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Very few materials have attracted so much attention in recent years, both from researchers and industry, as layered double hydroxides (LDHs) have. LDHs, which are also referred to as anionic clays or hydrotalcites, are a wide class of inorganic ionic lamellar clay materials consisting of alternately stacked positively charged metal hydroxide layers with intercalated charge-balancing anions in hydrated interlayer regions. Their unique properties, such as their extremely high versatility in chemical composition and intercalation ability, extraordinary tuneability in composition as well as morphology, good biocompatibility and high anion exchangeability, have triggered immense interdisciplinary interest for their use in many different fields of chemistry, biology, medicine, and physics. Indeed, the applications of LDHs are constantly growing: LDHs, in the form of aggregated lamellar clusters, exfoliated single-layer nanosheets, or hierarchical films of interconnected nanoplatelets, can be effectively used as nanoscale vehicles in drug delivery, heterogeneous catalysts and supports for molecular catalysts, ion exchangers and adsorbents, solid electrolytes or fillers in electrochemistry, for the fabrication of superhydrophobic surfaces, water treatment and purification, and the synthesis of functional thin films. This book gathers the contributions to the Special Issue “Layered Double Hydroxides” of Crystals, which includes two review articles and seven research papers.

Research & information: general --- layered double hydroxide --- memory effect --- rare earth --- europium --- 1,3,5-benzenetricarboxylic acid --- alginate beads --- green sorbent --- selective adsorption --- heavy metals --- tetracycline --- metal hydroxides --- layered double hydroxides --- removal --- water sample --- Bacillus subtilis --- surfactin --- quantitative analysis --- fermentation --- growth phase --- cellular biology --- catalysis --- DNA --- drug delivery --- hydrotalcite --- osteogenesis --- photocatalysis --- RNA. --- antimonate uptake --- mine water --- brandholzite --- zincalstibite --- iron precursor --- acidic residual solution --- LDH synthesis --- Mo(VI) adsorption --- resveratrol --- solid lipid nanoparticles --- endurance exercise --- mitochondrial nutrients --- mitochondrial quality control --- origin of life --- layer double hydroxide --- synthetic biology --- bioinspired devices --- biosensors --- bioanalysis --- n/a

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• Reference Manager
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Very few materials have attracted so much attention in recent years, both from researchers and industry, as layered double hydroxides (LDHs) have. LDHs, which are also referred to as anionic clays or hydrotalcites, are a wide class of inorganic ionic lamellar clay materials consisting of alternately stacked positively charged metal hydroxide layers with intercalated charge-balancing anions in hydrated interlayer regions. Their unique properties, such as their extremely high versatility in chemical composition and intercalation ability, extraordinary tuneability in composition as well as morphology, good biocompatibility and high anion exchangeability, have triggered immense interdisciplinary interest for their use in many different fields of chemistry, biology, medicine, and physics. Indeed, the applications of LDHs are constantly growing: LDHs, in the form of aggregated lamellar clusters, exfoliated single-layer nanosheets, or hierarchical films of interconnected nanoplatelets, can be effectively used as nanoscale vehicles in drug delivery, heterogeneous catalysts and supports for molecular catalysts, ion exchangers and adsorbents, solid electrolytes or fillers in electrochemistry, for the fabrication of superhydrophobic surfaces, water treatment and purification, and the synthesis of functional thin films. This book gathers the contributions to the Special Issue “Layered Double Hydroxides” of Crystals, which includes two review articles and seven research papers.

layered double hydroxide --- memory effect --- rare earth --- europium --- 1,3,5-benzenetricarboxylic acid --- alginate beads --- green sorbent --- selective adsorption --- heavy metals --- tetracycline --- metal hydroxides --- layered double hydroxides --- removal --- water sample --- Bacillus subtilis --- surfactin --- quantitative analysis --- fermentation --- growth phase --- cellular biology --- catalysis --- DNA --- drug delivery --- hydrotalcite --- osteogenesis --- photocatalysis --- RNA. --- antimonate uptake --- mine water --- brandholzite --- zincalstibite --- iron precursor --- acidic residual solution --- LDH synthesis --- Mo(VI) adsorption --- resveratrol --- solid lipid nanoparticles --- endurance exercise --- mitochondrial nutrients --- mitochondrial quality control --- origin of life --- layer double hydroxide --- synthetic biology --- bioinspired devices --- biosensors --- bioanalysis --- n/a

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The rise of photonics technologies has driven an extremely fast evolution in biosensing applications. Such rapid progress has created a gap of understanding and insight capability in the general public about advanced sensing systems that have been made progressively available by these new technologies. Thus, there is currently a clear need for moving the meaning of some keywords, such as plasmonic, into the daily vocabulary of a general audience with a reasonable degree of education. The selection of the scientific works reported in this book is carefully balanced between reviews and research papers and has the purpose of presenting a set of applications and case studies sufficiently broad enough to enlighten the reader attention toward the great potential of plasmonic biosensing and the great impact that can be expected in the near future for supporting disease screening and stratification.

Technology: general issues --- History of engineering & technology --- gold nanorods --- silica coating --- localized surface plasmon resonance (LSPR) --- surface functionalization --- SPR biosensor --- enzyme --- laccase --- chlorophene --- emerging pollutant --- water sample --- plasmonic nanowires --- molecular sensing --- surface-enhanced Raman spectroscopy --- porous alumina --- TREM2 sensors --- Alzheimer’s disease --- plasmonic interferometry --- optical biosensor --- surface plasmon resonance --- olfactory sensors --- electronic noses --- volatile organic compounds --- odorants --- SPR --- cell-based assay --- viral growth kinetics --- human coronavirus --- hydroxychloroquine --- protease --- caspase --- avidin-biotin interaction --- biosensors --- AuNPs --- metal–graphene hybrid --- simulations --- Mie theory --- African swine fever virus (ASFV) --- loop-mediated isothermal amplification (LAMP) --- surface plasmon resonance (SPR) --- fluorescence detection --- SERS analysis --- plasmonic metal nanoparticles --- hotspots --- hybrid materials --- gold nanorods --- silica coating --- localized surface plasmon resonance (LSPR) --- surface functionalization --- SPR biosensor --- enzyme --- laccase --- chlorophene --- emerging pollutant --- water sample --- plasmonic nanowires --- molecular sensing --- surface-enhanced Raman spectroscopy --- porous alumina --- TREM2 sensors --- Alzheimer’s disease --- plasmonic interferometry --- optical biosensor --- surface plasmon resonance --- olfactory sensors --- electronic noses --- volatile organic compounds --- odorants --- SPR --- cell-based assay --- viral growth kinetics --- human coronavirus --- hydroxychloroquine --- protease --- caspase --- avidin-biotin interaction --- biosensors --- AuNPs --- metal–graphene hybrid --- simulations --- Mie theory --- African swine fever virus (ASFV) --- loop-mediated isothermal amplification (LAMP) --- surface plasmon resonance (SPR) --- fluorescence detection --- SERS analysis --- plasmonic metal nanoparticles --- hotspots --- hybrid materials