Giant exciton-enhanced shift currents and direct current conduction with subbandgap photo excitations produced by many-electron interactions

Shift current is a direct current generated from nonlinear light–matter interaction in a noncentrosymmetric crystal and is considered a promising candidate for next-generation photovoltaic devices. The mechanism for shift currents in real materials is, however, still not well understood, especially if electron–hole interactions are included. Here, we employ a first-principles interacting Green’s-function approach on the Keldysh contour with real-time propagation to study photocurrents generated by nonlinear optical processes under continuous wave illumination in real materials. We demonstrate a strong direct current shift current at subbandgap excitation frequencies in monolayer GeS due to strongly bound excitons, as well as a giant excitonic enhancement in the shift current coefficients at above bandgap photon frequencies. Our results suggest that atomically thin two-dimensional materials may be promising building blocks for next-generation shift current devices.

When continuous wave light is shone on a noncentrosymmetric crystal, a direct current (DC) can arise due to a second-order optical response of the crystal. The origin of this current is interpreted to be related to the “shift” (1–4) of the intracell coordinates of the excited electron. This so-called shift current is proposed as an alternative to the photocurrent generated by traditional semiconductor p–n junctions (i.e., a junction between hole-doped [p-type] and electron-doped [n-type] semiconductors) for photovoltaic applications (5, 6). Unlike conventional photovoltaic devices, shift current is a bulk phenomenon, which does not require a p–n junction to separate the optically generated electron–hole pair for a DC. Moreover, recent studies reveal that the photocarriers in shift current can have long travel distances, which is distinct from the usual drift transport mechanism in traditional solar cells (7, 8) and makes shift current a promising candidate for efficient energy conversion.Despite many investigations over the past decade, a basic understanding of shift currents is far from complete. Most theoretical studies to date rely on the assumption of having noninteracting particles (3–6, 9–11). Given that it is well known that light-induced electron–hole pairs can form bound or resonant excitons (correlated electron–hole states), which dominate and qualitatively change the absorption features of semiconductors, electron–hole interactions or excitons are expected to play a large role in shift currents, especially for reduced dimensional systems. However, it is not straight forward to generalize existing ab initio methods [such as the ab initio GW plus Bethe-Salpeter equation (GW-BSE) approach (12)], used to understand and compute excitonic effects in linear optical absorption, to study nonlinear optical responses. Different model approaches to investigate the effects of many-electron interactions on nonlinear optical responses of materials have been proposed. For instance, a Floquet-based model Hamiltonian formalism showed that excitonic effects enhance nonlinear response (13). In the specific case of second harmonic generation, first-principles approaches have been developed and applied to real materials, for instance, by making an approximation to the full many-body perturbation theory treatment (14, 15) or to the time-dependent density function theory, in which electron interaction effects are taken into account via simplified kernels (16). A real-time formulation based on propagating the time-dependent Schrodinger equation has also been developed (17) and applied to second harmonic generation (18). For shift currents in real materials, only one recent study considered the effects of excitons on the linear optical coefficient that might influence shift currents, but these authors included only the effects of excitons on the electromagnetic field profile in a bulk sample, and the crucial process of shift current generation itself is still treated within an independent-particle picture (11). Thus, there is still no first-principles calculation and understanding of the role of many-electron interactions, particularly those due to excitons, on shift currents.Here, we show from first principles that 1) bound exciton states in the band gap can generate substantial shift currents, and 2) excitonic effects in the electron–hole continuum part of the spectrum can also greatly enhance shift currents due to the enhancement of the optical matrix elements from the coherence of the electron–hole pairs and to interexciton couplings that arose in the nonlinear responses.     

Emotional Eating Moderates the Relationship of Night Eating with Binge Eating and Body Mass

Night eating syndrome is marked by substantial evening or nocturnal food intake, insomnia, morning anorexia, and depressed mood. Night eating severity has been positively associated with body mass index (BMI), binge eating frequency, and emotional eating tendencies. We conducted an online questionnaire study among students (N = 729) and explored possible interactive effects between those variables. Night eating severity, binge eating frequency, BMI and emotional eating were all positively correlated with each other. Regression analyses showed that night eating severity was particularly related to more frequent binge episodes and higher BMI at high levels of emotional eating but unrelated to those variables at low levels of emotional eating. Thus, eating as a means of emotion regulation appears to be an important moderator of the relationship between night eating and both binge eating and BMI. Copyright © 2013 John Wiley & Sons, Ltd and Eating Disorders Association.     

Duration of interventricular septal shift toward the left ventricle is associated with poor clinical outcome in precapillary pulmonary hypertension: A cardiac magnetic resonance study

BackgroundRight ventricular pressure overload results in interventricular septal shift toward the left ventricle in patients with precapillary pulmonary hypertension (PH). We aimed to investigate the predictive role of the duration of septal curvature configuration during the cardiac cycle, as expressed by the novel marker curvature duration index (CDi) in precapillary PH.MethodsThis was a prospective study. All patients underwent cardiac magnetic resonance (CMR). CDi was defined by the number of CMR frames in which septal curvature configuration toward left ventricle is observed *100/total number of frames per cardiac cycle. Time from enrollment to first clinical failure event (death, hospitalization due to PH, and disease progression) was recorded.ResultsThe study included 36 patients with precapillary PH. During a median follow-up of 20 months (IQR 4-37 months), 14 clinical failure events were observed. Survival ROC analysis showed that the optimal cutoff value of CDi, which predicted clinical failure, was 67%. Kaplan–Meier survival analysis showed that CDi≥67% was associated with a 9.4-fold increase in the risk for clinical failure. Addition of CDi to baseline models including six-minute walk test distance (c-statistic = 0.65 vs. c-statistic = 0.79), NT-proBNP (c-statistic = 0.72 vs. c-statistic = 0.83), and WHO functional class (c-statistic = 0.76 vs. c-statistic = 0.81) improved risk stratification.ConclusionVentricular septal shift toward the left ventricle lasting for more than the two thirds of the cardiac cycle is associated with worse prognosis in precapillary PH.     

Investigating the age‐related “anterior shift” in the scalp distribution of the P3b component using principal component analysis

An age‐related “anterior shift” in the distribution of the P3b is often reported. Temporospatial principal component analysis (PCA) was used to investigate the basis of this observation. ERPs were measured in young and old adults during a visual oddball task. PCA revealed two spatially distinct factors in both age groups, identified as the posterior P3b and anterior P3a. Young subjects generated a smaller P3a than P3b, while old subjects generated a P3a that did not differ in amplitude from their P3b. Rather than having a more anteriorly distributed P3b, old subjects produced a large, temporally overlapping P3a. The pattern of the age‐related “anterior shift” in the P3 was similar for target and standard stimuli. The increase in the P3a in elderly adults may not represent a failure to habituate the novelty response, but may reflect greater reliance on executive control operations (P3a) to carry out the categorization/updating process (P3b).     

Biogeography of time partitioning in mammals

Many animals regulate their activity over a 24-h sleep–wake cycle, concentrating their peak periods of activity to coincide with the hours of daylight, darkness, or twilight, or using different periods of light and darkness in more complex ways. These behavioral differences, which are in themselves functional traits, are associated with suites of physiological and morphological adaptations with implications for the ecological roles of species. The biogeography of diel time partitioning is, however, poorly understood. Here, we document basic biogeographic patterns of time partitioning by mammals and ecologically relevant large-scale patterns of natural variation in “illuminated activity time” constrained by temperature, and we determine how well the first of these are predicted by the second. Although the majority of mammals are nocturnal, the distributions of diurnal and crepuscular species richness are strongly associated with the availability of biologically useful daylight and twilight, respectively. Cathemerality is associated with relatively long hours of daylight and twilight in the northern Holarctic region, whereas the proportion of nocturnal species is highest in arid regions and lowest at extreme high altitudes. Although thermal constraints on activity have been identified as key to the distributions of organisms, constraints due to functional adaptation to the light environment are less well studied. Global patterns in diversity are constrained by the availability of the temporal niche; disruption of these constraints by the spread of artificial lighting and anthropogenic climate change, and the potential effects on time partitioning, are likely to be critical influences on species’ future distributions.Natural cycles of light and darkness structure the environment of the majority of eukaryotic organisms. The rotation of the Earth partitions time into regular cycles of day and night, and although all points on the Earth’s surface receive roughly equal durations of light and darkness over the course of a year, at mid to high latitudes seasonal variation in day length imposes an uneven distribution throughout the annual cycle. During the hours when the sun is below the horizon, there is seasonal and latitudinal variation in the duration of “biologically useful semidarkness” in the form of twilight and moonlight (1), modified by both the lunar cycle and variable cloud cover, providing changing opportunities for animals able to use visual cues for key behaviors including foraging, predator avoidance, and reproduction (2–6). Activity during both daylight and semidarkness may be further constrained by covariance between the natural cycles of light and temperature; the metabolic costs of thermoregulation place constraints on the time available for activity (7). Thermal constraints may limit nocturnal activity when nighttime temperatures are low, and diurnal activity when temperatures are high. Furthermore, energetic constraints may force some species to be active throughout hours of both light and darkness (8). Where energetic and thermal costs are not prohibitive, temporal niche partitioning may occur as species specialize and avoid competition by concentrating their activity within a particular section along the light gradient (9, 10). Behavioral traits are associated with a range of specialized adaptations, particularly in visual systems and eye morphology (11) and energetics and resource use (6, 12). Thus, some species are apparently obligately diurnal in their peak activity patterns, some obligately nocturnal, obligately crepuscular (active primarily during twilight), or obligately cathemeral (significant activity both during daylight and night), and others make facultative use of both daylight and night (13), or show seasonal and/or geographical variation in their strategy. Strict nocturnality and diurnality are hence two ends of a continuum of possible strategies for partitioning time over the 24-h cycle. As properties of organisms that strongly influence performance within a particular environment, these strategies can be considered functional traits in themselves (14), but are also associated with suites of adaptations, with implications for the ecological roles of species and individuals. Crepuscular and cathemeral species may have intermediate adaptations (15), and behavior may be flexible to vary within species and among individuals according to factors such as time of year, habitat structure, food availability, age, temperature, and the presence or absence of predators (16–18).The ecology of diel time partitioning by organisms remains rather poorly understood (19, 20). Studies have considered the adaptive mechanisms behind strategies within a single ecosystem, including predator avoidance, energetic constraints, diet quality, and interspecific competition (9, 21). Meanwhile, although mapping functional traits has become a core technique in functional biogeography (22, 23), surprisingly little is known about the biogeography of diel activity patterns, and the extent to which they are determined by geographic gradients in light and climate. Addressing such issues has become more pressing with growth in the evidence for a wide range of ecological impacts of both anthropogenic climatic change and nighttime light pollution (24–28). Natural cycles of light have remained consistent for extremely long geological periods, providing a rather invariant context, and a very reliable set of potential environmental cues. The continued spread of electric lighting has caused substantial disruption to how these cycles are experienced by many organisms, exerting a novel environmental pressure (29). Direct illumination of the environment has quite localized effects, but sky glow—the amplified night sky brightness that is produced by upwardly emitted and reflected electric light being scattered by water, dust, and gas molecules in the atmosphere—can alter light regimes over extensive areas. Indeed, under cloudy conditions in urban areas, sky glow has been shown to be of an equivalent or greater magnitude than high-elevation summer moonlight (30). Understanding the biogeography of time partitioning by organisms provides a first step toward determining where such changes are likely to have the greatest impact.In this paper, we (i) document basic biogeographic patterns of time partitioning by organisms, using terrestrial mammals as a case study; (ii) document ecologically relevant large-scale patterns of natural variation in “biologically useful” natural light, constrained by temperature; and (iii) determine how well the first of these are predicted by the second. Mammals provide an interesting study group, being globally distributed, occupying a broad range of environments, and exhibiting a wide diversity of time-partitioning behavior. Much concern has also been expressed as to the potential impacts of nighttime light pollution on the group, and there are many studies documenting significant influences (31, 32). Due to the global nature of this study, and the paucity of detailed information on time partitioning reported for many species, our focus is on a high-level categorization, allocating species to one of four temporal niches: nocturnal, diurnal, cathemeral, and crepuscular (Fig. 1), albeit with the acknowledgment that in many species behavior occurs along a continuum of possible strategies that may be more flexible and complex.Open in a separate windowFig. 1.Examples of recorded diel activity patterns illustrating the four main time-partitioning strategies used to classify terrestrial mammals in this study (64–67).     

Geospatial revolution and remote sensing LiDAR in Mesoamerican archaeology

The application of light detection and ranging (LiDAR), a laser-based remote-sensing technology that is capable of penetrating overlying vegetation and forest canopies, is generating a fundamental shift in Mesoamerican archaeology and has the potential to transform research in forested areas world-wide. Much as radiocarbon dating that half a century ago moved archaeology forward by grounding archaeological remains in time, LiDAR is proving to be a catalyst for an improved spatial understanding of the past. With LiDAR, ancient societies can be contextualized within a fully defined landscape. Interpretations about the scale and organization of densely forested sites no longer are constrained by sample size, as they were when mapping required laborious on-ground survey. The ability to articulate ancient landscapes fully permits a better understanding of the complexity of ancient Mesoamerican urbanism and also aids in modern conservation efforts. The importance of this geospatial innovation is demonstrated with newly acquired LiDAR data from the archaeological sites of Caracol, Cayo, Belize and Angamuco, Michoacán, Mexico. These data illustrate the potential of technology to act as a catalytic enabler of rapid transformational change in archaeological research and interpretation and also underscore the value of on-the-ground archaeological investigation in validating and contextualizing results.     

老年高血压患者血压节律变化与靶器官损害的关系

目的 探讨老年高血压患者血压节律变化与靶器官损害的关系. 方法 70例老年高血压患者均行24h动态血压检测、颈动脉超声和超声心动图检查,根据24 h动态血压检测结果分为2组:勺形组40例及非勺形组30例,并对2组颈动脉粥样硬化(CAS)、左室肥厚(LVH)及动态血压各参数进行比较. 结果 CAS及LVH检出率非勺形组均高于勺形组(P＜0.01);2组间24 h平均收缩压(24hSBP)及舒张压(24hDBP)、24 h收缩压和舒张压负荷值(24hSBPL、24hDBPL),差异无统计学意义(P＞0.05).勺形组白天平均收缩压(dSBP)及舒张压(dDBP)、白天收缩压和舒张压负荷值(dSBPL、dDBPL)高于非勺形组(P＜0.05).勺形组夜间平均收缩压(nSBP)及舒张压(nDBP)、夜间收缩压和舒张压负荷值(nSBPL、nDBPL)明显低于非勺形组(P＜0.01). 结论 老年高血压患者血压节律变化的消失与靶器官损害关系密切,高血压患者降压治疗的同时还需纠正紊乱的血压昼夜节律.     

A position anchor sinks the double-drift illusion

When the internal texture of a Gabor patch moves orthogonally to its envelope''s motion, the perceived path, viewed in the periphery, shifts dramatically in position, and direction relative to the true path (the double-drift illusion). Here, we examine positional uncertainty as a critical factor underlying this illusory shift. We presented participants with an anchoring line at different distances from the drifting Gabor''s physical path. Our results indicate that placing an anchor (a fixed line) close to the Gabor''s path halved the magnitude of the illusion. This suppression was symmetrical for anchors placed on either side of the Gabor. In a second experiment, we used crowding to degrade the anchoring line''s position information by embedding it in a set of parallel lines. In this case, despite the presence of the same lines that reduced the illusion when presented in isolation, the illusory shift was now largely restored. We suggest that the adjacent lines crowded each other, reducing their positional certainty, and thus their ability to anchor the location of the moving Gabor. These findings indicate that the positional uncertainty of the equiluminant Gabor patch is critical for the illusory position offset.     

Perceived color shift of ceramics according to the change of illuminating light with spectroradiometer

PURPOSE

Perceived color of ceramics changes by the spectral power distribution of ambient light. This study aimed to quantify the amount of shifts in color and color coordinates of clinically simulated seven all-ceramics due to the switch of three ambient light sources using a human vision simulating spectroradiometer.

MATERIALS AND METHODS

CIE color coordinates, such as L*, a* and b*,of ceramic specimens were measured under three light sources, which simulate the CIE standard illuminant D65 (daylight), A (incandescent lamp), and F9 (fluorescent lamp). Shifts in color and color coordinate by the switch of lights were determined. Influence of the switched light (D65 to A, or D65 to F9), shade of veneer ceramics (A2 or A3), and brand of ceramics on the shifts was analyzed by a three-way ANOVA.

RESULTS

Shifts in color and color coordinates were influenced by three factors (P<.05). Color shifts by the switch to A were in the range of 5.9 to 7.7 ΔE*_abunits, and those by the switch to F9 were 7.7 to 10.2; all of which were unacceptable (ΔE*_ab > 5.5). When switched to A, CIE a* increased (Δa*: 5.6 to 7.6), however, CIE b* increased (Δb*: 4.9 to 7.8) when switched to F9.

CONCLUSION

Clinically simulated ceramics demonstrated clinically unacceptable color shifts according to the switches in ambient lights based on spectroradiometric readings. Therefore, shade matching and compatibility evaluation should be performed considering ambient lighting conditions and should be done under most relevant lighting condition.     

The influence of shift work on cognitive functions and oxidative stress

Shift work influences health, performance, activity, and social relationships, and it causes impairment in cognitive functions. In this study, we investigated the effects of shift work on participants' cognitive functions in terms of memory, attention, and learning, and we measured the effects on oxidative stress. Additionally, we investigated whether there were significant relationships between cognitive functions and whole blood oxidant/antioxidant status of participants. A total of 90 health care workers participated in the study, of whom 45 subjects were night-shift workers. Neuropsychological tests were administered to the participants to assess cognitive function, and blood samples were taken to detect total antioxidant capacity and total oxidant status at 08:00. Differences in anxiety, depression, and chronotype characteristics between shift work groups were not significant. Shift workers achieved significantly lower scores on verbal memory, attention–concentration, and the digit span forward sub-scales of the Wechsler Memory Scale-Revised (WMS-R), as well as on the immediate memory and total learning sub-scales of the Auditory Verbal Learning Test (AVLT). Oxidative stress parameters were significantly associated with some types of cognitive function, including attention–concentration, recognition, and long-term memory. These findings suggest that night shift work may result in significantly poorer cognitive performance, particularly working memory.