)

Effect of Protein-Based Treatment on Chemical Composition, Hardness and Bond Strength of Remineralized Enamel by Guilherme Genovez-Júnior (12791995)