01012nam a22002651i 450099100161123970753620031126162603.0040407s1921 fr a||||||||||||||||fre b12796645-39ule_instARCHE-077627ExLDip.to Scienze StoricheitaA.t.i. Arché s.c.r.l. Pandora Sicilia s.r.l.333.717Ferdinand Lop, Samuel129983La Tunisie et ses richesses /S. Ferdinand- Lop ; preface de Edouard SoulierParis :Roger et Cie,c1921197 p., [21] c. di tav. :ill. ;20 cmLes pays modernesTunisiaRisorse naturaliSoulier, Édouard.b1279664502-04-1416-04-04991001611239707536LE009 GEOG.16-9212009000157583le009-E0.00-l- 00000.i1334240x16-04-04Tunisie et ses richesses293639UNISALENTOle00916-04-04ma -frefr 3102807nam0 2200565 i 450 VAN012415520230703020848.245N978331958540620191009d2017 |0itac50 baengCH|||| |||||Functional Analysis, Spectral Theory, and ApplicationsManfred Einsiedler, Thomas WardChamSpringer2017xiv, 614 p.ill.24 cm001VAN00235792001 Graduate texts in mathematics210 New York [etc.]Springer276VAN0235619Functional Analysis, Spectral Theory, and Applications156255247-XXOperator theory [MSC 2020]VANC019759MF46-XXFunctional analysis [MSC 2020]VANC019764MF35J25Boundary value problems for second-order elliptic equations [MSC 2020]VANC019840MF11NxxMultiplicative number theory [MSC 2020]VANC020461MF22BxxLocally compact abelian groups (LCA groups) [MSC 2020]VANC021309MF37AxxErgodic theory [MSC 2020]VANC021388MF47A60Functional calculus for linear operators [MSC 2020]VANC021617MF35P20Asymptotic distribution of eigenvalues in context of PDEs [MSC 2020]VANC022648MF35P10Completeness of eigenfunctions and eigenfunction expansions in context of PDEs [MSC 2020]VANC023070MF20F69Asymptotic properties of groups [MSC 2020]VANC024156MFAmenable groupsKW:KElliptic regularityKW:KFunctional AnalysisKW:KLaplace operatorKW:KMeasurable functional calculusKW:KOrdinary differential equationsKW:KPartial differential equationsKW:KPontryagin dualityKW:KPrime number theoremKW:KProperty (T) Expander graphKW:KSpectral theory of Banach algebrasKW:KCHChamVANL001889EinsiedlerManfredVANV095627477516WardThomasVANV036606329535Springer <editore>VANV108073650ITSOL20240614RICAhttp://doi.org/10.1007/978-3-319-58540-6E-book – Accesso al full-text attraverso riconoscimento IP di Ateneo, proxy e/o ShibbolethBIBLIOTECA DEL DIPARTIMENTO DI MATEMATICA E FISICAIT-CE0120VAN08NVAN0124155BIBLIOTECA DEL DIPARTIMENTO DI MATEMATICA E FISICA08CONS e-book 0681 08eMF681 20191009 Functional Analysis, Spectral Theory, and Applications1562552UNICAMPANIA04207nam 2200589zu 450 991013720110332120230621135731.09782889194032 (ebook)(CKB)3710000000526103(SSID)ssj0001680206(PQKBManifestationID)16496091(PQKBTitleCode)TC0001680206(PQKBWorkID)15028245(PQKB)10274689(WaSeSS)IndRDA00056161(oapen)https://directory.doabooks.org/handle/20.500.12854/52946(oapen)doab52946(EXLCZ)99371000000052610320160829d2015 uy |engur|||||||||||txtrdacontentcrdamediacrrdacarrierMechanisms of neural circuit formation /Joshua A. Weiner, Robert W. Burgess, James Jontes [editors]Frontiers Media SA2015Switzerland :Frontiers Media SA,20151 online resource (179 pages) illustrations; digital, PDF file(s)Frontiers Research TopicsBibliographic Level Mode of Issuance: MonographIncludes bibliographical references.The formation of the proper pattern of neuronal circuits during development is critical for the normal function of the vertebrate brain and for the survival of the organism. Circuit tracing studies spanning the past 100 years have revealed the beauty and exquisite intricacy of this pattern, which represents the most complex biological system known. In humans, aberrant circuit formation is a likely underlying cause of a wide variety of birth defects and neurological disorders, including autism, intellectual disability, and schizophrenia. Furthermore, future therapeutic approaches to restoring the function of damaged neural circuits will require a better understanding of the developmental constraints under which those circuits were originally assembled. For these reasons, elucidating the molecular mechanisms of neural circuit formation is a major goal of neurobiology today.Substantial progress towards this goal has been made over the past decade, and the pace of research in the field continues to accelerate with the development of novel molecular techniques and a wider variety of genetic model systems, including zebrafish and nematodes in addition to fruit flies and mice. The aim of this Research Topic is to bring together the many strands of research that shed light on the mechanisms driving neural circuit formation: studies of the differentiation of distinct neuronal subtypes; the formation of dendritic arbors and the elaboration of postsynaptic spines; the pathfinding, targeting, and branching of axons; the proper apposition of specific pre- and post-synaptic terminals; the emerging role of glial cells in facilitating synaptogenesis and synapse elimination; and the mutations behind the aberrant circuitry that leads to neurological disorders. We seek to highlight not only newly identified molecular mechanisms, but also technical advances that have allowed progress in the field to grow exponentially, including novel imaging techniques and the proliferation of large-scale “-omics” studies. We hope that this Research Topic will provide a forum for top researchers in the field to present new data, formulate novel hypotheses and models, and critically review recent progress in each step of neural circuit formation.NeuroscienceHILCCHuman Anatomy & PhysiologyHILCCHealth & Biological SciencesHILCCneural circuitdendrite arborizationCell Adhesion Moleculesaxon guidancesynapse formationNeuroscienceHuman Anatomy & PhysiologyHealth & Biological SciencesRobert W. Burgessauth1363994Burgess Robert WJontes JamesWeiner Joshua APQKBUkMaJRU9910137201103321Mechanisms of neural circuit formation3385065UNINA