Hu Li – författare

Biomass conversion into drop-in chemicals using novel heterogeneous bulk- and nano-scale catalysts is currently a hot research topic with the aim of replacing petrochemicals in the chemical industry. Considering the importance of this subject to the scientific community, Advanced Catalysis for Drop-in Chemicals provides the latest developments in the catalytic synthesis of drop-in chemicals mainly from lignocellulose, carbohydrates (cellulose, hemicellulose, C6 and C5 sugars, and their derivatives), lignin, and glycerol. The role of both heterogeneous bulk solid and nanostructured catalysts, along with their advantages and disadvantages for drop-in chemicals synthesis are critically summarized. Addressing the frontiers and prospects for using drop-in chemicals in place of petrochemicals in the chemical industry is also a key topic of this book. Describes fossil fuels, biomass, drop-in chemicals, catalysis, and nano- and atomic-scale catalysts Includes pre- and post-treatment strategies for biomass upgrading Provides green catalytic processes for drop-in chemicals synthesis Outlines stabilization of nano- and atomic-scale catalysts Examines using drop-in chemicals in place of petrochemicals in the chemical industry

Biochemicals and Materials Production from Sustainable Biomass Resources provides a detailed overview of the experimentally developed approaches and strategies that facilitate carbon-based materials and fine chemicals derivation from biomass feedstocks with robust catalyst systems and renewed conversion routes. In addition, the book highlights theoretical methods like techno-economic analysis of biobutanol synthesis. As academia and industry are now striving to substitute fossil-based chemicals with alternative renewable resources, second-generation lignocellulosic biomass which does not depend on the food cycle has become increasingly important.

Lignocellulosic biomass is composed of three major polymeric components - lignin, cellulose and hemicellulose. The polymers can be degraded into monomeric counterparts through selective conversion routes like hydrolysis of cellulose to glucose and of hemicellulose to xylose.

Includes the recent development of biomass-derived high-value chemicals and functional materials Describes theoretical and technical details of specific conversion routes and preparation methods Covers jointly organic transformations, catalytic synthesis, reaction mechanisms, thermal stability, reaction parameters and solvent effects

Biomass, Biofuels, Biochemicals: Recent Advances in Development of Platform Chemicals provides a detailed overview on the experimentally developed methods that facilitate platform chemicals derivation from biomass-based substrates with robust catalyst systems. In addition, the book highlights the green chemistry approach towards platform chemical production. Chapters discuss platform chemicals and global market volumes, the optimization of process schemes and reaction parameters with respect to achieving a high yield of targeted platform chemicals, such as sugars and furonic compounds by modifying the respective catalytic system, the influence of solvents on reaction selectivity and product distribution, and the long-term stability of employed catalysts.

Overall, the objectives of the book are to provide the reader with an understanding of the societal importance of platform chemicals, an assessment of the techno-economic viability of biomass valorization processes, catalyst design for a specific reaction, and the design of a catalytic system.

Covers recent developments on platform chemicals Provides comprehensive technological developments on specific platform chemicals Covers organic transformations, catalytic synthesis, thermal stability, reaction parameters and solvent effect Includes case studies on the production of a number of chemicals, such as Levulinic acid, glycerol, phenol derivatives, and more

Diminishing confined fossil resources has spurred the scientific community to strive for alternative, sustainable resources, such as terrestrial biomass, which can potentially substitute fossil-based derivatives. Lignocellulosic biomass is deemed an indispensable carbon source for meeting industrial and social demands regarding energy/fuels and chemicals. Over the past decade, significant advances have been shown in developing a broad spectrum of high-value chemicals and functional materials derived from biomass-based substrates. In connection with this, furanic chemicals, such as 5-hydroxymethylfurfural (HMF) and furfural, have recently received considerable attention due to their potential applications. Catalytic Transformations of Sustainable and Versatile Furanic Chemicals aims to explicitly display the latest technical developments on designing functional catalysts, optimizing process and reaction parameters, and improving the stability of the employed materials on the transformation of HMF and furfural to a wide range of value-added chemicals via oxidation, reduction, hydrodeoxygenation, and reductive amination processes.Features:Highlighting the importance and significance of HMF and furfural.Evaluating the transformations of HMF and furfural with various catalytic processes.Designing robust and efficient catalytic systems.Understanding the stability of catalytic materials.Understanding the characteristic features of the catalytic materials.This book aims to target not only researchers focusing on biomass valorization from academic to industrial sectors but also graduate students interested in pursuing their higher education in biochemicals (especially furanic compounds), covering various aspects in organic synthesis routes, preparation of inorganic materials and physico-chemical properties, for both chemists and chemical engineers.

Diminishing confined fossil resources has spurred the scientific community to strive for alternative, sustainable resources, such as terrestrial biomass, which can potentially substitute fossil-based derivatives. Lignocellulosic biomass is deemed an indispensable carbon source for meeting industrial and social demands regarding energy/fuels and chemicals. Over the past decade, significant advances have been shown in developing a broad spectrum of high-value chemicals and functional materials derived from biomass-based substrates. In connection with this, furanic chemicals, such as 5-hydroxymethylfurfural (HMF) and furfural, have recently received considerable attention due to their potential applications. Catalytic Transformations of Sustainable and Versatile Furanic Chemicals aims to explicitly display the latest technical developments on designing functional catalysts, optimizing process and reaction parameters, and improving the stability of the employed materials on the transformation of HMF and furfural to a wide range of value-added chemicals via oxidation, reduction, hydrodeoxygenation, and reductive amination processes.Features:Highlighting the importance and significance of HMF and furfural.Evaluating the transformations of HMF and furfural with various catalytic processes.Designing robust and efficient catalytic systems.Understanding the stability of catalytic materials.Understanding the characteristic features of the catalytic materials.This book aims to target not only researchers focusing on biomass valorization from academic to industrial sectors but also graduate students interested in pursuing their higher education in biochemicals (especially furanic compounds), covering various aspects in organic synthesis routes, preparation of inorganic materials and physico-chemical properties, for both chemists and chemical engineers.

This book is the perfect reference guide to produce hydrocarbons from biomass. Both conventional and emerging chemo-catalytic processes for direct valorization of biomass to biofuels are presented. A must-have for scientific and also industrial researchers working in this field.

This book provides state-of-the-art reviews, current research, prospects and challenges of the production of biofuels and chemicals such as furanic biofuels, biodiesel, carboxylic acids, polyols and others from lignocellulosic biomass, furfurals, syngas and γ-valerolactone with bifunctional catalysts, including catalytic, and combined biological and chemical catalysis processes. The bifunctionality of catalytic materials is a concept of not only using multifunctional solid materials as activators, but also design of materials in such a way that the catalytic materials have synergistic characteristics that promote a cascade of transformations with performance beyond that of mixed mono-functional catalysts. This book is a reference designed for researchers, academicians and industrialists in the area of catalysis, energy, chemical engineering and biomass conversion. Readers will find the wealth of information contained in chapters both useful and essential, for assessing the production and application of various biofuels and chemicals by chemical catalysis and biological techniques.