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Long description: Sie skalieren ein Start-up, haben aber nur eine dunkle Ahnung, wie man das am besten macht? Dann geht es Ihnen wie den meisten Führungskräften in Wachstumsunternehmen – auch die haben keine Zeit, unzählige Bücher und Blogs zu lesen, Hunderte Podcasts zu hören und das ganze Wissen dann auch noch für die Praxis zuzuschneiden. Darum haben Martin Schilling und Thomas Klugkist das übernommen: Ausgehend von 40 Jahren kombinierter Erfahrung beim Aufbau von Unternehmen, haben sie Interviews mit rund 100 führenden Scale-up-Experten aus weltweit erfolgreichen Technologieunternehmen geführt – darunter Airbnb, Pinterest, N26, Zalando, Salesforce, Wayfair, AWS, GetYourGuide, Klarna und Hubspot. Aus diesem konzentrierten Know-how entstand dieses Handbuch für Start-up-Teams und -Führungskräfte, (zukünftige) Gründer und Gründerinnen, Investoren und Investorinnen sowie Innovationsabteilungen großer Unternehmen. Dabei geht es nicht darum, ein kleines Unternehmen von Zero to One oder eine Einhornfirma an die Börse zu bringen. Der Builder's Guide zielt auf die kritische Scale-up-Phase in der Mitte – in der sich ein Piratenschiff zu einem Raumschiff transformiert. Das Buch umfasst 99 Praxismodule zu den Themen Nordstern, AAA-Team, funktionale Exzellenz und Wachstumskapital. Wer hier gezielt sucht, findet in wenigen Minuten, was er schon am nächsten Montag anders macht.Für jeden Unternehmensbereich:Exemplarische OrganigrammeZiele und Schlüsselergebnisse (OKRs)Werkzeuge, Benchmarks und WachstumsformelnVertiefende digitale Inhalte als Augmented-Reality: Videos, Templates u.a.Außerdem: Vorworte von Thomas Heilmann, Christian Miele, Kulraj Smagh, Klaus Hommels und Joel Kaczmarek.Mit der kostenlosen App smARt Haufe" wird Ihr Buch interaktiv:Augmented-Reality-App für Smartphones und Tablets (iOS und Android)App "smARt Haufe" kostenlos downloaden, Buchseiten mit dem Smartphone scannen und Zusatzfunktionen nutzenDigitale Zusatzinhalte: VideosStimmen aus der Start-up-Szene:"Der Builder's Guide wird für Gründer und Gründerinnen, die sich auf der Reise der schnellen Skalierung befinden, unverzichtbar sein. Die hier zusammengetragenen, sofort umsetzbaren Maßnahmen werden der nächsten Generation von Start-ups helfen, globale Ambitionen zu erfüllen und eine Praxis der ständigen Entdeckung zu etablieren, durch die sie heute und vor allem morgen an der Spitze des Feldes bleiben werden."Kulraj Smagh, CEO bei Ciklum"Der Builder's Guide überführt das bei erfolgreichen Gründern schlummernde Erfahrungswissen in ein Framework. Wo Software-Unternehmens-Gründungen Skaleneffekte wie nie zuvor ermöglichen, ist ein solches Instrumentarium ungemein wichtig geworden."Joël Kaczmarek, Geschäftsführer digital kompakt Biographical note: Martin Schilling Dr. Martin Schilling war COO des FinTechs N26, zuvor Berater bei McKinsey, gründete und skalierte mehrere erfolgreiche Ventures (darunter eine Stiftung in Argentinien, ein öffentliches Unternehmen in Saudi-Arabien, ein Startup in Berlin, das McKinsey-Tochterunternehmen Orphoz) und ist Autor und Keynote Speaker mit Fokus auf Tech-Startups und Scale-ups. Thomas Klugkist Dr. Thomas Klugkist ist erfahrener Medien-, Kommunikations- und Change-Manager sowie Berater (Klett-Gruppe, Kirch-Gruppe, KPN/ Planet Internet, Schott Music, N26), ehemaliger Geschäftsführer eines Gründerverbandes (JCI Germany) und Autor mehrerer erfolgreicher Bücher.
Investition --- Geschäftsmodell --- Business --- Wachstum --- Unternehmer --- Unternehmensgründung --- Gründer --- Finanzierung --- Profit --- Kapital --- Handbuch --- Börsengang --- Investor --- Start-up --- Entrepreneurship --- Leitfaden --- Investoren --- Wachstumsrate --- Startup --- Toolkit --- Scale-Up --- Entrepreneur --- unternehmensgründer --- Wachstumsstrategie --- Skalierung --- OKR --- Unicorn --- Einhornfirma --- scaleup --- Martin Schilling --- Thomas Klugkist --- Wachstumsphase --- Marktbewertung --- Unicorn Firma --- Scaling
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Process intensification aims for increasing efficiency and sustainability of (bio-)chemical production processes. This book presents strategies for improving fluid separation such as reactive distillation, reactive absorption and membrane assisted separations. The authors discuss computer simulation, model development, methodological approaches for synthesis and the design and scale-up of final industrial processes. Process intensification aims for increasing efficiency and sustainability of (bio-)chemical production processes. This book presents strategies for improving fluid separation such as reactive distillation, reactive absorption and membrane assisted separations. The authors discuss computer simulation, model development, methodological approaches for synthesis and the design and scale-up of the final industrial processes.
Chemical process control. --- Separation (Technology) --- Salvage (Waste, etc.) --- Membranes (Technology) --- Chemistry, Technical. --- Chemical technology --- Industrial chemistry --- Technical chemistry --- Chemistry --- Technology --- Chemical engineering --- Artificial membranes --- Conversion of waste products --- Industrial salvage --- Recovery of waste products --- Solid waste management --- Utilization of waste products --- Waste management --- Waste reclamation --- Waste products --- Recycling (Waste, etc.) --- Refuse and refuse disposal --- Analytical chemistry --- Chemistry, Technical --- Process control --- Chemical separations --- Separation processes --- Separation science --- Separation technologies --- Separations, Chemical --- Fluid separation. --- Process Intensification. --- Scale-Up. --- Sustainable Production Processes.
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Since the first works introducing the aluminum intercalated clay family in the early 1970s, interest in the synthesis of Pillared InterLayered Clays (PILC) has increased tremendously, especially research into their properties and energetic and environmental applications. After our comprehensive reviews and book on the synthesis and catalytic applications of these materials, new references have appeared in the literature and the interest in this field is continuously increasing. The aim of this Special Issue is to collect the recent advances developed considering this family of solids.
Technology: general issues --- clays --- Al-PILC --- pillared clays --- scale up --- pillaring solution --- Keggin ion --- reutilization --- Keggin polycation --- concentrated media --- microwave radiation --- pillared montmorillonite --- AlNi-PILC --- Pd-Ce --- catalytic combustion --- benzene --- TPD/TPSR --- ZnO-TiO2/delaminated montmorillonite --- heterostructures --- Ag-coating --- solar photocatalytic activity --- water purification --- cadmium --- chitosan --- modification --- 13X molecular sieve --- removal --- dye remediation --- adsorption --- azo dye --- wastewater --- pillared porous phosphate heterostructures --- isotherm --- sericite --- thermal modification --- acid activation --- sodium modification --- montmorillonite/hydrotalcite composite --- montmorillonite/titania composite --- organoclay --- inverse micelle --- Mn-Al mixed oxide --- combustion catalysts --- ciprofloxacin --- smectite --- pillared clay --- keggin-like mixed Al/Fe polyoxocation --- mineralogical composition --- catalytic wet peroxide oxidation --- mesosilica --- methyl orange --- palygorskite
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A rapid growth in various industries and domestic activities is resulting in a huge amount of wastewater. Various types of wastewaters, such as textile, municipal, dairy, pharmaceutical, swine, and aquaculture, etc., are produced regularly by respective industries. These wastewaters are rich in nutrient content and promote eutrophication in the ecosystem and pose a threat to flora and fauna. According to an estimate, eutrophication causes losses of almost 2 billion US dollars annually, affecting real estate and fishing activities. Treatment of wastewater is a costly process and recently wastewater treatment with simultaneous energy production has received more attention. Microorganisms can be used to recover nutrients from wastewater and produce bioenergy (biodiesel, biohydrogen, bioelectricity, methane, etc.). A better understanding of the composition of various types of wastewaters and the development of technologies like anaerobic digestion (AD), microbial fuel cell (MFC), and microbial electrolysis cell (MEC) can help to make wastewater-based biorefinery a reality. To provide an overall overview to students, teachers, and researchers on wastewater to bioenergy technology ten chapters are included in this book.
Environmental science, engineering & technology --- effluent --- anaerobic digestion --- incineration --- Co-pyrolysis --- syngas --- biodiesel --- biofuel --- biogas --- MEC --- bio-hydrogen --- manure --- digestion --- cybersecurity --- cybercrime --- legislation --- policy --- systems thinking --- water --- DEA --- regional difference --- energy utilization efficiency --- carbon emission --- cost --- database --- treatment --- wastewater --- Web of Science --- biogas digestion --- hydrogen sulfide --- ferric oxide --- waterworks sludge --- biofilm --- lattice Boltzmann method --- cellular automata --- individual-based model --- chitin --- electricity generation --- halotolerant --- microbial fuel cell --- seafood processing --- microbial electrolysis cells --- chronological development --- wastewater to hydrogen --- scale-up --- life-cycle assessment --- MEC commercialization --- microalgae --- wastewater treatment --- nutrient removal --- n/a
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Since the first works introducing the aluminum intercalated clay family in the early 1970s, interest in the synthesis of Pillared InterLayered Clays (PILC) has increased tremendously, especially research into their properties and energetic and environmental applications. After our comprehensive reviews and book on the synthesis and catalytic applications of these materials, new references have appeared in the literature and the interest in this field is continuously increasing. The aim of this Special Issue is to collect the recent advances developed considering this family of solids.
clays --- Al-PILC --- pillared clays --- scale up --- pillaring solution --- Keggin ion --- reutilization --- Keggin polycation --- concentrated media --- microwave radiation --- pillared montmorillonite --- AlNi-PILC --- Pd-Ce --- catalytic combustion --- benzene --- TPD/TPSR --- ZnO-TiO2/delaminated montmorillonite --- heterostructures --- Ag-coating --- solar photocatalytic activity --- water purification --- cadmium --- chitosan --- modification --- 13X molecular sieve --- removal --- dye remediation --- adsorption --- azo dye --- wastewater --- pillared porous phosphate heterostructures --- isotherm --- sericite --- thermal modification --- acid activation --- sodium modification --- montmorillonite/hydrotalcite composite --- montmorillonite/titania composite --- organoclay --- inverse micelle --- Mn-Al mixed oxide --- combustion catalysts --- ciprofloxacin --- smectite --- pillared clay --- keggin-like mixed Al/Fe polyoxocation --- mineralogical composition --- catalytic wet peroxide oxidation --- mesosilica --- methyl orange --- palygorskite
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A rapid growth in various industries and domestic activities is resulting in a huge amount of wastewater. Various types of wastewaters, such as textile, municipal, dairy, pharmaceutical, swine, and aquaculture, etc., are produced regularly by respective industries. These wastewaters are rich in nutrient content and promote eutrophication in the ecosystem and pose a threat to flora and fauna. According to an estimate, eutrophication causes losses of almost 2 billion US dollars annually, affecting real estate and fishing activities. Treatment of wastewater is a costly process and recently wastewater treatment with simultaneous energy production has received more attention. Microorganisms can be used to recover nutrients from wastewater and produce bioenergy (biodiesel, biohydrogen, bioelectricity, methane, etc.). A better understanding of the composition of various types of wastewaters and the development of technologies like anaerobic digestion (AD), microbial fuel cell (MFC), and microbial electrolysis cell (MEC) can help to make wastewater-based biorefinery a reality. To provide an overall overview to students, teachers, and researchers on wastewater to bioenergy technology ten chapters are included in this book.
effluent --- anaerobic digestion --- incineration --- Co-pyrolysis --- syngas --- biodiesel --- biofuel --- biogas --- MEC --- bio-hydrogen --- manure --- digestion --- cybersecurity --- cybercrime --- legislation --- policy --- systems thinking --- water --- DEA --- regional difference --- energy utilization efficiency --- carbon emission --- cost --- database --- treatment --- wastewater --- Web of Science --- biogas digestion --- hydrogen sulfide --- ferric oxide --- waterworks sludge --- biofilm --- lattice Boltzmann method --- cellular automata --- individual-based model --- chitin --- electricity generation --- halotolerant --- microbial fuel cell --- seafood processing --- microbial electrolysis cells --- chronological development --- wastewater to hydrogen --- scale-up --- life-cycle assessment --- MEC commercialization --- microalgae --- wastewater treatment --- nutrient removal --- n/a
Choose an application
A rapid growth in various industries and domestic activities is resulting in a huge amount of wastewater. Various types of wastewaters, such as textile, municipal, dairy, pharmaceutical, swine, and aquaculture, etc., are produced regularly by respective industries. These wastewaters are rich in nutrient content and promote eutrophication in the ecosystem and pose a threat to flora and fauna. According to an estimate, eutrophication causes losses of almost 2 billion US dollars annually, affecting real estate and fishing activities. Treatment of wastewater is a costly process and recently wastewater treatment with simultaneous energy production has received more attention. Microorganisms can be used to recover nutrients from wastewater and produce bioenergy (biodiesel, biohydrogen, bioelectricity, methane, etc.). A better understanding of the composition of various types of wastewaters and the development of technologies like anaerobic digestion (AD), microbial fuel cell (MFC), and microbial electrolysis cell (MEC) can help to make wastewater-based biorefinery a reality. To provide an overall overview to students, teachers, and researchers on wastewater to bioenergy technology ten chapters are included in this book.
Environmental science, engineering & technology --- effluent --- anaerobic digestion --- incineration --- Co-pyrolysis --- syngas --- biodiesel --- biofuel --- biogas --- MEC --- bio-hydrogen --- manure --- digestion --- cybersecurity --- cybercrime --- legislation --- policy --- systems thinking --- water --- DEA --- regional difference --- energy utilization efficiency --- carbon emission --- cost --- database --- treatment --- wastewater --- Web of Science --- biogas digestion --- hydrogen sulfide --- ferric oxide --- waterworks sludge --- biofilm --- lattice Boltzmann method --- cellular automata --- individual-based model --- chitin --- electricity generation --- halotolerant --- microbial fuel cell --- seafood processing --- microbial electrolysis cells --- chronological development --- wastewater to hydrogen --- scale-up --- life-cycle assessment --- MEC commercialization --- microalgae --- wastewater treatment --- nutrient removal --- effluent --- anaerobic digestion --- incineration --- Co-pyrolysis --- syngas --- biodiesel --- biofuel --- biogas --- MEC --- bio-hydrogen --- manure --- digestion --- cybersecurity --- cybercrime --- legislation --- policy --- systems thinking --- water --- DEA --- regional difference --- energy utilization efficiency --- carbon emission --- cost --- database --- treatment --- wastewater --- Web of Science --- biogas digestion --- hydrogen sulfide --- ferric oxide --- waterworks sludge --- biofilm --- lattice Boltzmann method --- cellular automata --- individual-based model --- chitin --- electricity generation --- halotolerant --- microbial fuel cell --- seafood processing --- microbial electrolysis cells --- chronological development --- wastewater to hydrogen --- scale-up --- life-cycle assessment --- MEC commercialization --- microalgae --- wastewater treatment --- nutrient removal
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Since the first works introducing the aluminum intercalated clay family in the early 1970s, interest in the synthesis of Pillared InterLayered Clays (PILC) has increased tremendously, especially research into their properties and energetic and environmental applications. After our comprehensive reviews and book on the synthesis and catalytic applications of these materials, new references have appeared in the literature and the interest in this field is continuously increasing. The aim of this Special Issue is to collect the recent advances developed considering this family of solids.
Technology: general issues --- clays --- Al-PILC --- pillared clays --- scale up --- pillaring solution --- Keggin ion --- reutilization --- Keggin polycation --- concentrated media --- microwave radiation --- pillared montmorillonite --- AlNi-PILC --- Pd-Ce --- catalytic combustion --- benzene --- TPD/TPSR --- ZnO-TiO2/delaminated montmorillonite --- heterostructures --- Ag-coating --- solar photocatalytic activity --- water purification --- cadmium --- chitosan --- modification --- 13X molecular sieve --- removal --- dye remediation --- adsorption --- azo dye --- wastewater --- pillared porous phosphate heterostructures --- isotherm --- sericite --- thermal modification --- acid activation --- sodium modification --- montmorillonite/hydrotalcite composite --- montmorillonite/titania composite --- organoclay --- inverse micelle --- Mn-Al mixed oxide --- combustion catalysts --- ciprofloxacin --- smectite --- pillared clay --- keggin-like mixed Al/Fe polyoxocation --- mineralogical composition --- catalytic wet peroxide oxidation --- mesosilica --- methyl orange --- palygorskite --- clays --- Al-PILC --- pillared clays --- scale up --- pillaring solution --- Keggin ion --- reutilization --- Keggin polycation --- concentrated media --- microwave radiation --- pillared montmorillonite --- AlNi-PILC --- Pd-Ce --- catalytic combustion --- benzene --- TPD/TPSR --- ZnO-TiO2/delaminated montmorillonite --- heterostructures --- Ag-coating --- solar photocatalytic activity --- water purification --- cadmium --- chitosan --- modification --- 13X molecular sieve --- removal --- dye remediation --- adsorption --- azo dye --- wastewater --- pillared porous phosphate heterostructures --- isotherm --- sericite --- thermal modification --- acid activation --- sodium modification --- montmorillonite/hydrotalcite composite --- montmorillonite/titania composite --- organoclay --- inverse micelle --- Mn-Al mixed oxide --- combustion catalysts --- ciprofloxacin --- smectite --- pillared clay --- keggin-like mixed Al/Fe polyoxocation --- mineralogical composition --- catalytic wet peroxide oxidation --- mesosilica --- methyl orange --- palygorskite
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This Special Issue is result of a call for papers of the Section Industrial Crystallization of MDPI’s scientific journal Crystals. It addresses scientists and engineers active in research and process & product development in life-science industries (e.g. pharmaceuticals, fine chemicals and biotechnology products) and bulk chemical applications (e.g. desalination) as well. The contributions comprise several fundamental and application-oriented facets of crystallization providing an overview of industrially relevant subjects in the field. Main issues cover phase equilibria and solid-state behavior of crystalline compounds, crystal shape and size and related measurement techniques. Melt and solution crystallization are considered specifically addressing contemporary aspects of continuous crystallization and process intensification.
Technology: general issues --- K-MER zeolite --- synthesis parameter --- morphology --- cyanoethylation of methanol --- catalyst --- multi-dendrite motion --- CA-LBM model --- dendritic growth --- natural convection --- numerical simulation --- melt crystallization --- freeze crystallization (FC) --- recycling --- ionic liquid (IL) --- solid–liquid equilibrium --- cellulose --- nanocrystals --- modification --- poly(butylene succinate) --- crystallization --- kinetics --- chirality --- deracemization --- preferential crystallization --- racemic conglomerate --- phase behavior --- polymorphism --- aryl glycerol ethers --- spherical BaTiO3 nanoparticle --- hydrothermal synthesis --- nanoscale TiO2 seed --- crystal growth --- dielectric property --- curcumin --- purification --- ternary mixture of curcuminoids --- reverse osmosis --- membrane fouling --- gypsum scaling --- fluorescent-tagged polyacrylate --- fluorescence --- scale inhibition mechanisms --- solvent effect --- crystal habit --- aspect ratio --- molecular dynamics (MD) --- surface structure --- amine --- biocatalysis --- enzyme --- process intensification --- enantioselective --- fluidized bed --- continuous --- chiral separation --- racemate resolution --- enantiomer --- asparagine monohydrate --- fine chemicals --- continuous crystallization --- crystal shape --- process design --- DTB crystallizer --- scale up --- L-serine --- L-alanine --- enantiomers --- isomorphic miscibility --- thermal expansion --- PXRD --- TRPXRD --- optical measurement techniques --- crystal size measurement --- inline probe --- crystal needles --- microcrystals --- microplate --- grid scanning --- in situ data collection --- n/a --- solid-liquid equilibrium
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Scale up and implementation of new point-of-care (POC) diagnostics is a global health priority to enable the adoption of new evidence-based POC diagnostics and to replicate and extend the reach of POC diagnostics. Global private and public sector agencies have significantly increased their investment in the development of POC diagnostics to meet the unmet needs of patients in resource-limited settings, particularly disease burdened settings with limited access to laboratory infrastructure. However, previous research has demonstrated that the availability of health technologies in these settings does not always guarantee patient-centered outcomes. The applicability, effectiveness and sustainability of diagnostic technologies is affected by the involvement of all stakeholders during planning and implementation, which must be relevant to each specific context and sensitive to local culture. Factors such as infrastructure, resources, values and characteristics of participants can influence the implementation, scalability and sustainability of health interventions such as POC diagnostics. This book, “Implementation and Scale up of Point of Care (POC) Diagnostics in Resource-Limited Settings”, presents literature reviews and primary research studies focusing on the implementation and scale up of POC diagnostics in resource-limited settings.
Humanities --- Social interaction --- point-of-care-ultrasound --- ultrasound --- implementation --- point of care ultrasound --- augmented reality --- telemedicine --- spatial accessibility --- blood group --- rhesus type --- point-of-care testing --- maternal healthcare --- Upper East Region --- Ghana --- point-of-care ultrasound --- medical education --- syphilis --- maternal mortality --- interrupted time series --- segmented regression analysis --- point-of-care CD4+ t testing --- qualitative survey --- acceptability --- patients --- healthcare providers --- primary healthcare clinics --- HIV self-testing --- scale-up --- key stakeholder --- quality HIV point-of-care-diagnostics --- nominal group technique --- stakeholder engagement --- self-testing --- novel coronavirus disease-19 --- blockchain --- artificial intelligence --- geographical access --- glucose-6-phosphate dioxygenase deficiency --- antenatal care --- upper east region --- schistosomiasis --- barriers to diagnostics --- access to healthcare --- end-user perspectives --- neglected tropical diseases --- Nigeria --- case management --- electronic health information system --- diagnosis --- treatment --- point-of-care --- low and middle income countries --- point-of-care diagnostics --- healthcare services --- COVID-19 era
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