Table 1_Noble Humbug? Hard and soft laws on clinical placebo use.docx av 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 av 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 av 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 av 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 av 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 av 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 av 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 av 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. …”

Synthesis, Crystal Structure, Stability, and Mechanical Properties of the Hexagonal Tungsten Nitride WN_1−δ av Xuefeng Zhou (28696)

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Effects of granule particle size and lubricant concentration on tablet hardness containing large concentration of polymers av Chauhan Rajani (4830822)

“…The work involves optimization of a milling process for size reduction of granules and blending process to achieve tablets of good hardness on compression. …”

Hard Single-Molecule Magnet Behavior by a Linear Trinuclear Lanthanide–[1]Metallocenophane Complex av Trevor P. Latendresse (4102234)

“…A synthetic protocol was developed that involves the transmetalation of a mono-dysprosium–[1]­ferro­cenophane complex with DyX₃ (X = Cl^– or I^–) to afford [Dy₃Fc₆Li₂­(THF)₂]⁻, featuring a rare linear arrangement of magnetically anisotropic Dy³⁺ ions. …”

Mutations are required to maintain defectors. av Rutger Hermsen (195605)

Characteristics of non-synonymous hotspot mutations for spatial analysis. av Nimisha Ghosh (9637889)

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List of top 10 hotspot mutations based on spatial analysis. av Nimisha Ghosh (9637889)

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Fig 8 - av Nimisha Ghosh (9637889)

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List of top 10 hotspot mutations based on temporal analysis. av Nimisha Ghosh (9637889)

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Fig 7 - av Nimisha Ghosh (9637889)

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Pipeline of the work. av Nimisha Ghosh (9637889)

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Illustration of amino acid changes in SARS-CoV-2 proteins for the temporal and spatial non-synonymous hotspot mutations. av Nimisha Ghosh (9637889)

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Month wise (temporal) entropy of Indian SARS-CoV-2 genomes to show the changes in non-synonymous hotspot mutations. av Nimisha Ghosh (9637889)

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