| 1 | Bridging the gap: A novel approach for predicting the Young's modulus of nanodiamond polymer composites | 5.0 | 9 | Citations (PDF) |
| 2 | Simulation of tensile strength for polymer hydroxyapatite nanocomposites by interphase and nanofiller dimensions | 5.0 | 26 | Citations (PDF) |
| 3 | Predicting the strength in hydroxyapatite‐filled nanocomposites through advanced two‐phase modeling | 5.0 | 14 | Citations (PDF) |
| 4 | A modified version of conventional Halpin-Tsai model for the tensile modulus of polymer halloysite nanotube nanocomposites by filler network and nearby interphase | 3.2 | 12 | Citations (PDF) |
| 5 | Graphene-Based Electrochemical Biosensors for Breast Cancer Detection | 5.0 | 79 | Citations (PDF) |
| 6 | Simulating Electrical Conductivity of Graphene-Filled System by Developing McLachlan Model Applicable to Breast Cancer Biosensors | 2.0 | 0 | Citations (PDF) |
| 7 | Significances of effective interphase characteristics on the Pukanszky interfacial factor and strength of halloysite-containing composites after mechanical percolation onset | 3.2 | 3 | Citations (PDF) |
| 8 | Effective DC Conductivity of Polymer Composites Containing Graphene Nanosheets | 2.0 | 4 | Citations (PDF) |
| 9 | Synthesis of Fe-Doped Peroxidase Mimetic Nanozymes from Natural Hemoglobin for Colorimetric Biosensing and In Vitro Anticancer Effects | 5.0 | 6 | Citations (PDF) |
| 10 | Influences of Tunneling Distance and Interphase Size on the Conductivity of Graphene-Filled Nanomaterials | 2.0 | 1 | Citations (PDF) |
| 11 | Effect of interphase region on the Young's modulus of polymer nanocomposites reinforced with cellulose nanocrystals | 3.2 | 10 | Citations (PDF) |
| 12 | A review on polymeric nanocomposites for the electrochemical sensing of breast cancer biomarkers | 4.7 | 8 | Citations (PDF) |
| 13 | Percolation onset and conductivity of nanocomposites assuming an incomplete dispersion of graphene nanosheets in a polymer matrix | 2.7 | 1 | Citations (PDF) |
| 14 | A model for tensile modulus of halloysite-nanotube-based samples assuming the distribution and networking of both nanoparticles and interphase zone after mechanical percolation | 3.8 | 6 | Citations (PDF) |
| 15 | Formulation of interfacial parameter in Kolarik model by aspect ratio of carbon nanotubes and interfacial shear strength to simulate the tensile strength of carbon‐nanotube‐based systems | 5.0 | 1 | Citations (PDF) |
| 16 | Tensile modulus of halloysite-nanotube-based system assuming the defective interfacial bonding between polymer medium and halloysite nanotube | 4.3 | 1 | Citations (PDF) |
| 17 | Expansion of Takayanagi model by interphase characteristics and filler size to approximate the tensile modulus of halloysite-nanotube-filled system | 6.2 | 22 | Citations (PDF) |
| 18 | Progressing of Kovacs model for conductivity of graphene-filled products by total contact resistance and actual filler amount | 2.6 | 2 | Citations (PDF) |
| 19 | Interfacial stress transfer factor and tensile strength of polymer halloysite nanotubes systems | 5.0 | 3 | Citations (PDF) |
| 20 | Simple models for tensile modulus of shape memory polymer nanocomposites at ambient temperature | 5.6 | 5 | Citations (PDF) |
| 21 | Development of a model for modulus of polymer halloysite nanotube nanocomposites by the interphase zones around dispersed and networked nanotubes | 3.5 | 26 | Citations (PDF) |
| 22 | A simple model for gas barrier performance of polymer nanocomposites considering filler alignment angle and diffusion direction | 8.8 | 12 | Citations (PDF) |
| 23 | Advanced Kolarik model for the modulus of a nanocomposite system reinforced by halloysite nanotubes and interphase zone | 5.0 | 6 | Citations (PDF) |
| 24 | Effect of contact resistance on the electrical conductivity of polymer graphene nanocomposites to optimize the biosensors detecting breast cancer cells | 3.5 | 32 | Citations (PDF) |
| 25 | Advanced model for conductivity estimation of graphene-based samples considering interphase effect, tunneling mechanism, and filler wettability | 5.8 | 5 | Citations (PDF) |
| 26 | Two-Stage Modeling of Tensile Strength for a Carbon-Nanotube-Based System Applicable in the Biomedical Field | 2.0 | 10 | Citations (PDF) |
| 27 | Osteogenesis capability of three-dimensionally printed poly(lactic acid)-halloysite nanotube scaffolds containing strontium ranelate | 5.6 | 29 | Citations (PDF) |
| 28 | Intelligent modeling and optimization of titanium surface etching for dental implant application | 3.5 | 11 | Citations (PDF) |
| 29 | Development of a theoretical model for estimating the electrical conductivity of a polymeric system reinforced with silver nanowires applicable for the biosensing of breast cancer cells | 6.2 | 21 | Citations (PDF) |
| 30 | The least length of halloysite nanotubes allowing the operative stress shifting via imperfect interphase after percolation onset for the strength of nanocomposites applicable in the biomedical products | 5.0 | 0 | Citations (PDF) |
| 31 | Modeling of mechanical behaviors and interphase properties of polymer/nanodiamond composites for biomedical products | 6.2 | 35 | Citations (PDF) |
| 32 | Progression of <scp>O</scp>uali model by the strengthening and percolating efficacies of interphase for polymer halloysite nanotubes composites applicable in the biomedical products | 5.0 | 4 | Citations (PDF) |
| 33 | Crucial interfacial shear strength to consider an imperfect interphase in halloysite-nanotube-filled biomedical samples | 6.2 | 11 | Citations (PDF) |
| 34 | Effective Conductivity of Carbon-Nanotube-Filled Systems by Interfacial Conductivity to Optimize Breast Cancer Cell Sensors | 4.0 | 1 | Citations (PDF) |
| 35 | Tensile Modulus of Polymer Halloysite Nanotube Systems Containing Filler–Interphase Networks for Biomedical Requests | 2.9 | 3 | Citations (PDF) |
| 36 | Advancement of the Power-Law Model and Its Percolation Exponent for the Electrical Conductivity of a Graphene-Containing System as a Component in the Biosensing of Breast Cancer | 4.6 | 7 | Citations (PDF) |
| 37 | Simulation of Tensile Strength for Halloysite Nanotube-Filled System | 2.0 | 5 | Citations (PDF) |
| 38 | Modeling of Electrical Conductivity for Graphene-Filled Products Assuming Interphase, Tunneling Effect, and Filler Agglomeration Optimizing Breast Cancer Biosensors | 2.9 | 6 | Citations (PDF) |
| 39 | Modeling of Electrical Conductivity for Polymer–Carbon Nanofiber Systems | 2.9 | 10 | Citations (PDF) |
| 40 | Minimum Halloysite Length for Efficient Load Transfer Through the Interphase of Polymer Nanocomposites in Biomedical Applications | 2.0 | 4 | Citations (PDF) |
| 41 | A Review on Non-Enzymatic Electrochemical Biosensors of Glucose Using Carbon Nanofiber Nanocomposites | 5.0 | 50 | Citations (PDF) |
| 42 | An overview of the plant-mediated green synthesis of noble metal nanoparticles for antibacterial applications | 5.8 | 189 | Citations (PDF) |
| 43 | Electrical conductivity of interphase zone in polymer nanocomposites by carbon nanotubes properties and interphase depth | 2.7 | 8 | Citations (PDF) |
| 44 | Biosensing Applications of Polyaniline (PANI)-Based Nanocomposites: A Review | 14.3 | 138 | Citations (PDF) |
| 45 | Formulation of tunneling resistance between neighboring carbon nanotubes in polymer nanocomposites | 2.6 | 9 | Citations (PDF) |
| 46 | A rapid nanobiosensing platform based on herceptin-conjugated graphene for ultrasensitive detection of circulating tumor cells in early breast cancer | 5.6 | 37 | Citations (PDF) |
| 47 | Reduced graphene oxide-grafted bovine serum albumin/bredigite nanocomposites with high mechanical properties and excellent osteogenic bioactivity for bone tissue engineering | 6.6 | 27 | Citations (PDF) |
| 48 | Development of Ji Micromechanics Model for Electrical Conductivity of Carbon Nanotubes-reinforced Samples | 2.0 | 1 | Citations (PDF) |
| 49 | Micromechanics Modeling of Electrical Conductivity for Polymer Nanocomposites by Network Portion, Interphase Depth, Tunneling Properties and Wettability of Filler by Polymer Media | 2.0 | 2 | Citations (PDF) |
| 50 | Development and simplification of a micromechanic model for conductivity of carbon nanotubes-reinforced nanocomposites | 2.5 | 1 | Citations (PDF) |
| 51 | Advanced Models for Modulus and Strength of Carbon-Nanotube-Filled Polymer Systems Assuming the Networks of Carbon Nanotubes and Interphase Section | 2.1 | 3 | Citations (PDF) |
| 52 | A two-step technique established by simple models to estimate the tensile strength of halloysite nanotubes-filled nanocomposites | 5.5 | 2 | Citations (PDF) |
| 53 | Simulation of tensile strength for halloysite nanotubes/polymer composites | 5.6 | 13 | Citations (PDF) |
| 54 | Simulation of relaxation time and storage modulus for carbon nanotubes-based nanocomposites | 6.2 | 4 | Citations (PDF) |
| 55 | Effect of Imperfect Interphase Section Neighboring Dispersed and Networked Nanoclay on the Modulus of Nanocomposites by a Modeling Method | 2.0 | 0 | Citations (PDF) |
| 56 | Local delivery of chemotherapeutic agent in tissue engineering based on gelatin/graphene hydrogel | 6.2 | 33 | Citations (PDF) |
| 57 | Modification of advanced Takayanagi model for the modulus of nanoclay/polymer systems comprising the effectual networks of both nanoclay and interphase section | 2.7 | 1 | Citations (PDF) |
| 58 | Effects of interfacial shear strength on the operative aspects of interphase section and tensile strength of carbon-nanotube-filled system: A modeling study | 4.2 | 3 | Citations (PDF) |
| 59 | Development of Jang–Yin model for effectual conductivity of nanocomposite systems by simple equations for the resistances of carbon nanotubes, interphase and tunneling section | 2.7 | 14 | Citations (PDF) |
| 60 | Tensile modulus of clay‐reinforced system supposing the interphase effectiveness for load transferring | 5.0 | 5 | Citations (PDF) |
| 61 | Micromechanics simulation of electrical conductivity for carbon-nanotube-filled polymer system by adjusting Ouali model | 2.7 | 10 | Citations (PDF) |
| 62 | Modeling of Stress Relaxation Modulus for a Nanocomposite Biosensor by Relaxation Time, Yield Stress, and Zero Complex Viscosity | 2.0 | 6 | Citations (PDF) |
| 63 | Tensile strength of carbon‐nanotube‐based nanocomposites by the effective characteristics of interphase area nearby the filler network | 5.0 | 14 | Citations (PDF) |
| 64 | A hybrid approach for in-situ synthesis of bioceramic nanocomposites to adjust the physicochemical and biological characteristics | 6.2 | 9 | Citations (PDF) |
| 65 | Development of an advanced Takayanagi equation for the electrical conductivity of carbon nanotube-reinforced polymer nanocomposites | 4.7 | 3 | Citations (PDF) |
| 66 | The interphase degradation in a nanobiosensor including biopolymers and carbon nanotubes | 4.5 | 3 | Citations (PDF) |
| 67 | An applicable model for the modulus of polymer halloysite nanotubes samples by the characteristics of halloysite nanotubes, interphase zone and filler/interphase network | 5.2 | 10 | Citations (PDF) |
| 68 | Percolation onset and electrical conductivity for a multiphase system containing carbon nanotubes and nanoclay | 6.2 | 25 | Citations (PDF) |
| 69 | A simple model for determining the strength of polymer halloysite nanotube systems | 12.8 | 9 | Citations (PDF) |
| 70 | The strengthening efficacy of filler/interphase network in polymer halloysite nanotubes system after mechanical percolation | 6.2 | 19 | Citations (PDF) |
| 71 | Tuning of a mechanics model for the electrical conductivity of CNT-filled samples assuming extended CNT | 2.7 | 1 | Citations (PDF) |
| 72 | Significances of interphase conductivity and tunneling resistance on the conductivity of carbon nanotubes nanocomposites | 5.0 | 90 | Citations (PDF) |
| 73 | Simulation of Percolation Threshold, Tunneling Distance, and Conductivity for Carbon Nanotube (CNT)-Reinforced Nanocomposites Assuming Effective CNT Concentration | 4.6 | 32 | Citations (PDF) |
| 74 | Effects of CNT size, network fraction, and interphase thickness on the tunneling distance between neighboring carbon nanotubes (CNTs) in nanocomposites | 5.8 | 18 | Citations (PDF) |
| 75 | Modeling the effect of interfacial conductivity between polymer matrix and carbon nanotubes on the electrical conductivity of nanocomposites | 4.4 | 9 | Citations (PDF) |
| 76 | Effect of conductivity transportation from carbon nanotubes (CNT) to polymer matrix surrounding CNT on the electrical conductivity of nanocomposites | 5.0 | 10 | Citations (PDF) |
| 77 | Role of critical interfacial shear modulus between polymer matrix and carbon nanotubes in the tensile modulus of polymer nanocomposites | 3.7 | 8 | Citations (PDF) |
| 78 | Experimental data and modeling of electrical conductivity for polymer carbon nanotubes nanobiosensor during degradation in neutral phosphate-buffered saline (PBS) | 4.3 | 4 | Citations (PDF) |
| 79 | Tensile modulus prediction of carbon nanotubes-reinforced nanocomposites by a combined model for dispersion and networking of nanoparticles | 6.2 | 70 | Citations (PDF) |
| 80 | Interfacial factors affecting the strengthening efficacy of nanoclay in nanocomposites | 7.7 | 5 | Citations (PDF) |
| 81 | Advancement of a model for electrical conductivity of polymer nanocomposites reinforced with carbon nanotubes by a known model for thermal conductivity | 4.0 | 6 | Citations (PDF) |
| 82 | Polymer tunneling resistivity between adjacent carbon nanotubes (CNT) in polymer nanocomposites | 4.7 | 8 | Citations (PDF) |
| 83 | Development of Conventional Paul Model for Tensile Modulus of Polymer Carbon Nanotube Nanocomposites After Percolation Threshold by Filler Network Density | 2.0 | 16 | Citations (PDF) |
| 84 | Simulation of Young’s modulus for clay-reinforced nanocomposites assuming mechanical percolation, clay-interphase networks and interfacial linkage | 6.2 | 31 | Citations (PDF) |
| 85 | Effects of critical interfacial shear strength between polymer and nanoclay on the Pukanszky's “B” interphase factor and tensile strength of polymer nanocomposites | 3.7 | 3 | Citations (PDF) |
| 86 | Estimation of average contact number of carbon nanotubes (CNTs) in polymer nanocomposites to optimize the electrical conductivity | 4.0 | 0 | Citations (PDF) |
| 87 | Expression of characteristic tunneling distance to control the electrical conductivity of carbon nanotubes-reinforced nanocomposites | 6.2 | 18 | Citations (PDF) |
| 88 | Experimental data and modeling of storage and loss moduli for a biosensor based on polymer nanocomposites | 4.2 | 10 | Citations (PDF) |
| 89 | A simulation study for tunneling conductivity of carbon nanotubes (CNT) reinforced nanocomposites by the coefficient of conductivity transferring amongst nanoparticles and polymer medium | 4.2 | 7 | Citations (PDF) |
| 90 | Two-Stage Simulation of Tensile Modulus of Carbon Nanotube (CNT)-Reinforced Nanocomposites After Percolation Onset Using the Ouali Approach | 2.0 | 9 | Citations (PDF) |
| 91 | Effect of interfacial/interphase conductivity on the electrical conductivity of polymer carbon nanotubes nanocomposites | 4.0 | 9 | Citations (PDF) |
| 92 | Modeling of interphase strength between polymer host and clay nanoparticles in nanocomposites by clay possessions and interfacial/interphase terms | 5.6 | 11 | Citations (PDF) |
| 93 | Model Progress for Tensile Power of Polymer Nanocomposites Reinforced with Carbon Nanotubes by Percolating Interphase Zone and Network Aspects | 4.6 | 3 | Citations (PDF) |
| 94 | Effects of critical interfacial shear modulus between polymer matrix and nanoclay on the effective interphase properties and tensile modulus of nanocomposites | 7.7 | 16 | Citations (PDF) |
| 95 | Modeling the Effects of Filler Network and Interfacial Shear Strength on the Mechanical Properties of Carbon Nanotube-Reinforced Nanocomposites | 2.0 | 9 | Citations (PDF) |
| 96 | An overview on the synthesis and recent applications of conducting poly(3,4-ethylenedioxythiophene) (PEDOT) in industry and biomedicine | 3.5 | 86 | Citations (PDF) |
| 97 | A facile and simple approach to synthesis and characterization of methacrylated graphene oxide nanostructured polyaniline nanocomposites | 5.6 | 39 | Citations (PDF) |
| 98 | Correlation of tunneling diameter between neighboring carbon nanotubes in polymer nanocomposites to interphase depth, tunneling factors and the percentage of networked nanoparticles | 4.7 | 9 | Citations (PDF) |
| 99 | Calculation of tunneling distance in carbon nanotubes nanocomposites: effect of carbon nanotube properties, interphase and networks | 3.5 | 21 | Citations (PDF) |
| 100 | Simulation of tensile modulus of polymer carbon nanotubes nanocomposites in the case of incomplete interfacial bonding between polymer matrix and carbon nanotubes by critical interfacial parameters | 4.2 | 9 | Citations (PDF) |
| 101 | Definition of “b” exponent and development of power-law model for electrical conductivity of polymer carbon nanotubes nanocomposites | 4.2 | 6 | Citations (PDF) |
| 102 | Simulation of tunneling distance and electrical conductivity for polymer carbon nanotubes nanocomposites by interphase thickness and network density | 5.0 | 7 | Citations (PDF) |
| 103 | Interphase thickness and electrical conductivity of polymer carbon nanotube (CNT) nanocomposites assuming the interfacial conductivity between polymer matrix and nanoparticles | 3.5 | 5 | Citations (PDF) |
| 104 | Analysis of critical interfacial shear strength between polymer matrix and carbon nanotubes and its impact on the tensile strength of nanocomposites | 6.2 | 28 | Citations (PDF) |
| 105 | Calculation of the Electrical Conductivity of Polymer Nanocomposites Assuming the Interphase Layer Surrounding Carbon Nanotubes | 4.6 | 37 | Citations (PDF) |
| 106 | Study on the Effects of the Interphase Region on the Network Properties in Polymer Carbon Nanotube Nanocomposites | 4.6 | 29 | Citations (PDF) |
| 107 | Development of Expanded Takayanagi Model for Tensile Modulus of Carbon Nanotubes Reinforced Nanocomposites Assuming Interphase Regions Surrounding the Dispersed and Networked Nanoparticles | 4.6 | 12 | Citations (PDF) |
| 108 | Effects of carbon nanotubes and interphase properties on the interfacial conductivity and electrical conductivity of polymer nanocomposites | 3.4 | 4 | Citations (PDF) |
| 109 | Effects of network, tunneling, and interphase properties on the operative tunneling resistance in polymer carbon nanotubes (<scp>CNTs</scp>) nanocomposites | 5.0 | 6 | Citations (PDF) |
| 110 | Effects of critical interfacial shear strength between a polymer matrix and carbon nanotubes on the interphase strength and Pukanszky's “<i>B</i>” interphase parameter | 4.4 | 4 | Citations (PDF) |
| 111 | Analysis of the Connecting Effectiveness of the Interphase Zone on the Tensile Properties of Carbon Nanotubes (CNT) Reinforced Nanocomposite | 4.6 | 16 | Citations (PDF) |
| 112 | A simple and sensible equation for interphase potency in carbon nanotubes (CNT) reinforced nanocomposites | 6.2 | 16 | Citations (PDF) |
| 113 | An experimental study on one-step and two-step foaming of natural rubber/silica nanocomposites | 5.6 | 25 | Citations (PDF) |
| 114 | A highly sensitive biosensor based on methacrylated graphene oxide-grafted polyaniline for ascorbic acid determination | 5.6 | 51 | Citations (PDF) |
| 115 | Microfluidic-assisted synthesis and modelling of monodispersed magnetic nanocomposites for biomedical applications | 5.6 | 21 | Citations (PDF) |
| 116 | Modeling of viscosity and complex modulus for poly (lactic acid)/poly (ethylene oxide)/carbon nanotubes nanocomposites assuming yield stress and network breaking time | 12.8 | 73 | Citations (PDF) |
| 117 | Simplification and development of McLachlan model for electrical conductivity of polymer carbon nanotubes nanocomposites assuming the networking of interphase regions | 12.8 | 81 | Citations (PDF) |
| 118 | Simple model for hydrolytic degradation of poly(lactic acid)/poly(ethylene oxide)/carbon nanotubes nanobiosensor in neutral phosphate‐buffered saline solution | 4.3 | 27 | Citations (PDF) |
| 119 | Evaluation of the Tensile Strength in Carbon Nanotube-Reinforced Nanocomposites Using the Expanded Takayanagi Model | 2.0 | 74 | Citations (PDF) |
| 120 | Modeling the roles of carbon nanotubes and interphase dimensions in the conductivity of nanocomposites | 4.2 | 74 | Citations (PDF) |
| 121 | Following the morphological and thermal properties of PLA/PEO blends containing carbon nanotubes (CNTs) during hydrolytic degradation | 12.8 | 90 | Citations (PDF) |
| 122 | Explanation of main tunneling mechanism in electrical conductivity of polymer/carbon nanotubes nanocomposites by interphase percolation | 3.2 | 10 | Citations (PDF) |
| 123 | A Simulation Work for the Influences of Aggregation/Agglomeration of Clay Layers on the Tensile Properties of Nanocomposites | 2.0 | 80 | Citations (PDF) |
| 124 | Tensile strength prediction of carbon nanotube reinforced composites by expansion of cross-orthogonal skeleton structure | 12.8 | 79 | Citations (PDF) |
| 125 | Effects of interphase regions and tunneling distance on the electrical conductivity of polymer carbon nanotubes nanocomposites | 4.9 | 4 | Citations (PDF) |
| 126 | The complex viscosity of polymer carbon nanotubes nanocomposites as a function of networks properties | 4.9 | 3 | Citations (PDF) |
| 127 | A developed equation for electrical conductivity of polymer carbon nanotubes (CNT) nanocomposites based on Halpin-Tsai model | 4.2 | 71 | Citations (PDF) |
| 128 | Degradation biosensing performance of polymer blend carbon nanotubes (CNTs) nanocomposites | 4.5 | 15 | Citations (PDF) |
| 129 | Effects of interphase regions and filler networks on the viscosity of PLA/PEO/carbon nanotubes biosensor | 5.0 | 79 | Citations (PDF) |
| 130 | Analysis of complex viscosity and shear thinning behavior in poly (lactic acid)/poly (ethylene oxide)/carbon nanotubes biosensor based on Carreau–Yasuda model | 4.2 | 132 | Citations (PDF) |
| 131 | A multistep methodology for effective conductivity of carbon nanotubes reinforced nanocomposites | 6.0 | 42 | Citations (PDF) |
| 132 | Prediction of loss factor (tan δ) for polymer nanocomposites as a function of yield tress, relaxation time and the width of transition region between Newtonian and power-law behaviors | 3.4 | 21 | Citations (PDF) |
| 133 | The effective conductivity of polymer carbon nanotubes (CNT) nanocomposites | 4.7 | 80 | Citations (PDF) |
| 134 | Expression of normal stress difference and relaxation modulus for ternary nanocomposites containing biodegradable polymers and carbon nanotubes by storage and loss modulus data | 12.8 | 79 | Citations (PDF) |
| 135 | A modeling methodology to investigate the effect of interfacial adhesion on the yield strength of MMT reinforced nanocomposites | 5.8 | 83 | Citations (PDF) |
| 136 | The roles of interphase and filler dimensions in the properties of tunneling spaces between CNT in polymer nanocomposites | 5.0 | 83 | Citations (PDF) |
| 137 | Effect of “<i>Z</i>” factor for strength of interphase layers on the tensile strength of polymer nanocomposites | 5.0 | 72 | Citations (PDF) |
| 138 | A model for the tensile modulus of polymer nanocomposites assuming carbon nanotube networks and interphase zones | 2.3 | 4 | Citations (PDF) |
| 139 | Variations of tunneling properties in poly (lactic acid) (PLA)/poly (ethylene oxide) (PEO)/carbon nanotubes (CNT) nanocomposites during hydrolytic degradation | 4.5 | 75 | Citations (PDF) |
| 140 | A new methodology based on micromechanics model to predict the tensile modulus and network formation in polymer/CNT nanocomposites | 5.2 | 7 | Citations (PDF) |
| 141 | Dependence of mechanical performances of polymer/carbon nanotubes nanocomposites on percolation threshold | 2.8 | 74 | Citations (PDF) |
| 142 | A simple model for constant storage modulus of poly (lactic acid)/poly (ethylene oxide)/carbon nanotubes nanocomposites at low frequencies assuming the properties of interphase regions and networks | 3.4 | 75 | Citations (PDF) |
| 143 | Prediction of complex modulus in phase-separated poly (lactic acid)/poly (ethylene oxide)/carbon nanotubes nanocomposites | 5.5 | 36 | Citations (PDF) |
| 144 | The percolation threshold for tensile strength of polymer/CNT nanocomposites assuming filler network and interphase regions | 4.5 | 83 | Citations (PDF) |
| 145 | A multistep methodology based on developed Takayanagi, Paul and Ouali models for tensile modulus of polymer/carbon nanotubes nanocomposites above percolation threshold assuming the contribution of interphase regions | 5.5 | 19 | Citations (PDF) |
| 146 | Structural and phase separation characterization of poly(lactic acid)/poly(ethylene oxide)/carbon nanotube nanocomposites by rheological examinations | 12.8 | 78 | Citations (PDF) |
| 147 | A simple model for electrical conductivity of polymer carbon nanotubes nanocomposites assuming the filler properties, interphase dimension, network level, interfacial tension and tunneling distance | 8.8 | 82 | Citations (PDF) |
| 148 | Analysis of the roles of interphase, waviness and agglomeration of CNT in the electrical conductivity and tensile modulus of polymer/CNT nanocomposites by theoretical approaches | 5.2 | 80 | Citations (PDF) |
| 149 | A model for tensile strength of polymer/carbon nanotubes nanocomposites assuming the percolation of interphase regions | 5.2 | 80 | Citations (PDF) |
| 150 | Roles of filler dimensions, interphase thickness, waviness, network fraction, and tunneling distance in tunneling conductivity of polymer CNT nanocomposites | 4.5 | 26 | Citations (PDF) |
| 151 | Tensile modulus of polymer/CNT nanocomposites containing networked and dispersed nanoparticles | 3.7 | 7 | Citations (PDF) |
| 152 | A multistep methodology for calculation of the tensile modulus in polymer/carbon nanotube nanocomposites above the percolation threshold based on the modified rule of mixtures | 4.4 | 79 | Citations (PDF) |
| 153 | Predicting the electrical conductivity in polymer carbon nanotube nanocomposites based on the volume fractions and resistances of the nanoparticle, interphase, and tunneling regions in conductive networks | 4.4 | 77 | Citations (PDF) |
| 154 | Considering the filler network as a third phase in polymer/CNT nanocomposites to predict the tensile modulus using Hashin-Hansen model | 2.8 | 9 | Citations (PDF) |
| 155 | Prediction of storage modulus in solid-like poly (lactic acid)/poly (ethylene oxide)/carbon nanotubes nanocomposites assuming the contributions of nanoparticles and interphase regions in the networks | 3.4 | 30 | Citations (PDF) |
| 156 | Estimation of the tensile modulus of polymer carbon nanotube nanocomposites containing filler networks and interphase regions by development of the Kolarik model | 4.4 | 36 | Citations (PDF) |
| 157 | A power model to predict the electrical conductivity of CNT reinforced nanocomposites by considering interphase, networks and tunneling condition | 12.8 | 78 | Citations (PDF) |
| 158 | Development of Hashin-Shtrikman model to determine the roles and properties of interphases in clay/CaCO3/PP ternary nanocomposite | 5.6 | 79 | Citations (PDF) |
| 159 | Evaluation of nanoparticle dispersion and its influence on the tensile modulus of polymer nanocomposites by a modeling method | 2.1 | 16 | Citations (PDF) |
| 160 | Accounting the reinforcing efficiency and percolating role of interphase regions in tensile modulus of polymer/CNT nanocomposites | 5.9 | 79 | Citations (PDF) |
| 161 | Influences of nanoparticles aggregation/agglomeration on the interfacial/interphase and tensile properties of nanocomposites | 12.8 | 297 | Citations (PDF) |
| 162 | Predictions of Takayanagi model for tensile modulus of polymer/CNT nanocomposites by properties of nanoparticles and filler network | 2.1 | 3 | Citations (PDF) |
| 163 | Effects of pseudoinclusions containing intercalated Mt platelets on the tensile modulus and strength of Mt/polymer nanocomposites | 5.6 | 1 | Citations (PDF) |
| 164 | Development of a conventional model to predict the electrical conductivity of polymer/carbon nanotubes nanocomposites by interphase, waviness and contact effects | 8.2 | 88 | Citations (PDF) |
| 165 | Efficiency of stress transfer between polymer matrix and nanoplatelets in clay/polymer nanocomposites | 5.6 | 80 | Citations (PDF) |
| 166 | Tensile modulus of polymer/CNT nanocomposites by effective volume fraction of nanoparticles as a function of CNT properties in the network | 3.3 | 6 | Citations (PDF) |
| 167 | The mechanical behavior of CNT reinforced nanocomposites assuming imperfect interfacial bonding between matrix and nanoparticles and percolation of interphase regions | 8.8 | 83 | Citations (PDF) |
| 168 | Prediction of tensile modulus in polymer nanocomposites containing carbon nanotubes (CNT) above percolation threshold by modification of conventional model | 2.7 | 85 | Citations (PDF) |
| 169 | A two-step model for the tunneling conductivity of polymer carbon nanotube nanocomposites assuming the conduction of interphase regions | 4.4 | 78 | Citations (PDF) |
| 170 | Mathematical Simplification of the Tandon–Weng Approach to the Mori–Tanaka Model for Estimating the Young’s Modulus of Clay/Polymer Nanocomposites | 2.0 | 4 | Citations (PDF) |
| 171 | Predictions of micromechanics models for interfacial/interphase parameters in polymer/metal nanocomposites | 3.4 | 78 | Citations (PDF) |
| 172 | The reinforcing and characteristics of interphase as the polymer chains adsorbed on the nanoparticles in polymer nanocomposites | 2.1 | 12 | Citations (PDF) |
| 173 | A two-step technique for tensile strength of montmorillonite/polymer nanocomposites assuming filler morphology and interphase properties | 5.6 | 16 | Citations (PDF) |
| 174 | Development and modification of conventional Ouali model for tensile modulus of polymer/carbon nanotubes nanocomposites assuming the roles of dispersed and networked nanoparticles and surrounding interphases | 9.9 | 77 | Citations (PDF) |
| 175 | Theoretical characterization of interphase properties in polymer nanocomposites | 2.1 | 7 | Citations (PDF) |
| 176 | A simple methodology to predict the tunneling conductivity of polymer/CNT nanocomposites by the roles of tunneling distance, interphase and CNT waviness | 4.4 | 78 | Citations (PDF) |
| 177 | Development of a Model for Electrical Conductivity of Polymer/Graphene Nanocomposites Assuming Interphase and Tunneling Regions in Conductive Networks | 3.9 | 75 | Citations (PDF) |
| 178 | Multistep modeling of Young’s modulus in polymer/clay nanocomposites assuming the intercalation/exfoliation of clay layers and the interphase between polymer matrix and nanoparticles | 8.2 | 82 | Citations (PDF) |
| 179 | Expansion of Kolarik model for tensile strength of polymer particulate nanocomposites as a function of matrix, nanoparticles and interphase properties | 9.9 | 20 | Citations (PDF) |
| 180 | Evaluation of Mechanical Properties in Nanocomposites Containing Carbon Nanotubes Below and Above Percolation Threshold | 2.0 | 6 | Citations (PDF) |
| 181 | An approach to study the roles of percolation threshold and interphase in tensile modulus of polymer/clay nanocomposites | 9.9 | 76 | Citations (PDF) |
| 182 | A Two‐Step Method Based on Micromechanical Models to Predict the Young's Modulus of Polymer Nanocomposites | 4.1 | 40 | Citations (PDF) |
| 183 | Development of cubic orthogonal skeleton or three perpendicular plates system for prediction of Young’s modulus in polymer nanocomposites assuming the interphase | 2.1 | 8 | Citations (PDF) |
| 184 | Shear, Bulk, and Young’s Moduli of Clay/Polymer Nanocomposites Containing the Stacks of Intercalated Layers as Pseudoparticles | 3.9 | 16 | Citations (PDF) |
| 185 | Effects of imperfect interfacial adhesion between polymer and nanoparticles on the tensile modulus of clay/polymer nanocomposites | 5.6 | 89 | Citations (PDF) |
| 186 | Simple expressions of bulk and shear moduli of polymer/clay nanocomposites by Tandon–Weng approach assuming 3D randomly oriented platelets | 2.6 | 1 | Citations (PDF) |
| 187 | The roles of nanoparticles accumulation and interphase properties in properties of polymer particulate nanocomposites by a multi-step methodology | 8.2 | 89 | Citations (PDF) |
| 188 | A model for tensile strength of polymer/clay nanocomposites assuming complete and incomplete interfacial adhesion between the polymer matrix and nanoparticles by the average normal stress in clay platelets | 4.4 | 81 | Citations (PDF) |
| 189 | Development of Nicolais–Narkis model for yield strength of polymer nanocomposites reinforced with spherical nanoparticles | 3.4 | 43 | Citations (PDF) |
| 190 | Modeling the yield strength of polymer nanocomposites based upon nanoparticle agglomeration and polymer–filler interphase | 9.9 | 78 | Citations (PDF) |
| 191 | Polymer/metal nanocomposites for biomedical applications | 5.8 | 258 | Citations (PDF) |
| 192 | Modeling the strength and thickness of the interphase in polymer nanocomposite reinforced with spherical nanoparticles by a coupling methodology | 9.9 | 74 | Citations (PDF) |
| 193 | Development of Halpin-Tsai model for polymer nanocomposites assuming interphase properties and nanofiller size | 5.5 | 112 | Citations (PDF) |
| 194 | Modeling approach for tensile strength of interphase layers in polymer nanocomposites | 9.9 | 81 | Citations (PDF) |
| 195 | Study of nanoparticles aggregation/agglomeration in polymer particulate nanocomposites by mechanical properties | 8.2 | 501 | Citations (PDF) |
| 196 | “ a ” interfacial parameter in Nicolais–Narkis model for yield strength of polymer particulate nanocomposites as a function of material and interphase properties | 9.9 | 81 | Citations (PDF) |
| 197 | Study on interfacial properties in polymer blend ternary nanocomposites: Role of nanofiller content | 3.2 | 76 | Citations (PDF) |
| 198 | Assumption of interphase properties in classical Christensen–Lo model for Young's modulus of polymer nanocomposites reinforced with spherical nanoparticles | 4.4 | 81 | Citations (PDF) |
| 199 | Thickness, modulus and strength of interphase in clay/polymer nanocomposites | 5.6 | 86 | Citations (PDF) |
| 200 | New models for yield strength of polymer/clay nanocomposites | 12.8 | 85 | Citations (PDF) |
| 201 | Modeling of tensile modulus in polymer/carbon nanotubes (CNT) nanocomposites | 4.5 | 74 | Citations (PDF) |
| 202 | A developed model to assume the interphase properties in a ternary polymer nanocomposite reinforced with two nanofillers | 12.8 | 80 | Citations (PDF) |
| 203 | Effects of interphase on tensile strength of polymer/CNT nanocomposites by Kelly–Tyson theory | 3.7 | 149 | Citations (PDF) |
| 204 | Estimation of material and interfacial/interphase properties in clay/polymer nanocomposites by yield strength data | 5.6 | 83 | Citations (PDF) |
| 205 | A simple technique for determination of interphase properties in polymer nanocomposites reinforced with spherical nanoparticles | 4.2 | 84 | Citations (PDF) |
| 206 | An analysis of interfacial adhesion in nanocomposites from recycled polymers | 3.2 | 74 | Citations (PDF) |
| 207 | Determination of polymer–nanoparticles interfacial adhesion and its role in shape memory behavior of shape memory polymer nanocomposites | 3.4 | 80 | Citations (PDF) |
| 208 | Modeling of interfacial bonding between two nanofillers (montmorillonite and CaCO3) and a polymer matrix (PP) in a ternary polymer nanocomposite | 6.7 | 83 | Citations (PDF) |
| 209 | Recent progress on preparation and properties of nanocomposites from recycled polymers: A review | 7.2 | 145 | Citations (PDF) |
| 210 | Analysis of tensile modulus of PP/nanoclay/CaCO<sub>3</sub> ternary nanocomposite using composite theories | 2.7 | 74 | Citations (PDF) |
| 211 | Nonisothermal crystallization and melting behavior of PP/nanoclay/CaCO<sub>3</sub> ternary nanocomposite | 2.7 | 73 | Citations (PDF) |
| 212 | Optimization of mechanical properties of PP/Nanoclay/CaCO<sub>3</sub> ternary nanocomposite using response surface methodology | 2.7 | 94 | Citations (PDF) |
