[1]	Cussler E L, Moggridge G D. Chemical Product Design. 1st ed. Cambridge: Cambridge University Press, 2001, 1–416

[2]	Gani R. Chemical product design: challenges and opportunities. Computers & Chemical Engineering, 2004, 28: 2441–2457

[3]	Costa R, Moggridge G D, Saraiva P M. Chemical product engineering. An emerging paradigm within chemical engineering. AIChE Journal, 2006, 52: 1976–1986

[4]	Hill M. Chemical product engineering—the third paradigm. Computers & Chemical Engineering, 2009, 33: 947–953

[5]	Smith B V, Ierapepritou M G. Integrative chemical product design strategies: reflecting industry trends and challenges. Computers & Chemical Engineering, 2010, 34: 857–865

[6]	Ng K M, Gani R. Chemical product design: advances in and proposed directions for research and teaching. Computers & Chemical Engineering, 2019, 126: 147–156

[7]	Olson G B. Designing a new material world. Science, 2000, 288: 993–998

[8]	Wibowo C, Ng K M. Product-oriented process synthesis and development: creams and pastes. AIChE Journal, 2001, 47: 2746–2767

[9]	Wibowo C, Ng K M. Product-centered processing: manufacture of chemical-based consumer products. AIChE Journal, 2002, 48: 1212–1230

[10]	Ng K M, Gani R, Johansen K D. Chemical Product Design: Towards a Perspective Through Case Studies. 1st ed. Amsterdam: Elsevier, 2007, 165–490

[11]	Seider W D, Widagdo S, Seader J D, Lewin D R. Perspectives on chemical product and process design. Computers & Chemical Engineering, 2009, 33: 930–935

[12]	Smith B V, Ierapepritou M G. Framework for consumer-integrated optimal product design. Industrial & Engineering Chemistry Research, 2009, 48: 8566–8574

[13]	Gani R, Ng K M. Product design—molecules, devices, functional products, and formulated products. Computers & Chemical Engineering, 2015, 81: 70–79

[14]	Bernardo F P, Saraiva P M. A Conceptual model for chemical product design. AIChE Journal, 2015, 61: 802–815

[15]	Mattei M, Kontogeorgis G M, Gani R. A comprehensive framework for surfactant selection and design for emulsion based chemical product design. Fluid Phase Equilibria, 2014, 362: 288–299

[16]	Cheng Y S, Lam K W, Ng K M, Ko R K M, Wibowo C. An integrative approach to product development—a skin-care cream. Computers & Chemical Engineering, 2009, 33: 1097–1113

[17]	Bagajewicz M J. On the role of microeconomics, planning, and finances in product design. AIChE Journal, 2007, 53: 3155–3170

[18]	Fung K Y, Ng K M, Zhang L, Gani R. A grand model for chemical product design. Computers & Chemical Engineering, 2016, 91: 15–27

[19]	Zhang L, Fung K Y, Zhang X, Fung H K, Ng K M. An integrated framework for designing formulated products. Computers & Chemical Engineering, 2017, 107: 61–76

[20]	Chan Y C, Fung K Y, Ng K M. Product design: a pricing framework accounting for product quality and consumer awareness. AIChE Journal, 2018, 64: 2462–2471

[21]	Zhang X, Zhang L, Fung K Y, Rangaiah G P, Ng K M. Product design: impact of government policy and consumer preference on company profit and corporate social responsibility. Computers & Chemical Engineering, 2018, 118: 118–131

[22]	Zhang X, Zhang L, Fung K Y, Ng K M. Product design: incorporating make-or-buy analysis and supplier selection. Chemical Engineering Science, 2019, 202: 357–372

[23]	Torquato S. Random heterogeneous materials: microstructure and macroscopic properties. Interdisciplinary Applied Mathematics, 2002, 16: 1–656

[24]	Fullwood D T, Niezgoda S R, Adams B L, Kalidindi S R. Microstructure sensitive design for performance optimization. Progress in Materials Science, 2010, 55: 477–562

[25]	Brough D B, Wheeler D, Warren J A, Kalidindi S R. Microstructure-based knowledge systems for capturing process-structure evolution linkages. Current Opinion in Solid State and Materials Science, 2017, 21: 129–140

[26]	Cecen A, Dai H, Yabansu Y C, Kalidindi S R, Song L. Material structure-property linkages using three-dimensional convolutional neural networks. Acta Materialia, 2018, 146: 76–84

[27]	Bostanabad R, Zhang Y, Li X, Kearney T, Brinson L C, Apley D W, Liu W K, Chen W. Computational microstructure characterization and reconstruction: review of the state-of-the-art techniques. Progress in Materials Science, 2018, 95: 1–41

[28]	Mushtaq F. Computation-based microstructure design of structured chemical products. Dissertation for the Doctoral Degree. Hong Kong: The Hong Kong University of Science and Technology, 2020, 50–90

[29]

Lu D, Liu C, Lang X, Wang B, Li Z, Lee W M P, Lee S W R. Enhancement of thermal conductivity of die attach adhesive (DAAs) using nanomaterials for high brightness light emitting diode (HBLED). In: 2011 IEEE 61st Electronic Components and Technology Conference (ECTC), Lake Buena Vista, FL: IEEE, 2011, 667–672

[30]	Anandraj J, Joshi M G. Fabrication, performance and applications of integrated nanodielectric properties of materials: a review. Composite Interfaces, 2018, 25: 455–489

[31]	Muñoz V, Buffa F, Molinari F, Hermida L G, García J J, Abraham G A. Electrospun ethylcellulose-based nanofibrous mats with insect-repellent activity. Materials Letters, 2019, 253: 289–292

[32]	Cao L, Fu Q, Si Y, Ding B, Yu J. Porous materials for sound absorption. Composites Communications, 2018, 10: 25–35

[33]	Li G R, Wang L S, Yang G J. Achieving self-enhanced thermal barrier performance through a novel hybrid-layered coating design. Materials & Design, 2019, 167: 107647

[34]	Lee B, Liu J Z, Sun B, Shen C Y, Dai G C. Thermally conductive and electrically insulating EVA composite encapsulants for solar photovoltaic (PV) cell. Express Polymer Letters, 2008, 2: 357–363

[35]	Cui C H, Yan D X, Pang H, Xu X, Jia L C, Li Z M. Formation of a segregated electrically conductive network structure in a low-melt-viscosity polymer for highly efficient electromagnetic interference shielding. ACS Sustainable Chemistry & Engineering, 2016, 4: 4137–4145

[36]	Wang M, Zhang K, Dai X X, Li Y, Guo J, Liu H, Li G H, Tan Y J, Zeng J B, Guo Z. Enhanced electrical conductivity and piezoresistive sensing in multi-wall carbon nanotubes/polydimethylsiloxane nanocomposites via the construction of a self-segregated structure. Nanoscale, 2017, 9: 11017

[37]	Conte E, Gani R, Ng K M. Design of formulated products: a systematic methodology. AIChE Journal, 2011, 57: 2431–2449

[38]	Conte E, Gani R, Cheng Y S, Ng K M. Design of formulated products: experimental component. AIChE Journal, 2012, 58: 173–189

[39]	Zhang X, Zhou T, Zhang L, Fung K Y, Ng K M. Food product design: a hybrid machine learning and mechanistic modeling approach. Industrial & Engineering Chemistry Research, 2019, 58: 16743–16752

[40]	Király A, Ronkay F. Effect of filler dispersion on the electrical conductivity and mechanical properties of carbon/polypropylene composites. Polymer Composites, 2013, 34: 1195–1203

[41]	Fu S, Sun Z, Huang P, Li Y, Hu N. Some basic aspects of polymer nanocomposites: a critical review. Nano Materials Science, 2019, 1: 2–30

[42]	Yang X Y, Chen L H, Li Y, Rooke J R, Sanchezc C, Su B L. Hierarchically porous materials: synthesis strategies and structure design. Chemical Society Reviews, 2017, 46: 481–558

[43]	Slater A G, Cooper A I. Function-led design of new porous materials. Science, 2015, 348: aaa8075

[44]	Liu Q, Ye F, Gao Y, Liu S, Yang H, Zhou Z. Fabrication of a new SiC/2024Al co-continuous composite with lamellar microstructure and high mechanical properties. Journal of Alloys and Compounds, 2014, 585: 146–153

[45]	Pang H, Xu L, Yan D X, Li Z M. Conductive polymer composites with segregated structures. Progress in Polymer Science, 2014, 39: 1908–1933

[46]	Pang H, Chen C, Bao Y, Chen J, Ji X, Lei J, Li Z M. Electrically conductive carbon nanotube/ultrahigh molecular weight polyethylene composites with segregated and double percolated structure. Materials Letters, 2012, 79: 96–99

[47]	Wang M, Pan N. Predictions of effective physical properties of complex multiphase materials. Materials Science and Engineering, 2008, 63: 1–30

[48]	Nan C W, Birringer R, Clarke D R, Gleiter H. Effective thermal conductivity of particulate composites with interfacial thermal resistance. Journal of Applied Physics, 1997, 81: 6692–6699

[49]	Nan C W, Shi Z, Lin Y. A simple model for thermal conductivity of carbon nanotube-based composites. Chemical Physics Letters, 2003, 37: 666–669

[50]	Singh K J, Singh R, Chaudhary D R. Heat conduction and a porosity correction term for spherical and cubic particles in a simple cubic packing. Journal of Physics. D, Applied Physics, 1998, 31: 1681–1687

[51]	Carson J K, Lovatt S J, Tanner D J, Cleland A C. Thermal conductivity bounds for isotropic, porous materials. International Journal of Heat and Mass Transfer, 2005, 48: 2150–2158

[52]	Wang J F, Carson J K, North M F, Cleland D J. A new approach to modelling the effective thermal conductivity of heterogeneous materials. International Journal of Heat and Mass Transfer, 2006, 49: 3075–3083

[53]	Agari Y, Uno T. Estimation on thermal conductivities of filled polymers. Journal of Applied Polymer Science, 1986, 32: 5705–5712

[54]	Liang X G, Ji X. Thermal conductance of randomly oriented composites of thin layers. International Journal of Heat and Mass Transfer, 2000, 43: 3633–3640

[55]	Mushtaq F, Zhang X, Fung K Y, Ng K M. Product design: an optimization-based approach for targeting of particulate composite microstructure. Computers & Chemical Engineering, 2020, 140: doi:10.1016/j.compchemeng.2020.106975

[56]	Liu Y, Greene M S, Chen W, Dikin D A, Liu W K. Computational microstructure characterization and reconstruction for stochastic multiscale material design. Computer Aided Design, 2013, 45: 65–76

[57]	Mukherjee P P, Wang C Y. Stochastic microstructure reconstruction and direct numerical simulation of the PEFC catalyst layer. Journal of the Electrochemical Society, 2006, 153: A840–A849

[58]	Sheidaei A, Baniassadi M, Banu M, Askeland P, Pahlavanpour M, Kuuttila N, Pourboghrat F, Drzal L T, Garmestani H. 3-D microstructure reconstruction of polymer nano-composite using FIBSEM and statistical correlation function. Composites Science and Technology, 2013, 80: 47–54

[59]	Wu W, Jiang F. Microstructure reconstruction and characterization of PEMFC electrodes. International Journal of Hydrogen Energy, 2014, 39: 15894–15906

[60]	Derossi A, Gerke K M, Karsanina M V, Nicolai B, Verboven P, Severini C. Mimicking 3D food microstructure using limited statistical information from 2D cross-sectional image. Journal of Food Engineering, 2019, 241: 116–126

[61]	Xu H, Li Y, Brinson C, Chen W. A descriptor-based design methodology for developing heterogeneous microstructural materials system. Journal of Mechanical Design, 2014, 136: 051007

[62]	Zhang Y, Zhao H, Hassinger I, Brinson L C, Schadler L, Chen W. Microstructure reconstruction and structural equation modeling for computational design of nanodielectrics. Integrating Materials and Manufacturing Innovation, 2015, 4: 209–234

[63]	Hassinger I, Li X, Zhao H, Xu H, Huang Y, Prasad A, Schadler L, Chen W, Brinson L C. Toward the development of a quantitative tool for predicting dispersion of nanocomposites under non-equilibrium processing conditions. Journal of Materials Science, 2016, 51: 4238–4249

[64]	Lu W, Xiao R, Yang J, Li H, Zhang W. Data mining-aided materials discovery and optimization. Journal of Materiomics, 2017, 3: 191–201

[65]	Zhou T, Song Z, Sundmacher K. Big data creates new opportunities for materials research: a review on methods and applications of machine learning for materials design. Engineering, 2019, 5: 1017–1026

[66]	Gu G X, Chen C T, Richmond D J, Buehler M J. Bioinspired hierarchical composite design using machine learning: simulation, additive manufacturing, and experiment. Materials Horizons, 2018, 5: 939–945

[67]	Gu G H, Noh J, Kim I, Jung Y. Machine learning for renewable energy materials. Journal of Materials Chemistry. A, Materials for Energy and Sustainability, 2019, 7: 17096–17117

[68]	Besseris G J. Taguchi-generalized regression neural network micro-screening for physical and sensory characteristics of bread. Heliyon, 2018, 3: e00551

[69]	Bendsøe M P, Sigmund O. Topology Optimization: Theory, Methods, and Applications. 2nd ed. New York: Springer-Verlag Berlin Heidelberg, 2004, 1–318

[70]	Suzuki K, Kikuchi N. A homogenization method for shape and topology optimization. Computer Methods in Applied Mechanics and Engineering, 1991, 93: 291–318

[71]	Bendsøe M P, Sigmund O. Material interpolation schemes in topology optimization. Archive of Applied Mechanics, 1999, 69: 635–654

[72]	Xie Y M, Steven G P. A simple evolutionary procedure for structural optimization. Computers & Structures, 1993, 49: 885–896

[73]	Wang M Y, Wang X, Guo D. A level set method for structural topology optimization. Computer Methods in Applied Mechanics and Engineering, 2003, 192: 227–246

[74]	Murray W, Ng K M. An algorithm for nonlinear optimization problems with binary variables. Computational Optimization and Applications, 2010, 47: 257–288

[75]	Xia L, Breitkopf P. Multiscale structural topology optimization with an approximate constitutive model for local material microstructure. Computer Methods in Applied Mechanics and Engineering, 2015, 286: 147–167

[76]	Sigmund O, Maute K. Topology optimization approaches. Structural and Multidisciplinary Optimization, 2013, 48: 1031–1055

[77]	Zheng J, Luo Z, Li H, Jiang C. Robust topology optimization for cellular composites with hybrid uncertainties. International Journal for Numerical Methods in Engineering, 2018, 115: 695–713

[78]	Chu S, Gao L, Xia M, Li H. Design of sandwich panels with truss cores using explicit topology optimization. Composite Structures, 2019, 210: 892–905

[79]	Hu M, Feng J, Ng K M. Thermally conductive PP/AlN composites with a 3-D segregated structure. Composites Science and Technology, 2015, 110: 26–34

[80]	Adams B L, Henrie A, Henrie B, Lyon M, Kalidindi S R, Garmestani H. Microstructure-sensitive design of a compliant beam. Journal of the Mechanics and Physics of Solids, 2001, 49: 1639–1663

[81]	Tan D, Irwin P. Polymer Based Nanodielectric Composites, Advances in Ceramics—Electric and Magnetic Ceramics, Bioceramics, Ceramics and Environment. London: IntechOpen, 2011, 115–132

[82]	Lee D W, Yoo B R. Advanced silica/polymer composites: materials and applications. Journal of Industrial and Engineering Chemistry, 2016, 38: 1–12

[83]	Yu Z Q, You S L, Baier H. Effect of organosilane coupling agents on microstructure and properties of nanosilica/epoxy composites. Polymer Composites, 2012, 33: 1516–1524

[84]	Tanaka T, Montanari G C, Mülhaupt R. Polymer nanocomposites as dielectrics and electrical insulation-perspectives for processing technologies, material characterization and future applications. IEEE Transactions on Dielectrics and Electrical Insulation, 2004, 11: 763–784

[85]	Cai Z, Wang X, Luo B, Hong W, Wu L, Li L. Dielectric response and breakdown behavior of polymer-ceramic nanocomposites: the effect of nanoparticle distribution. Composites Science and Technology, 2017, 145: 105–113

[86]	Sarami M A, Moghadam M, Gilani A G. Modified dielectric permittivity models for binary liquid mixture. Journal of Molecular Liquids, 2019, 277: 546–555

[87]	Bellucci F, Fabiani D, Montanari G C, Testa L. The processing of nanocomposites. In: Dielectric Polymer Nanocomposites. New York: Springer Science and Business Media, 2010, 31–64

[88]	Seider W D, Lewin D R, Seader J D, Widegado S, Gani R, Ng K M. Product and Process Design Principles: Synthesis, Analysis and Evaluation. 4th ed. New York: Wiley, 2017, 674–681

[89]	Romero A S, Chen B. Strategies for the preparation of polymer composites with complex alignment of the dispersed phase. Nanocomposites, 2018, 4: 137–155