scholarly article | Q13442814 |
P50 | author | Martin Eimer | Q1790491 |
P2093 | author name string | Monika Kiss | |
José Van Velzen | |||
P2860 | cites work | Neural activity predicts individual differences in visual working memory capacity. | Q52001274 |
Prior information of stimulus location: effects on ERP measures of visual selection and response selection. | Q52029030 | ||
Effects of hand posture on preparatory control processes and sensory modulations in tactile-spatial attention. | Q52091697 | ||
Shifting visual attention in space: an electrophysiological analysis using high spatial resolution mapping. | Q52167112 | ||
Electrophysiological measurement of rapid shifts of attention during visual search | Q59070140 | ||
Spherical splines for scalp potential and current density mapping | Q69052761 | ||
The spatial allocation of visual attention as indexed by event-related brain potentials | Q69134912 | ||
Serial deployment of attention during visual search | Q73202800 | ||
Frontoparietal control of spatial attention and motor intention in human EEG | Q81470541 | ||
Electrophysiological evidence of the capture of visual attention | Q83973328 | ||
Neural processes involved in directing attention | Q87295842 | ||
Event-related brain potentials in the study of visual selective attention | Q24601030 | ||
Neural sources of focused attention in visual search | Q33924933 | ||
The N2pc component as an indicator of attentional selectivity | Q34402025 | ||
Attentional selection and identification of visual objects are reflected by distinct electrophysiological responses | Q36481712 | ||
Attentional capture by task-irrelevant fearful faces is revealed by the N2pc component. | Q36643244 | ||
Electrophysiological correlates of change detection. | Q36646292 | ||
Efficient attentional selection predicts distractor devaluation: event-related potential evidence for a direct link between attention and emotion | Q36678735 | ||
The interdependence of spatial attention and lexical access as revealed by early asymmetries in occipito-parietal ERP activity. | Q38398463 | ||
Neural mechanisms of visual selective attention | Q40605037 | ||
Spatial filtering during visual search: evidence from human electrophysiology | Q46225654 | ||
The role of attention in different visual-search tasks | Q46376238 | ||
"Sensory gating" as a mechanism for visuospatial orienting: electrophysiological evidence from trial-by-trial cuing experiments | Q48111928 | ||
Electroencephalographic activity associated with shifts of visuospatial attention | Q48112719 | ||
Electrophysiological evidence of central interference in the control of visuospatial attention | Q48147593 | ||
Shifts of attention in the early blind: an erp study of attentional control processes in the absence of visual spatial information. | Q48546833 | ||
Cross-modal interactions between audition, touch, and vision in endogenous spatial attention: ERP evidence on preparatory states and sensory modulations. | Q48624262 | ||
Modulations of sensory-evoked brain potentials indicate changes in perceptual processing during visual-spatial priming | Q48627901 | ||
Fundamental properties of the N2pc as an index of spatial attention: effects of masking. | Q50706633 | ||
On the control of visual spatial attention: evidence from human electrophysiology. | Q50753308 | ||
The dynamics of shifting visuospatial attention revealed by event-related potentials. | Q50757612 | ||
Spatial attention freezes during the attention blink. | Q51980119 | ||
Electrophysiological measures of maintaining representations in visual working memory. | Q51992901 | ||
P433 | issue | 2 | |
P407 | language of work or name | English | Q1860 |
P921 | main subject | attention | Q6501338 |
P304 | page(s) | 240-249 | |
P577 | publication date | 2007-10-26 | |
P1433 | published in | Psychophysiology | Q15716416 |
P1476 | title | The N2pc component and its links to attention shifts and spatially selective visual processing | |
P478 | volume | 45 |
Q37378627 | A cuing study of the N2pc component: an index of attentional deployment to objects rather than spatial locations |
Q46345159 | Age group and individual differences in attentional orienting dissociate neural mechanisms of encoding and maintenance in visual STM. |
Q37069420 | Attentional capture by visual singletons is mediated by top-down task set: new evidence from the N2pc component. |
Q44746695 | Attentional capture during visual search is attenuated by target predictability: evidence from the N2pc, Pd, and topographic segmentation |
Q47328845 | Attentional gain is modulated by probabilistic feature expectations in a spatial cueing task: ERP evidence. |
Q91591362 | Between one event and two: The locus of the effect of stimulus contrast on temporal integration |
Q61947469 | Brain-Machine Interfaces for Assistive Robotics |
Q47117080 | Changes of Attention during Value-Based Reversal Learning Are Tracked by N2pc and Feedback-Related Negativity |
Q52565535 | Cortical mechanisms of prioritizing selection for rejection in visual search. |
Q89700489 | Covert Spatial Attention Speeds Target Individuation |
Q37427092 | Does focused endogenous attention prevent attentional capture in pop-out visual search? |
Q41988742 | ERP markers of target selection discriminate children with high vs. low working memory capacity |
Q39982943 | Electrophysiological Evidence of Atypical Spatial Attention in Those with a High Level of Self-reported Autistic Traits. |
Q35067544 | Electrophysiological correlates of amnestic mild cognitive impairment in a simon task. |
Q92132750 | Electrophysiological correlates of the flexible allocation of visual working memory resources |
Q48442652 | Electrophysiological evidence for inhibition of return effect in exogenous orienting |
Q38378550 | Electrophysiological evidence of semantic interference in visual search |
Q42114580 | Elucidating unconscious processing with instrumental hypnosis |
Q33393635 | Express attentional re-engagement but delayed entry into consciousness following invalid spatial cues in visual search |
Q36294131 | Facilitation or disengagement? Attention bias in facial affect processing after short-term violent video game exposure |
Q50505287 | Feature singletons attract spatial attention independently of feature priming. |
Q36094189 | How the speed of motor-response decisions, but not focal-attentional selection, differs as a function of task set and target prevalence |
Q35575381 | Inhibition deficit in the spatial tendency of the response in multiple-domain amnestic mild cognitive impairment. An event-related potential study |
Q36929290 | Involuntary attentional capture is determined by task set: evidence from event-related brain potentials |
Q34124332 | Long-term memories bias sensitivity and target selection in complex scenes |
Q57788753 | Money or smiles: Independent ERP effects of associated monetary reward and happy faces |
Q41585126 | Multimodal neuroimaging evidence linking memory and attention systems during visual search cued by context |
Q51854727 | Negative attentional set in the attentional blink: control is not lost. |
Q92782495 | Neural Dynamics of Cognitive Control over Working Memory Capture of Attention |
Q58093073 | Neural correlates of goal-directed enhancement and suppression of visual stimuli in the absence of conscious perception |
Q33889231 | Neural mechanisms of human perceptual learning: electrophysiological evidence for a two-stage process |
Q34506042 | Perceptual grouping and visual enumeration |
Q37592723 | Practice begets the second target: task repetition and the attentional blink effect |
Q48514480 | Rebalancing Spatial Attention: Endogenous Orienting May Partially Overcome the Left Visual Field Bias in Rapid Serial Visual Presentation |
Q48335801 | Reward associations magnify memory-based biases on perception. |
Q47139707 | Scopolamine Reduces Electrophysiological Indices of Distractor Suppression: Evidence from a Contingent Capture Task |
Q51931913 | Searching for targets within the spatial layout of visual short-term memory. |
Q30470796 | Seeing emotion with your ears: emotional prosody implicitly guides visual attention to faces |
Q48110629 | Shifting visual attention away from fixation is specifically associated with alpha band activity over ipsilateral parietal regions |
Q39252188 | Spatial attention across perception and action |
Q50565516 | Spatial attention facilitates assembly of the briefest percepts: Electrophysiological evidence from color fusion. |
Q37184671 | Spatial selection of features within perceived and remembered objects |
Q33840992 | Temporal brain dynamics of multiple object processing: the flexibility of individuation |
Q47351109 | The N2pc component reliably captures attentional bias in social anxiety |
Q49030224 | The Rapid Capture of Attention by Rewarded Objects. |
Q48527920 | The deployment of visual attention during temporal integration: an electrophysiological investigation |
Q40202383 | The effects of self-focus on attentional biases in social anxiety:An ERP study |
Q36152112 | The face is more than its parts--brain dynamics of enhanced spatial attention to schematic threat |
Q36984644 | The lasting memory enhancements of retrospective attention |
Q37428875 | The roles of feature-specific task set and bottom-up salience in attentional capture: an ERP study. |
Q43595099 | Top-down task sets for combined features: behavioral and electrophysiological evidence for two stages in attentional object selection. |
Q48593063 | Toward the influence of temporal attention on the selection of targets in a visual search task: An ERP study |
Q48369948 | Tuning perceptual competition |
Q50642968 | Two visual targets for the price of one? Pupil dilation shows reduced mental effort through temporal integration. |
Q39123896 | Understanding how visual attention locks on to a location: Toward a computational model of the N2pc component |
Q33692286 | Value associations of emotional faces can modify the anger superiority effect: behavioral and electrophysiological evidence |
Q35871389 | Value-based attentional capture influences context-dependent decision-making |
Q37688739 | Variations in the magnitude of attentional capture: testing a two-process model |
Q47600785 | Visual working memory representations guide the detection of emotional faces: An ERP study |
Q48703713 | What You See Is What You Remember: Visual Chunking by Temporal Integration Enhances Working Memory. |
Q51915743 | What is top-down about contingent capture? |
Q36673859 | Working memory as internal attention: toward an integrative account of internal and external selection processes |
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