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. …”

Effects of granule particle size and lubricant concentration on tablet hardness containing large concentration of polymers by 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. …”

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

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Hard Single-Molecule Magnet Behavior by a Linear Trinuclear Lanthanide–[1]Metallocenophane Complex by 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. by Rutger Hermsen (195605)

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

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

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Fig 8 - by Nimisha Ghosh (9637889)

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

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Fig 7 - by Nimisha Ghosh (9637889)

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Pipeline of the work. by 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. by 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. by Nimisha Ghosh (9637889)

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