LEADER 00899nam0-22003011i-450- 001 990006779900403321 005 20001010 035 $a000677990 035 $aFED01000677990 035 $a(Aleph)000677990FED01 035 $a000677990 100 $a20001010d--------km-y0itay50------ba 101 0 $aita 105 $ay-------001yy 200 1 $aFourier analysis and its applications$fGerald B. Folland 210 $aPacific Grove$cWadsworth and Brooks-Cole advanced books and software$dc 1992. 215 $aX, 434 p.$d23 cm 225 1 $a<>Wadsworth & Brooks$fCole mathematics series$v 676 $a515 700 1$aFolland,$bGerald Budge$041512 801 0$aIT$bUNINA$gRICA$2UNIMARC 901 $aBK 912 $a990006779900403321 952 $aVI N 69$b20830$fFSPBC 959 $aFSPBC 996 $aFourier analysis and its applications$9634652 997 $aUNINA DB $aGEN01 LEADER 00726nam0-22002771i-450- 001 990003288770403321 005 20151113084220.0 035 $a000328877 035 $aFED01000328877 035 $a(Aleph)000328877FED01 035 $a000328877 100 $a20030910d1911----km-y0itay50------ba 101 0 $afre 105 $ay-------001yy 200 1 $aA travers l'Argentine moderne$fFrançois Crastre 210 $aParis$cLibrarie Hachette$d1911 215 $a184 p.$d18 cm 610 0 $aArgentina 676 $a021.055 700 1$aCrastre,$bFrancois$0130774 801 0$aIT$bUNINA$gRICA$2UNIMARC 901 $aBK 912 $a990003288770403321 952 $a021.055.CRA$b12823$fDECGE 959 $aDECGE 997 $aUNINA LEADER 04246nam 22006255 450 001 9910986138103321 005 20250312115243.0 010 $a9783031752797 024 7 $a10.1007/978-3-031-75279-7 035 $a(CKB)37836749300041 035 $a(MiAaPQ)EBC31957527 035 $a(Au-PeEL)EBL31957527 035 $a(DE-He213)978-3-031-75279-7 035 $a(OCoLC)1507699359 035 $a(EXLCZ)9937836749300041 100 $a20250312d2025 u| 0 101 0 $aeng 135 $aur||||||||||| 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 10$aCircular Economy Opportunities and Pathways for Manufacturers $eManufacturing Renewed /$fby Henrik Hvid Jensen 205 $a1st ed. 2025. 210 1$aCham :$cSpringer Nature Switzerland :$cImprint: Springer,$d2025. 215 $a1 online resource (469 pages) 225 1 $aFuture of Business and Finance,$x2662-2475 311 08$a9783031752780 327 $aThe Future of Manufacturing: Clean(er), digital, and circular models change production, consumption, and trade -- The Imperative of Circularity for Modern Manufacturers -- Manufacturers? competitiveness hinges on being clean(er) ? Generates growth for manufacturers through decarbonization -- Integrating Digital Capabilities in the Circular -- Economy: A Comprehensive Approach -- Digital Aspects in Circular Business Models for Manufacturers. 330 $aIn today's rapidly evolving manufacturing landscape, the future competitiveness for manufacturers hinges on three interlinked paradigms: 1. Circular Economy Models for Zero-Waste Product Lifecycles: The shift from traditional linear models to circular ones is increasingly crucial. Circular strategies extend product lifecycles, optimize resource use, and open new revenue streams, ultimately bolstering resilience, competitiveness and customer relationships. 2. Sustainable Manufacturing Through Decarbonization: As global awareness around sustainability grows, the push toward decarbonized manufacturing processes is no longer optional. Such an approach minimizes environmental impact while aligning with international sustainability goals. 3. Digital Enablement for Paradigm Transformation: Digitization serves as the lynchpin in realizing cleaner manufacturing and circular economy objectives. Tools like the Digital Product Passport (DPP) empower manufacturers to achieve transparency, encourage collaboration, and create unmatched business value, expediting the transition to sustainable and circular manufacturing. One of the most pressing challenges for manufacturers today is achieving the transition to cleaner and circular business models in a financially viable way. This book delves deeply into the business opportunities circularity presents and the pivotal role of digital solutions in enabling a smooth and cost-effective transition. It emphasizes how digitization can address economic feasibility concerns while driving operational efficiency and sustainability. By breaking down these critical elements, the book provides actionable insights and frameworks, serving as a practical guide for manufacturers striving to align economic priorities with environmental and operational demands, ensuring long-term competitiveness and resilience. 410 0$aFuture of Business and Finance,$x2662-2475 606 $aProduction management 606 $aTechnological innovations 606 $aIndustries 606 $aEnvironmental economics 606 $aProduction 606 $aEconomics of Innovation 606 $aSector and Industry Studies 606 $aEnvironmental Economics 615 0$aProduction management. 615 0$aTechnological innovations. 615 0$aIndustries. 615 0$aEnvironmental economics. 615 14$aProduction. 615 24$aEconomics of Innovation. 615 24$aSector and Industry Studies. 615 24$aEnvironmental Economics. 676 $a658.5 700 $aJensen$b Henrik Hvid$01790991 801 0$bMiAaPQ 801 1$bMiAaPQ 801 2$bMiAaPQ 906 $aBOOK 912 $a9910986138103321 996 $aCircular Economy Opportunities and Pathways for Manufacturers$94327849 997 $aUNINA LEADER 07999nam 2200445z- 450 001 9910220055703321 005 20210211 035 $a(CKB)3800000000216221 035 $a(oapen)https://directory.doabooks.org/handle/20.500.12854/52930 035 $a(oapen)doab52930 035 $a(EXLCZ)993800000000216221 100 $a20202102d2017 |y 0 101 0 $aeng 135 $aurmn|---annan 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 00$aMechanical Signaling in Plants: From Perception to Consequences for Growth and Morphogenesis (Thigmomorphogenesis) and Ecological Significance 210 $cFrontiers Media SA$d2017 215 $a1 online resource (93 p.) 225 1 $aFrontiers Research Topics 311 08$a9782889450749 311 08$a2889450740 330 $aDuring the 1970s, renewed interest in plant mechanical signaling led to the discovery that plants subjected to mechanical stimulation develop shorter and thicker axes than undisturbed plants, a syndrome called thigmomorphogenesis. Currently, mechanosensing is being intensively studied because of its involvement in many physiological processes in plants and particularly in the control of plant morphogenesis. From an ecological point of view, the shaping of plant architecture has to be precisely organized in space to ensure light capture as well as mechanical stability. In natural environments terrestrial plants are subjected to mechanical stimulation mainly due to wind, but also due to precipitation, while aquatic and marine plants are subjected to current and wave energy. Plants acclimate to mechanically challenging environments by sensing mechanical stimulations and modifying their growth in length and diameter and their tissue properties to reduce potential for buckling or breakage. From a morphogenetic point of view, both external and internal mechanical cues play an important role in the control of cell division and meristem development likely by modulating microtubule orientation. How mechanical stimulations are being sensed by plants is an area of intense research. Different types of mechanosensors have been discovered or proposed, including ion channels gated by membrane tension (stretch activation) and plasma membrane receptor-like kinases that monitor the cell wall deformations. Electrophysiologists have measured the conductances of some stretch-activated channels and have showed that SAC of different structures can exhibit different conductances. The role of these differences in conductance has not yet been established. Once a mechanical stimulus has been perceived, it must be converted into a biological signal that can lead to variations of plant phenotype. Calcium has been shown to function as an early second messenger, tightly linked with changes in cytosolic and apoplastic pH. Transcriptional analyses of the effect of mechanical stimulation have revealed a considerable number of differentially expressed genes, some of which appear to be specific to mechanical signal transduction. These genes can thus serve as markers of mechanosensing, for example, in studies attempting to define signalling threshold, or variations of mechanosensitivity (accommodation). Quantitative biomechanical studies have lead to a model of mechanoperception which links mechanical state and plant responses, and provides an integrative tool to study the regulation of mechanosensing. This model includes parameters (sensitivity and threshold) that can be estimated experimentally. It has also been shown that plants are desensitized when exposed to multiple mechanical signals as a function of their mechanical history. Finally, mechanosensing is also involved in osmoregulation or cell expansion. The links between these different processes involving mechanical signalling need further investigation. This frontier research topic provides an overview of the different aspects of mechanical signaling in plants, spanning perception, effects on plant growth and morphogenesis, and broad ecological significance.During the 1970s, renewed interest in plant mechanical signaling led to the discovery that plants subjected to mechanical stimulation develop shorter and thicker axes than undisturbed plants, a syndrome called thigmomorphogenesis. Currently, mechanosensing is being intensively studied because of its involvement in many physiological processes in plants and particularly in the control of plant morphogenesis. From an ecological point of view, the shaping of plant architecture has to be precisely organized in space to ensure light capture as well as mechanical stability. In natural environments terrestrial plants are subjected to mechanical stimulation mainly due to wind, but also due to precipitation, while aquatic and marine plants are subjected to current and wave energy. Plants acclimate to mechanically challenging environments by sensing mechanical stimulations and modifying their growth in length and diameter and their tissue properties to reduce potential for buckling or breakage. From a morphogenetic point of view, both external and internal mechanical cues play an important role in the control of cell division and meristem development likely by modulating microtubule orientation. How mechanical stimulations are being sensed by plants is an area of intense research. Different types of mechanosensors have been discovered or proposed, including ion channels gated by membrane tension (stretch activation) and plasma membrane receptor-like kinases that monitor the cell wall deformations. Electrophysiologists have measured the conductances of some stretch-activated channels and have showed that SAC of different structures can exhibit different conductances. The role of these differences in conductance has not yet been established. Once a mechanical stimulus has been perceived, it must be converted into a biological signal that can lead to variations of plant phenotype. Calcium has been shown to function as an early second messenger, tightly linked with changes in cytosolic and apoplastic pH. Transcriptional analyses of the effect of mechanical stimulation have revealed a considerable number of differentially expressed genes, some of which appear to be specific to mechanical signal transduction. These genes can thus serve as markers of mechanosensing, for example, in studies attempting to define signalling threshold, or variations of mechanosensitivity (accommodation). Quantitative biomechanical studies have lead to a model of mechanoperception which links mechanical state and plant responses, and provides an integrative tool to study the regulation of mechanosensing. This model includes parameters (sensitivity and threshold) that can be estimated experimentally. It has also been shown that plants are desensitized when exposed to multiple mechanical signals as a function of their mechanical history. Finally, mechanosensing is also involved in osmoregulation or cell expansion. The links between these different processes involving mechanical signalling need further investigation. This frontier research topic provides an overview of the different aspects of mechanical signaling in plants, spanning perception, effects on plant growth and morphogenesis, and broad ecological significance. 517 $aMechanical Signaling in Plants 606 $aBotany & plant sciences$2bicssc 610 $aacclimation 610 $aGrowth 610 $aMechanical signals 610 $aPerception 610 $athigmomorphognesis 615 7$aBotany & plant sciences 700 $aStephen J. Mitchell$4auth$01292326 702 $aMonshausen$b Gabrielle$4auth 702 $aPuijalon$b Sara$4auth 702 $aCoutand$b Catherine$4auth 906 $aBOOK 912 $a9910220055703321 996 $aMechanical Signaling in Plants: From Perception to Consequences for Growth and Morphogenesis (Thigmomorphogenesis) and Ecological Significance$93022174 997 $aUNINA