Sebald, lector de Benjamin: la rememoración como crítica espectral

Partiendo de la sentencia benjaminiana que afirma que «los hechos históricos pasan a serlo que ahora mismo nos sobrevino: constatarlos es una tarea del recuerdo», que supone ungiro copernicano en el campo historiográfico, porque lo histórico ya no versa sobre la reconstruccióndel pasado sino sobre su construcción en el presente, el artículo aborda laUnheimlichkeit en la obra de Sebald, entendida como condición de posibilidad de su escrituracomo rememoración, presentándose como ese Jetztzeit benjaminiano que urge ainterrumpir la continuidad opresiva de la historia, la necesidad de la cadena de los acontecimientos.La Unheimlichkeit abre un espacio en el lenguaje en el que pueda sobrevivirla memoria de aquellos confinados a los archivos. La imposibilidad de hacer revivir esasvidas que acabaron en los archivos no es motivo para hacerlas morir una segunda vez.Starting from the Benjaminian sentence that asserts “the historical facts happen to be whatstrike us right now: To state them is a task of memory”, and which supposes a Copernicanturning point in the historiographical field, as the historical is not about the reconstructionof the past anymore but about its construction in the present, this paper deals with Sebald’sUnheimlichkeit understood as a condition of possibility of the act of remembrance in hiswriting, thus presenting itself as a Benjaminian Jetztzeit that urges a break in the oppressivecontinuity of history, the necessary chain of events. Unheimlichkeit opens a space in thelanguage in which the memory of those who are confined to the archives may survive.The impossibility of resurrecting those lives that have ended in the archives is no reason tomake them die a second time

Ressenyes

Index de les obres ressenyades: Itsjok KATZENELSON, El canto del pueblo judío asesinad

Walter Benjamin : las formas de la crítica

Presentació d'Enrahonar 58.Presentación de Enrahonar 58.Presentation of Enrahonar 58

Modelling Day and Night-Time Population using a 3D Urban Model

Dasymetric methods are commonly used to redistribute or disaggregate (census) population data, using either simple binary or multi-layer models. Most models show limitations in high density built-up areas as they commonly ignore the 3D dimension (meaning buildings height) of multi-story urban environments. For example, simple dasymetric models only allocate the population counts to built-up areas, without considering differences between areas of multi-story and single-story buildings. Furthermore, such models only allow the disaggregation of ‘night-time’ population data, while for many urban applications such as transport, health or hazard, the location of ‘day-time’ population is of interest. This research presents an initial approach to model day and night-time population using as case study an Indian city (Kalyan-Dombivli). For most Indian cities, census population data is only available for wards, while day-time population data is either not available or of very poor quality. Besides census data and ancillary spatial data, this research uses a 3D urban model, extracted from Cartosat stereo-images. First, the extracted height from the stereo-image is used in combination with building footprints to disaggregate census population data at wards to ‘night-time’ population per building. Second, a classification of economically active areas is constructed based on the 3D urban model in combination with other spatial layers (e.g. transport layers) to model the day-time population. The result shows different concentration of population during day and night-time across ward boundaries as well as it confirms the potential of 3D data to disaggregate population data

Polaronic signature in the metallic phase of La0.7Ca0.3MnO3 films detected by scanning tunneling spectroscopy

In this work we map tunnel conductance curves with nanometric spatial resolution, tracking polaronic quasiparticle excitations when cooling across the insulator-to-metal transition in La0.7Ca0.3MnO3 films. In the insulating phase the spectral signature of polarons, a depletion of conductance at low bias flanked by peaks, is detected all over the scanned surface. These features are still observed at the transition and persist on cooling into the metallic phase. Polaron-binding energy maps reveal that polarons are not confined to regions embedded in a highly-conducting matrix but are present over the whole field of view both above and below the transition temperature.Comment: 10 pages, 4 figure

The role of earth observation in an integrated deprived area mapping “system” for low-to-middle income countries

Urbanization in the global South has been accompanied by the proliferation of vast informal and marginalized urban areas that lack access to essential services and infrastructure. UN-Habitat estimates that close to a billion people currently live in these deprived and informal urban settlements, generally grouped under the term of urban slums. Two major knowledge gaps undermine the efforts to monitor progress towards the corresponding sustainable development goal (i.e., SDG 11—Sustainable Cities and Communities). First, the data available for cities worldwide is patchy and insufficient to differentiate between the diversity of urban areas with respect to their access to essential services and their specific infrastructure needs. Second, existing approaches used to map deprived areas (i.e., aggregated household data, Earth observation (EO), and community-driven data collection) are mostly siloed, and, individually, they often lack transferability and scalability and fail to include the opinions of different interest groups. In particular, EO-based-deprived area mapping approaches are mostly top-down, with very little attention given to ground information and interaction with urban communities and stakeholders. Existing top-down methods should be complemented with bottom-up approaches to produce routinely updated, accurate, and timely deprived area maps. In this review, we first assess the strengths and limitations of existing deprived area mapping methods. We then propose an Integrated Deprived Area Mapping System (IDeAMapS) framework that leverages the strengths of EO- and community-based approaches. The proposed framework offers a way forward to map deprived areas globally, routinely, and with maximum accuracy to support SDG 11 monitoring and the needs of different interest groups

Photodetectors based on low-dimensional materials and hybrid systems

Premi extraordinari doctorat UPC curs 2015-2016, àmbit de CiènciesIn the last decade, two-dimensional (2D) materials have attracted attention both in the nascent field of flexible nanotechnology as well as in more conventional semiconductor technol-ogies. Within the rapidly expanding portfolio of 2D materials, the group of semiconducting transition metal dichalcogenides (TMDCs) has emerged as an intriguing candidate for various optoelectronic applications. The atomically thin profile, favorable bandgap and outstanding electronic properties of TMDCs are unique features that can be explored and applied in novel photodetecting platforms. This thesis presents highly sensitive two-dimensional phototransistors made of sub-nanometre thick TMDC channels. Firstly, an encapsulation route is developed to address the detrimental and, to date, uncontrollable impact of atmospheric adsorbates, which severely deteriorate detector performance. The passivation scheme improves the transport properties of TMDCs, leading to high photoconductive gain with gate dependent responsivity of 10 -10^4 A/W throughout the visible, and temporal response down to 10 ms, which is suitable for imaging applications. The atomic device thickness yields ultra-low dark current operation and record detectivity of 10^11 - 10^12 Jones for TMDC-based detectors is achieved. The use of monolayer TMDCs, however, has disadvantages like limited spectral absorption due to the bandgap and limited absorption efficiency. In order to increase the absorption and to extend the spectral coverage, TMDC channels are covered with colloidal quantum dots to make hybrid phototransistors. This compelling synergy combines strong and size-tunable light absorption within the QD film, efficient charge separation at the TMDC-QD interface and fast carrier transport through the 2D channel. This results in large gain of 10^6 electrons per absorbed photon and creates the basis for extremely sensitive light sensing. Colloidal quan-tum dots are an ideal sensitizer, because their solution-processing and facile implementation on arbitrary substrates allows for low-cost fabrication of hybrid TMDC-QD devices. Moreover, the custom tailored bandgap of quantum dots provides the photodetector with wide spectral tunability. For photodetection in the spectral window of NIR/SWIR, which is still dominated by expensive and complex epitaxy-based technologies, these hybrid detectors have the potential to favorably compete with commercially available systems. The interface of the TMDC-QD hybrid is of paramount importance for sensitive detector operation. A high density of trap states at the interface is shown to be responsible for inefficient gate-control over channel conductivity, which leads to high dark currents. To maintain the unique electrical field-effect modulation in TMDCs upon deposition of colloidal quantum dots, a passivation route of the interface with semiconducting metal-oxide films is developed. The buffer-layer material is selected such that charge transfer from QDs into the channel is favored. The retained field-effect modulation with a large on/off ratio allows operation of the phototransistor at significantly lower dark currents than non-passivated hybrids. A TMDC-QD phototransistor with an engineered interface that exhibits detectivity of 10^12 - 10^13 Jones and response times of 12 ms and less is reported. In summary, this work showcases prototype photodetectors made of encapsulated 2D TMDCs and TMDC-QD hybrids. Plain TMDC-detectors have potential for application as flexible and semi-transparent detector platforms with high sensitivity in the visible. The hybrid TMDC-QD device increases its spectral selectivity to the NIR/SWIR due to the variable absorption of the sensitizing quantum dots and reaches compelling performance thanks to im-proved light-matter interaction and optimized photocarrier generation.En la última década ha surgido un gran interés por los materiales bidimensionales (2D) tanto para las tecnologías emergentes de dispositivos flexibles, como para las tecnologías de semiconductores tradicionales. Dentro del creciente catálogo de materiales 2D, los semiconductores basados en dicalcogenuros de metales de transición (DCMTs) han surgido como candidatos para aplicaciones optoelectrónicas. Sus características únicas, tales como grosor atómico, banda prohibida y propiedades electrónicas pueden ser examinadas y aplicadas en nuevas plataformas de fotodetección. En esta tesis se presentan nuevos fototransistores bidimensionales ultrasensibles basados en canales de DCMTs subnanométricos. Se presenta una ruta de encapsulación para intentar solucionar el impacto negativo, e incontrolable hasta la fecha, producido por la adsorción de sustancias atmosféricas que degradan el funcionamiento de los detectores. Este proceso mejora el transporte en los DCMTs dando lugar a una gran ganancia fotoconductora, una respuesta, dependiente de la tensión aplicada en el gate, de 10-10^4 A/W en el visible y una respuesta temporal de tan solo 10 ms, todo ello adecuado para aplicaciones de imagen. El grosor atómico de los dispositivos da lugar a corrientes de oscuridad muy bajas y una detectividad de 10^11-10^12 Jones. Sin embargo, el uso de monocapas de DCMTs presenta ciertas desventajas como por ejem-plo una eficiencia en la absorción baja. Con el fin de mejorar la absorción, los canales de DCMTs se han recubierto con puntos cuánticos (QDs) para fabricar fototransistores híbridos. Esta sinergia combina la alta absorción de los QDs, una eficiente separación de cargas en la interfaz DCMT-QD y un rápido transporte de cargas a través del canal 2D. Todo esto resulta en una ganancia de 10^6 electrones por fotón absorbido y crea la base para sensores de luz extremadamente sensibles. Los puntos cuánticos coloidales son sensibizadores ideales ya que su procesado en disolución y su fácil incorporación sobre cualquier sustrato permiten la fabricación de sistemas híbridos DCMT-QD a bajo coste. Además, la posibilidad de modifi-car la banda prohibida, ofrecida por los QDs, proporciona al fotodetector una amplia respuesta espectral. Para fotodetección en la ventana espectral del infrarrojo cercano (NIR/SWIR), estos detectores híbridos presentan el potencial de competir favorablemente con los sistemas comerciales disponibles. La interfaz entre el híbrido DCMT-QD es de la mayor importancia para la sensibilidad del detector. Se ha demostrado que una alta densidad de trampas en la interfaz es la responsable del ineficiente control mediante el gate de la conductividad del canal, dando lugar a corrientes de oscuridad muy altas. Para mantener la excepcional modulación de efecto campo aún después de la deposición de los QDs, se ha desarrollado una ruta de pasivación de la interfaz con óxidos metálicos semiconductores. El material de esta capa amortiguadora (buffer) es seleccionado de tal manera que permita la transferencia de cargas desde los puntos cuánticos hasta el canal DCMT. Esto retiene la modulación de efecto campo con una relación encendido/apagado muy alta, permitiendo el funcionamiento del fototransistor con corrientes de oscuridad significativamente menores que las de los híbridos sin pasivar. Así, se presenta un fototransistor híbrido DCMT-QD, con una interfaz cuidadosamente diseñada, que exhibe una detectividad de 10^12-10^13 Jones. En resumen, este trabajo presenta unos prototipos de fotodetectores basados en DCMT 2D encapsulados y en híbridos DCMT-QD. Los fotodetectores basados en DCMT simples presentan potencial para su aplicación en detectores flexibles y semitransparentes, con gran sensibilidad en el visible. Los híbridos DCMT-QD amplían la selectividad espectral al infrarrojo cercano gracias a la absorción variable ofrecida por los puntos cuánticos y alcanzan un muy interesante rendimiento gracias a una mejor interacción luz-materia.Award-winningPostprint (published version

Proliferation and arrest of human tetraploid cells

Durch Fehler entstandene tetraploide Zellen sind chromosomal instabil und können zu Zelltransformation führen. Die Beweise verdichten sich, dass die Propagation von tetraploiden Säugetierzellen durch einen p53-vermittelten Arrest eingeschränkt wird; jedoch ist weiterhin unklar, was die Ursache dieses p53-vermittelten Arrests ist. Um die Ursache des p53-vermittelten Arrests zu identifizieren, wurden individuelle Zellen mittels zeitraffender Mikroskopie in Echtzeit verfolgt. Neu entstandene tetraploide Zellen können einen Zellzyklus vollenden, aber die Mehrzahl der Zellen starb oder verharrte in einem Arrest in der folgenden G1-Phase, abhängig davon ob die vorangegangene Mitose fehlerfrei verlief oder nicht. Tochterzellen, denen eine fehlerhafte Mitose voranging, akkumulierten p53 im Zellkern, was zum Zelltod oder einem irreversiblen Zellzyklusarrest führte. Es zeigte sich durch den Anstieg von 8-OHdG, einem Indikator für oxidative DNA Schädigung, dass tetraploide Zellen durch die vermehrten fehlerhaften Mitosen höheren Konzentrationen von reaktiven oxidativen Spezien (ROS) ausgesetzt sind. Der Anstieg von 8-OHdG korrelierte mit der p53-Akkumulation im Zellkern. Da keine vermehrte Phosphorylierung des Histons H2AX (γ-H2AX), ein Marker für DNA-Strangbrüche, detektiert wurde, lässt sich schlussfolgern, dass ROS entscheidend für den p53 vermittelten Arrest verantwortlich sind. Mehrere p53-aktivierende Kinasen wurden mittels RNA Interferenz (RNAi) und chemischer Genetik untersucht, ob sie einen Einfluss auf den Zellzyklusarrest von tetraploiden Zellen haben. Von den getesteten Kinasen hatte nur ATM einen Einfluss auf die Aktivierung von p53 nach fehlerhaften tetraploiden Mitosen. Zwar wird ATM in der Regel durch DNA-Schäden aktiviert, jedoch wurde bereits zuvor gezeigt, dass ATM auch durch erhöhte ROS Konzentrationen aktiviert werden kann. Um die Zusammenhänge des Zellzyklusarrests weiter aufzuklären, wurde ein genomübergreifender esiRNA Screen etabliert, der die Zellproliferation nach induzierter Tetraploidisierung analysiert. Durch Kombination der Zellzyklusanalyse an Hand des DNA-Gehalts zusammen mit den FUCCI-Zellzyklusindikatoren, konnten tetraploide und diploide Zellen nebeneinander mikroskopisch analysiert werden, ohne zuvor tetraploide und diploide Zellen isolieren zu müssen. Dieser neue experimentelle Ansatz ermöglichte die Identifikation von Genen, die spezifisch die Proliferation von tetraploiden Zellen verstärken oder einschränken Im Primärscreen wurden 1159 Gene identifiziert, deren Inhibition die Proliferation einschränken. Weiter wurden 431 Gene identifiziert, deren Inhibition die Proliferation der tetraploiden Zellen verstärken. Von den 431 Genen, deren Inhibition die Proliferation verstärken, wurden 371 Gene einem Konfirmationsscreen unterzogen, in dem 158 der identifizierten 371 Gene bestätigt wurden. Die bioinformatische Analyse der 158 Gene zeigte eine signifikante Anhäufung von Genen, die mit DNA-Replikation, dem kanonischen Wnt-Signalweg oder mit Tumorsignalwegen assoziiert sind. Unter letzteren ist CCDC6 sehr interessant, da dessen Genprodukt durch ATM phosphoryliert wird und nachgeschaltet den Tumorsuppressor 14-3-3σ reguliert. Des weiteren wurden mittels einer Meta Analyse der Ergebnisse des Primärscreens, zusammen mit den Daten aus dem “Project Achilles”, welches genomweit den Effekt von shRNA-vermittelter Geninhibition auf die Proliferation von 108 Krebszelllinien untersuchte, 18 Gene identifiziert, deren Inhibition sowohl die Proliferation von tetraploiden Zellen einschränkt, als auch die Proliferation von Zelllinien hemmt, welche von Krebsarten stammen, die zu meist chromosomale Instabilitäten (CIN) aufweisen. Damit bilden die präsentierten Daten nicht nur eine gute Basis zur Aufklärung des Zellzyklusarrests tetraploider Zellen, sondern auch für die Identifikation neuer potentieller Zielmoleküle, welche benutzt werden können um Tumorerkrankungen mit chromosomaler Instabilität zu behandeln, welche häufig resistent gegen die bislang verfügbaren Behandlungen sind.Erroneously arising tetraploid mammalian cells are chromosomally unstable and may facilitate cell transformation. An increasing body of evidence suggests that the propagation of mammalian tetraploid cells is limited by a p53-dependent arrest, however, the triggers of this arrest have thus far not been identified. To elucidate the timing and causes of this arrest, time-lapse live cell imaging was performed to track the fate of individual cells immediately after tetraploidization. Newly formed tetraploid cells can progress through one cell cycle, but the majority of cells arrest or die in the subsequent G1 stage, with the fate of these tetraploid cells determined by the preceding mitosis. Daughter cells arising from defective mitosis accumulated p53 in the nucleus, which led to irreversible cell cycle arrest or death. Furthermore this p53 accumulation coincides and correlates with an increase of the oxidative DNA damage marker 8-OHdG, suggesting an increase in reactive oxygen species (ROS), but does not coincide with the phosphorylation of H2AX (γ-H2AX), a marker for canonical DNA damage. Using RNA interference and chemical genetics, several p53 activating kinases were tested for their contribution to the cell cycle arrest of tetraploid cells. Of the tested kinases, only ATM was shown to play a role in the activation of p53 after defects in mitosis. ATM kinase is a DNA damage-responsive kinase, however, it has been shown that increased ROS levels activate ATM in a non-canonical way. To gain further insights into arrest of tetraploid cells, an unbiased genome-wide esiRNA screen was performed to analyze cell proliferation after induced tetraploidization. Using FUCCI cell cycle probes, combined with DNA content cell cycle profiling, allowed an image-based assay to examine tetraploid and diploid cells side-by-side. This novel approach enabled us to screen for genes that specifically restricts or enhances cell proliferation after tetraploidization, if inhibited by esiRNA mediated knockdown. From the primary screen we identified 1159 genes that decreased and 431 genes that increased the cell proliferation after tetraploidization, if knocked down by esiRNA. From the 431 genes that increased proliferation upon knockdown, 374 were selected and subjected to a re-screen. Of these 374 genes, we were able to confirm the results for 158 of the genes. A bioinformatics analysis of the 158 genes for which the phenotype were confirmed by the re-screen revealed a significant enrichment of genes involved in DNA replication, the canonical Wnt signaling pathway and in pathways linked to cancer. Among the latter, CCDC6 is particularly interesting, because its gene product is a target of the ATM kinase and an upstream regulator of the tumor suppressor 14-3-3σ. Moreover, by comparing the results of the primary screen with the data of the “Project Archilles”, which measured the proliferation in genome wide pooled-shRNA screens for 108 cancer cell lines, 18 genes were identified that are essential for the proliferation of cells after tetraploidization, as well as for the proliferation of cancer cell lines that derive from cancer types with a high incidence for chromosomal instability (CIN). Taken together, the presented data builds an excellent resource not only for elucidating how the arrest after tetraploidization is mediated, but also to identify novel potential therapeutic targets against tumors with CIN, which are frequently resistant to many of today’s anti-cancer therapies

Quantum Information Processing with Ferroelectrically Coupled Quantum Dots

I describe a proposal to construct a quantum information processor using ferroelectrically coupled Ge/Si quantum dots. The spin of single electrons form the fundamental qubits. Small (<10 nm diameter) Ge quantum dots are optically excited to create spin polarized electrons in Si. The static polarization of an epitaxial ferroelectric thin film confines electrons laterally in the semiconductor; spin interactions between nearest neighbor electrons are mediated by the nonlinear process of optical rectification. Single qubit operations are achieved through "g-factor engineering" in the Ge/Si structures; spin-spin interactions occur through Heisenberg exchange, controlled by ferroelectric gates. A method for reading out the final state, while required for quantum computing, is not described; electronic approaches involving single electron transistors may prove fruitful in satisfying this requirement.Comment: 10 pages, 3 figure