Shi-Qing Wang

What is he best known for?

The fields of study he is best known for:

• Polymer
• Thermodynamics
• Composite material

Slip, Mechanics, Polymer, Shear and Mineralogy are his primary areas of study. His Slip research includes themes of Rheology, Capillary action, Polymer adsorption and Surface energy. Shi-Qing Wang studies Mechanics, focusing on Shear flow in particular.

His biological study spans a wide range of topics, including Critical resolved shear stress and Shear stress. His Polymer study incorporates themes from Stress relaxation, Relaxation rate, Oscillatory shear and Shearing. Shi-Qing Wang has researched Shear in several fields, including Creep, Flow birefringence and Shear rate.

His most cited work include:

• Investigating linear and nonlinear viscoelastic behavior using model silica-particle-filled polybutadiene (184 citations)
• Exploring molecular origins of sharkskin, partial slip, and slope change in flow curves of linear low density polyethylene (145 citations)
• New theoretical considerations in polymer rheology: Elastic breakdown of chain entanglement network (128 citations)

What are the main themes of his work throughout his whole career to date?

The scientist’s investigation covers issues in Polymer, Composite material, Shear, Rheology and Mechanics. His Polymer study combines topics in areas such as Stress, Thermodynamics and Polymer chemistry. His Shear research also works with subjects such as

• Shear rate that connect with fields like Shear modulus,
• Classical mechanics which connect with Amplitude.

His Rheology study frequently involves adjacent topics like Viscoelasticity. Shi-Qing Wang interconnects Stress relaxation, Reptation and Mineralogy in the investigation of issues within Mechanics. Shi-Qing Wang has included themes like Die swell, Sharkskin, Capillary action and Surface energy in his Slip study.

He most often published in these fields:

• Polymer (53.47%)
• Composite material (31.02%)
• Shear (25.31%)

What were the highlights of his more recent work (between 2017-2021)?

• Polymer (53.47%)
• Composite material (31.02%)
• Brittleness (6.53%)

In recent papers he was focusing on the following fields of study:

Shi-Qing Wang spends much of his time researching Polymer, Composite material, Brittleness, Polystyrene and Rheology. His work carried out in the field of Polymer brings together such families of science as Shear, Polymer science, Polymer chemistry and Deformation. His Shear research is multidisciplinary, incorporating elements of Creep, Reduced viscosity, Shear thinning and Velocimetry.

His work on Crystallinity, Compression and Ductility as part of general Composite material research is frequently linked to Molecular dynamics, bridging the gap between disciplines. His Polystyrene research includes elements of Stress and Deformation. His research in Rheology intersects with topics in Chemical physics, Mechanics and Theoretical physics.

Between 2017 and 2021, his most popular works were:

• Why Is Crystalline Poly(lactic acid) Brittle at Room Temperature (17 citations)
• Nonlinear Polymer Rheology: Macroscopic Phenomenology and Molecular Foundation (11 citations)
• Illustrating the Molecular Origin of Mechanical Stress in Ductile Deformation of Polymer Glasses (9 citations)

In his most recent research, the most cited papers focused on:

• Polymer
• Thermodynamics
• Composite material

His primary areas of study are Polymer, Composite material, Brittleness, Polystyrene and Deformation. His study in Polymer is interdisciplinary in nature, drawing from both Shear and Nanocomposite. The concepts of his Shear study are interwoven with issues in Nonlinear rheology, Reduced viscosity, Wall slip, Polymer chemistry and Polymer solution.

His work deals with themes such as Volume fraction, Compression, Molar mass distribution and Molar mass, which intersect with Brittleness. His Polystyrene study frequently links to other fields, such as Methyl methacrylate. He studied Deformation and Crazing that intersect with Necking, Work, Fracture, Amorphous solid and Ultimate tensile strength.

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