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210  1$aPiscataway, NJ :$cIEEE,$d[2017]
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200 10$aSustainable process engineering $econcepts, strategies, evaluation and implementation /$fby David Brennan
205   $aFirst edition.
210  1$aSingapore :$cPan Stanford Publishing, an imprint of Pan Stanford,$d2012.
215   $a1 online resource (417 p.)
300   $aDescription based upon print version of record.
311   $a981-4316-78-4 
320   $aIncludes bibliographical references.
327   $aFront Cover; Contents; Acknowledgements; Preface; PART A: CONCEPTS; Introduction to Part A; 1. Sustainability Concepts; 2. Cleaner Production; 3. Industrial Ecology; PART B: STRATEGIES; Introduction to Part B; 4. Waste Minimisation in Reactors; 5. Waste Minimisation in Separation Processes; 6. Identification of Waste in Utility Systems; 7. Energy Conservation; 8. Materials Recycling; 9. Waste Minimisation in Operations; PART C: EVALUATION; 10. Life Cycle Assessment; 11. Life Cycle Assessment Case Studies; 12. Safety Evaluation; 13. Assessment of Costs and Economics
327   $a14. Sustainability AssessmentPART D: IMPLEMENTATION; 15. Planning for Sustainable Process Industries; 16. Process Design and Project Development; 17. Operations Management; Back Cover
330 3 $aThis book introduces chemical engineering students to key concepts, strategies, and evaluation methods in sustainable process engineering. The book is intended to supplement chemical engineering texts in fundamentals and design, rather than replace them. The key objectives of the book are to widen system boundaries beyond a process plant to include utility supplies, interconnected plants, wider industry sectors, and entire product life cycles; identify waste and its sources in process and utility systems and adopt waste minimization strategies; broaden evaluation to include technical, economic, safety, environmental, social, and sustainability criteria and to integrate the assessments; and broaden the engineering horizon to incorporate planning, development, design, and operations.
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200 10$aStochastic Differential Equations for Chemical Transformations in White Noise Probability Space $eWick Products and Computations /$fby Don Kulasiri
205   $a1st ed. 2024.
210  1$aSingapore :$cSpringer Nature Singapore :$cImprint: Springer,$d2024.
215   $a1 online resource (181 pages)
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327   $aChapter 1. Introduction to Chemical transformations in far from equilibrium systems -- Chapter 2. A brief introduction to vectors spaces: succinct but pertinent summary for scientists -- Chapter 3. White noise probability spaces (Hermite polynomials and functions and their use in defining Weiner Chaos expansion) -- Chapter 4. Introduction to Skorohod integration and Malliavian derivatives?practical interpretations -- Chapter 5. Introduction to Wick Product and its algebra (analytical solutions to Wick product driven stochastic differential equations; Hermite transformations) -- Chapter 6. Numerical solutions to stochastic chemical reactions -- Chapter 7. Stochastic coupled reactions systems: Numerical solutions -- Chapter 8. Modelling chiral symmetry breaking and stability in a noisy environment using Wick products?A case study.
330   $aThis book highlights the applications of stochastic differential equations in white noise probability space to chemical reactions that occur in biology. These reactions operate in fluctuating environments and are often coupled with each other. The theory of stochastic differential equations based on white noise analysis provides a physically meaningful modelling framework. The Wick product-based calculus for stochastic variables is similar to regular calculus; therefore, there is no need for Ito calculus. Numerical examples are provided with novel ways to solve the equations. While the theory of white noise analysis is well developed by mathematicians over the past decades, applications in biophysics do not exist. This book provides a bridge between this kind of mathematics and biophysics.
606   $aMathematical physics
606   $aComputer simulation
606   $aDifferential equations
606   $aBioinformatics
606   $aBiomathematics
606   $aComputational Physics and Simulations
606   $aDifferential Equations
606   $aComputational and Systems Biology
606   $aMathematical and Computational Biology
615  0$aMathematical physics.
615  0$aComputer simulation.
615  0$aDifferential equations.
615  0$aBioinformatics.
615  0$aBiomathematics.
615 14$aComputational Physics and Simulations.
615 24$aDifferential Equations.
615 24$aComputational and Systems Biology.
615 24$aMathematical and Computational Biology.
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