PsycINFO Search Summary
Search Terms / Articles Yielded / Date
"contingent capture AND attention capture" / 63 / 9/15/2013
"onset AND attention capture" / 51 / 9/15/2013
"new object AND attention capture" / 43 / 3/12/2013
Total Unique Articles / 120
Paradigm Classification
Paradigm / Definition
Spatial Cuing / Participants search a display for a target defined by a simple stimulus feature (e.g., shape, letter, color). An onset cue appears before a search display. The onset cue is nonpredictive of target location (valid on 1/n trials, where n = setsize). The primary capture measure is cue validity effects(faster valid RTs than invalid RTs).
Irrelevant Feature / Participants search a display for a target defined by a simple stimulus feature (e.g., shape, letter, color). A nonpredictive onset appears during a search display. The onset is nonpredictive of target location (target on 1/n trials). The primary measure of capture are search slopes (flatter slopes when the onset is the target than a distractor.
Additional Singleton / Participants search a display for a target defined by a simple stimulus feature (e.g., shape, letter, color). An antipredictive onset appears at a distractor location during search. The onset never appears at a distractor location. The primary measure of capture are singleton-presence costs (faster RTs when the onset is absent than present).
Other / Paradigms that cannot be classified as one of the above paradigms.
* In the typical IFP, ASP, or Spatial Cuing Paradigm, the participant has no foreknowledge of the target locations. Studies where the participants had foreknowledge of the target location (e.g., via central cuing) were classified as "other"

Excluded Articles

Article / Exp. / Exclusion Reason
Ariga, A., & Yokosawa, K. (2006). Semantic activation of target congruence contingently captures attention. The Japanese Journal of Psychonomic Science, 25(2), 285–286. / 1A / (1) Not a study of involuntary capture
Ariga, A., & Yokosawa, K. (2006). Semantic activation of target congruence contingently captures attention. The Japanese Journal of Psychonomic Science, 25(2), 285–286. / 1B / (1) Not a study of involuntary capture
Ariga, A., & Yokosawa, K. (2006). Semantic activation of target congruence contingently captures attention. The Japanese Journal of Psychonomic Science, 25(2), 285–286. / 2A / (1) Not a study of involuntary capture
Ariga, A., & Yokosawa, K. (2006). Semantic activation of target congruence contingently captures attention. The Japanese Journal of Psychonomic Science, 25(2), 285–286. / 2B / (1) Not a study of involuntary capture
Astle, D. E., Nobre, A. C., & Scerif, G. (2010). Subliminally presented and stored objects capture spatial attention. The Journal of Neuroscience, 30(10), 3567–3571. / 1 / (1) Not a study of involuntary capture
Astle, D. E., Nobre, A. C., & Scerif, G. (2010). Subliminally presented and stored objects capture spatial attention. The Journal of Neuroscience, 30(10), 3567–3571. / 2 / (1) Not a study of involuntary capture
Astle, D. E., Nobre, A. C., & Scerif, G. (2010). Subliminally presented and stored objects capture spatial attention. The Journal of Neuroscience, 30(10), 3567–3571. / 3 / (1) Not a study of involuntary capture
Barcelo, F., Escera, C., Corral, M. J., & Periáñez, J. A. (2006). Task Switching and Novelty Processing Activate a Common Neural Network for Cognitive Control. Journal of Cognitive Neuroscience, 18(10), 1734–1748. / 1 / (1) Not a study of involuntary capture
Cole, G., Gellatly, A., & Blurton, A. (2001). Effect of object onset on the distribution of visual attention. Journal of Experimental Psychology: Human Perception and Performance, 27(6), 1356–1368. / 1 / (1) Not a study of involuntary capture
Cole, G., Gellatly, A., & Blurton, A. (2001). Effect of object onset on the distribution of visual attention. Journal of Experimental Psychology: Human Perception and Performance, 27(6), 1356–1368. / 2 / (1) Not a study of involuntary capture
Cole, G., Gellatly, A., & Blurton, A. (2001). Effect of object onset on the distribution of visual attention. Journal of Experimental Psychology: Human Perception and Performance, 27(6), 1356–1368. / 3 / (1) Not a study of involuntary capture
Cole, G., Gellatly, A., & Blurton, A. (2001). Effect of object onset on the distribution of visual attention. Journal of Experimental Psychology: Human Perception and Performance, 27(6), 1356–1368. / 4 / (1) Not a study of involuntary capture
Cole, G., Gellatly, A., & Blurton, A. (2001). Effect of object onset on the distribution of visual attention. Journal of Experimental Psychology: Human Perception and Performance, 27(6), 1356–1368. / 5 / (1) Not a study of involuntary capture
Cole, G., Gellatly, A., & Blurton, A. (2001). Effect of object onset on the distribution of visual attention. Journal of Experimental Psychology: Human Perception and Performance, 27(6), 1356–1368. / 6 / (1) Not a study of involuntary capture
Cole, G., Gellatly, A., & Blurton, A. (2001). Effect of object onset on the distribution of visual attention. Journal of Experimental Psychology: Human Perception and Performance, 27(6), 1356–1368. / 7 / (1) Not a study of involuntary capture
Dowman, R. (2011). The role of somatic threat feature detectors in the attentional bias toward pain: Effects of spatial attention. Psychophysiology, 48(3), 397–409. / 1 / (1) Not a study of involuntary capture
Fellrath, J., Blanche-Durbec, V., Schnider, A., Jacquemoud, A.-S., & Ptak, R. (2012). Visual search in spatial neglect studied with a preview paradigm. Frontiers in Human Neuroscience, 6. / 1 / (1) Not a study of involuntary capture
Folk, C. L., Remington, R. W., & Johnston, J. C. (1992). Involuntary covert orienting is contingent on attentional control settings. Journal of Experimental Psychology: Human Perception and Performance, 18(4), 1030–1044. / 1 / (1) Not a study of involuntary capture
Gellatly, A., Cole, G., & Blurton, A. (1999). Do equiluminant object onsets capture visual attention? Journal of Experimental Psychology: Human Perception and Performance, 25(6), 1609–1624. / 5 / (1) Not a study of involuntary capture
Hahn, S., & Kramer, A. F. (1998). Further evidence for the division of attention among non-contiguous locations. Visual Cognition, 5(1-2), 217–256. / 1 / (1) Not a study of involuntary capture
Hahn, S., & Kramer, A. F. (1998). Further evidence for the division of attention among non-contiguous locations. Visual Cognition, 5(1-2), 217–256. / 2 / (1) Not a study of involuntary capture
Hahn, S., & Kramer, A. F. (1998). Further evidence for the division of attention among non-contiguous locations. Visual Cognition, 5(1-2), 217–256. / 3 / (1) Not a study of involuntary capture
Hahn, S., & Kramer, A. F. (1998). Further evidence for the division of attention among non-contiguous locations. Visual Cognition, 5(1-2), 217–256. / 5 / (1) Not a study of involuntary capture
Hahn, S., & Kramer, A. F. (1998). Further evidence for the division of attention among non-contiguous locations. Visual Cognition, 5(1-2), 217–256. / 4 / (1) Not a study of involuntary capture
Homa, D., Newton, C., Terry, D., Schafer, S., & Richter, K. (2007). Memory search following valid and invalid abrupt-onset cues. The American Journal of Psychology, 120(3), 383–413. / 1 / (1) Not a study of involuntary capture
Homa, D., Newton, C., Terry, D., Schafer, S., & Richter, K. (2007). Memory search following valid and invalid abrupt-onset cues. The American Journal of Psychology, 120(3), 383–413. / 2 / (1) Not a study of involuntary capture
Homa, D., Newton, C., Terry, D., Schafer, S., & Richter, K. (2007). Memory search following valid and invalid abrupt-onset cues. The American Journal of Psychology, 120(3), 383–413. / 3 / (1) Not a study of involuntary capture
Homa, D., Newton, C., Terry, D., Schafer, S., & Richter, K. (2007). Memory search following valid and invalid abrupt-onset cues. The American Journal of Psychology, 120(3), 383–413. / 4 / (1) Not a study of involuntary capture
Horstmann, G., & Ansorge, U. (2006). Attentional shifts to rare singletons. Visual Cognition, 14(3), 295–325. / 3 / (1) Not a study of involuntary capture
Kunar, M. A., & Watson, D. G. (2013). When Are Abrupt Onsets Found Efficiently in Complex Visual Search? Evidence From Multielement Asynchronous Dynamic Search. Journal of Experimental Psychology: Human Perception and Performance. / 1 / (1) Not a study of involuntary capture
Kunar, M. A., & Watson, D. G. (2013). When Are Abrupt Onsets Found Efficiently in Complex Visual Search? Evidence From Multielement Asynchronous Dynamic Search. Journal of Experimental Psychology: Human Perception and Performance. / 2 / (1) Not a study of involuntary capture
Kunar, M. A., & Watson, D. G. (2013). When Are Abrupt Onsets Found Efficiently in Complex Visual Search? Evidence From Multielement Asynchronous Dynamic Search. Journal of Experimental Psychology: Human Perception and Performance. / 3 / (1) Not a study of involuntary capture
Kunar, M. A., & Watson, D. G. (2013). When Are Abrupt Onsets Found Efficiently in Complex Visual Search? Evidence From Multielement Asynchronous Dynamic Search. Journal of Experimental Psychology: Human Perception and Performance. / 4 / (1) Not a study of involuntary capture
Kunar, M. A., & Watson, D. G. (2013). When Are Abrupt Onsets Found Efficiently in Complex Visual Search? Evidence From Multielement Asynchronous Dynamic Search. Journal of Experimental Psychology: Human Perception and Performance. / 5 / (1) Not a study of involuntary capture
Kunar, M. A., & Watson, D. G. (2013). When Are Abrupt Onsets Found Efficiently in Complex Visual Search? Evidence From Multielement Asynchronous Dynamic Search. Journal of Experimental Psychology: Human Perception and Performance. / 6 / (1) Not a study of involuntary capture
Kunar, M. A., & Watson, D. G. (2013). When Are Abrupt Onsets Found Efficiently in Complex Visual Search? Evidence From Multielement Asynchronous Dynamic Search. Journal of Experimental Psychology: Human Perception and Performance. / 7 / (1) Not a study of involuntary capture
Kunar, M. A., & Watson, D. G. (2013). When Are Abrupt Onsets Found Efficiently in Complex Visual Search? Evidence From Multielement Asynchronous Dynamic Search. Journal of Experimental Psychology: Human Perception and Performance. / 8 / (1) Not a study of involuntary capture
Lien, M.-C., Ruthruff, E., Goodin, Z., & Remington, R. W. (2008). Contingent attentional capture by top-down control settings: Converging evidence from event-related potentials. Journal of Experimental Psychology: Human Perception and Performance, 34(3), 509–530. / 1 / (1) Not a study of involuntary capture
Lin, Z. (2013). Voluntary Spatial Attention Induces Spatial Facilitation and Object-Centered Suppression. Journal of Experimental Psychology: Human Perception and Performance. / 1 / (1) Not a study of involuntary capture
Lin, Z. (2013). Voluntary Spatial Attention Induces Spatial Facilitation and Object-Centered Suppression. Journal of Experimental Psychology: Human Perception and Performance. / 3 / (1) Not a study of involuntary capture
Lin, Z. (2013). Voluntary Spatial Attention Induces Spatial Facilitation and Object-Centered Suppression. Journal of Experimental Psychology: Human Perception and Performance. / 4 / (1) Not a study of involuntary capture
Lin, Z. (2013). Voluntary Spatial Attention Induces Spatial Facilitation and Object-Centered Suppression. Journal of Experimental Psychology: Human Perception and Performance. / 2A / (1) Not a study of involuntary capture
Lin, Z. (2013). Voluntary Spatial Attention Induces Spatial Facilitation and Object-Centered Suppression. Journal of Experimental Psychology: Human Perception and Performance. / 2B / (1) Not a study of involuntary capture
Maringelli, F., & Umiltà, C. (1998). The control of the attentional focus. European Journal of Cognitive Psychology, 10(3), 225–246. / 2 / (1) Not a study of involuntary capture
Maringelli, F., & Umiltà, C. (1998). The control of the attentional focus. European Journal of Cognitive Psychology, 10(3), 225–246. / 3 / (1) Not a study of involuntary capture
Maringelli, F., & Umiltà, C. (1998). The control of the attentional focus. European Journal of Cognitive Psychology, 10(3), 225–246. / 1A / (1) Not a study of involuntary capture
Maringelli, F., & Umiltà, C. (1998). The control of the attentional focus. European Journal of Cognitive Psychology, 10(3), 225–246. / 1B / (1) Not a study of involuntary capture
Maringelli, F., & Umiltà, C. (1998). The control of the attentional focus. European Journal of Cognitive Psychology, 10(3), 225–246. / 1C / (1) Not a study of involuntary capture
Müller-Plath, G., & Klöckner, N. (2013). Exogenous attention can be counter-selective: Onset cues disrupt sensitivity to color changes. Psychological Research. / 1 / (1) Not a study of involuntary capture
Müller-Plath, G., & Klöckner, N. (2013). Exogenous attention can be counter-selective: Onset cues disrupt sensitivity to color changes. Psychological Research. / 2 / (1) Not a study of involuntary capture
Müller-Plath, G., & Klöckner, N. (2013). Exogenous attention can be counter-selective: Onset cues disrupt sensitivity to color changes. Psychological Research. / 3 / (1) Not a study of involuntary capture
Pinto, Y., Olivers, C. N. L., & Theeuwes, J. (2008). Static items are automatically prioritized in a dynamic environment. Visual Cognition, 16(7), 916–932. / 1 / (1) Not a study of involuntary capture
Pinto, Y., Olivers, C. N. L., & Theeuwes, J. (2008). Static items are automatically prioritized in a dynamic environment. Visual Cognition, 16(7), 916–932. / 2 / (1) Not a study of involuntary capture
Pinto, Y., Olivers, C. N. L., & Theeuwes, J. (2008). Static items are automatically prioritized in a dynamic environment. Visual Cognition, 16(7), 916–932. / 3 / (1) Not a study of involuntary capture
Porter, G., Wright, A., Tales, A., & Gilchrist, I. D. (2012). Stimulus onsets and distraction in younger and older adults. Psychology and Aging, 27(4), 1111–1119. / 1 / (1) Not a study of involuntary capture
Porter, G., Wright, A., Tales, A., & Gilchrist, I. D. (2012). Stimulus onsets and distraction in younger and older adults. Psychology and Aging, 27(4), 1111–1119. / 2 / (1) Not a study of involuntary capture
Rauschenberger, R. (2003). When something old becomes something new: Spatiotemporal object continuity and attentional capture. Journal of Experimental Psychology: Human Perception and Performance, 29(3), 600–615. / 5 / (1) Not a study of involuntary capture
Turatto, M., Bettella, S., Umiltà, C., & Bridgeman, B. (2003). Perceptual conditions necessary to induce change blindness. Visual Cognition, 10(2), 233–255. / 1 / (1) Not a study of involuntary capture
Turatto, M., Bettella, S., Umiltà, C., & Bridgeman, B. (2003). Perceptual conditions necessary to induce change blindness. Visual Cognition, 10(2), 233–255. / 2 / (1) Not a study of involuntary capture
Turatto, M., Bettella, S., Umiltà, C., & Bridgeman, B. (2003). Perceptual conditions necessary to induce change blindness. Visual Cognition, 10(2), 233–255. / 3 / (1) Not a study of involuntary capture
Turatto, M., Bettella, S., Umiltà, C., & Bridgeman, B. (2003). Perceptual conditions necessary to induce change blindness. Visual Cognition, 10(2), 233–255. / 4 / (1) Not a study of involuntary capture
Turatto, M., Bettella, S., Umiltà, C., & Bridgeman, B. (2003). Perceptual conditions necessary to induce change blindness. Visual Cognition, 10(2), 233–255. / 5 / (1) Not a study of involuntary capture
Warner, C. B., Juola, J. F., & Koshino, H. (1990). Voluntary allocation versus automatic capture of visual attention. Perception & Psychophysics, 48(3), 243–251. / 1 / (1) Not a study of involuntary capture
Warner, C. B., Juola, J. F., & Koshino, H. (1990). Voluntary allocation versus automatic capture of visual attention. Perception & Psychophysics, 48(3), 243–251. / 1 / (1) Not a study of involuntary capture
Watson, D. G., & Humphreys, G. W. (1995a). Attention capture by contour onsets and offsets: No special role for onsets. Perception & Psychophysics, 57(5), 583–597. / 1A / (1) Not a study of involuntary capture
Wong, J. H., Peterson, M. S., & Hillstrom, A. P. (2007). Are changes in semantic and structural information sufficient for oculomotor capture? Journal of Vision, 7(12), 1–10. / 1 / (1) Not a study of involuntary capture
Yantis, S. (1993a). Stimulus-driven attentional capture and attentional control settings. Journal of Experimental Psychology: Human Perception and Performance, 19(3), 676–681. / 1 / (1) Not a study of involuntary capture
Yantis, S. (1993b). Stimulus-driven attentional capture. Current Directions in Psychological Science, 2(5), 156–161. / 1 / (1) Not a study of involuntary capture
Yantis, S., & Jonides, J. (1984). Abrupt visual onsets and selective attention: Evidence from visual search. Journal of Experimental Psychology: Human Perception and Performance, 10(5), 601–621. / 2 / (1) Not a study of involuntary capture
Adamo, M., Pun, C., Pratt, J., & Ferber, S. (2008). Your divided attention, please! The maintenance of multiple attentional control sets over distinct regions in space. Cognition, 107(1), 295–303. / 1 / (2) No abrupt onsets
Al-Aidroos, N., Guo, R. M., & Pratt, J. (2010). You can’t stop new motion: Attentional capture despite a control set for colour. Visual Cognition, 18(6), 859–880. / 1 / (2) No abrupt onsets
Al-Aidroos, N., Guo, R. M., & Pratt, J. (2010). You can’t stop new motion: Attentional capture despite a control set for colour. Visual Cognition, 18(6), 859–880. / 2 / (2) No abrupt onsets
Al-Aidroos, N., Guo, R. M., & Pratt, J. (2010). You can’t stop new motion: Attentional capture despite a control set for colour. Visual Cognition, 18(6), 859–880. / 3 / (2) No abrupt onsets
Al-Aidroos, N., Harrison, S., & Pratt, J. (2010). Attentional control settings prevent abrupt onsets from capturing visual spatial attention. The Quarterly Journal of Experimental Psychology, 63(1), 31–41. / 1 / (2) No abrupt onsets
Anderson, B. A., & Folk, C. L. (2012). Dissociating location-specific inhibition and attention shifts: Evidence against the disengagement account of contingent capture. Attention, Perception, & Psychophysics, 74(6), 1183–1198. / 1 / (2) No abrupt onsets
Anderson, B. A., & Folk, C. L. (2012). Dissociating location-specific inhibition and attention shifts: Evidence against the disengagement account of contingent capture. Attention, Perception, & Psychophysics, 74(6), 1183–1198. / 2 / (2) No abrupt onsets
Anderson, B. A., & Folk, C. L. (2012). Dissociating location-specific inhibition and attention shifts: Evidence against the disengagement account of contingent capture. Attention, Perception, & Psychophysics, 74(6), 1183–1198. / 3 / (2) No abrupt onsets
Anderson, B. A., & Folk, C. L. (2012). Dissociating location-specific inhibition and attention shifts: Evidence against the disengagement account of contingent capture. Attention, Perception, & Psychophysics, 74(6), 1183–1198. / 4 / (2) No abrupt onsets
Anderson, B. A., & Folk, C. L. (2012). Dissociating location-specific inhibition and attention shifts: Evidence against the disengagement account of contingent capture. Attention, Perception, & Psychophysics, 74(6), 1183–1198. / 5 / (2) No abrupt onsets
Anderson, B. A., & Folk, C. L. (2012). Dissociating location-specific inhibition and attention shifts: Evidence against the disengagement account of contingent capture. Attention, Perception, & Psychophysics, 74(6), 1183–1198. / 6 / (2) No abrupt onsets
Ansorge, U., & Becker, S. I. (2013). Contingent capture in cueing: The role of color search templates and cue-target color relations. Psychological Research. / 1 / (2) No abrupt onsets
Ansorge, U., Horstmann, G., & Carbone, E. (2005). Top-down contingent capture by color: Evidence from RT distribution analyses in a manual choice reaction task. ActaPsychologica, 120(3), 243–266. / 1 / (2) No abrupt onsets
Ansorge, U., Horstmann, G., & Carbone, E. (2005). Top-down contingent capture by color: Evidence from RT distribution analyses in a manual choice reaction task. ActaPsychologica, 120(3), 243–266. / 2 / (2) No abrupt onsets
Ansorge, U., Kiss, M., & Eimer, M. (2009). Goal-driven attentional capture by invisible colors: Evidence from event-related potentials. Psychonomic Bulletin & Review, 16(4), 648–653. / 1 / (2) No abrupt onsets
Ariga, A., & Yokosawa, K. (2008). Contingent attentional capture occurs by activated target congruence. Perception & Psychophysics, 70(4), 680–687. / 1A / (2) No abrupt onsets
Ariga, A., & Yokosawa, K. (2008). Contingent attentional capture occurs by activated target congruence. Perception & Psychophysics, 70(4), 680–687. / 1B / (2) No abrupt onsets
Ariga, A., & Yokosawa, K. (2008). Contingent attentional capture occurs by activated target congruence. Perception & Psychophysics, 70(4), 680–687. / 2A / (2) No abrupt onsets
Ariga, A., & Yokosawa, K. (2008). Contingent attentional capture occurs by activated target congruence. Perception & Psychophysics, 70(4), 680–687. / 2B / (2) No abrupt onsets
Atchley, P., Kramer, A. F., & Hillstrom, A. P. (2000). Contingent capture for onsets and offsets: Attentional set for perceptual transients. Journal of Experimental Psychology: Human Perception and Performance, 26(2), 594–606. / 4 / (2) No abrupt onsets
Becker, S. I., Folk, C. L., & Remington, R. W. (2010). The role of relational information in contingent capture. Journal of Experimental Psychology: Human Perception and Performance, 36(6), 1460–1476. / 1 / (2) No abrupt onsets
Becker, S. I., Folk, C. L., & Remington, R. W. (2010). The role of relational information in contingent capture. Journal of Experimental Psychology: Human Perception and Performance, 36(6), 1460–1476. / 2 / (2) No abrupt onsets
Becker, S. I., Folk, C. L., & Remington, R. W. (2010). The role of relational information in contingent capture. Journal of Experimental Psychology: Human Perception and Performance, 36(6), 1460–1476. / 3 / (2) No abrupt onsets
Brisson, B., Leblanc, É.,Jolicœur, P. (2009). Contingent capture of visual-spatial attention depends on capacity-limited central mechanisms: Evidence from human electrophysiology and the psychological refractory period. Biological Psychology, 80(2), 218–225. / 1 / (2) No abrupt onsets
Brockmole, J. R., & Henderson, J. M. (2008). Prioritizing new objects for eye fixation in real-world scenes: Effects of object-scene consistency. Visual Cognition, 16(2-3), 375–390. / 1 / (2) No abrupt onsets
Burnham, B. R., & Neely, J. H. (2007). Involuntary capture of visual-spatial attention occurs for intersections, both real and “imagined.” Psychonomic Bulletin & Review, 14(4), 735–741. / 1 / (2) No abrupt onsets
Burnham, B. R., & Neely, J. H. (2007). Involuntary capture of visual-spatial attention occurs for intersections, both real and “imagined.” Psychonomic Bulletin & Review, 14(4), 735–741. / 2 / (2) No abrupt onsets
Burnham, B. R., & Neely, J. H. (2007). Involuntary capture of visual-spatial attention occurs for intersections, both real and “imagined.” Psychonomic Bulletin & Review, 14(4), 735–741. / 3 / (2) No abrupt onsets
Burnham, B. R., & Neely, J. H. (2008). A static color discontinuity can capture spatial attention when the target is an abrupt-onset singleton. Journal of Experimental Psychology: Human Perception and Performance, 34(4), 831–841. / 2 / (2) No abrupt onsets
Burnham, B. R., & Neely, J. H. (2008). A static color discontinuity can capture spatial attention when the target is an abrupt-onset singleton. Journal of Experimental Psychology: Human Perception and Performance, 34(4), 831–841. / 3 / (2) No abrupt onsets
Burnham, B. R., & Neely, J. H. (2008). A static color discontinuity can capture spatial attention when the target is an abrupt-onset singleton. Journal of Experimental Psychology: Human Perception and Performance, 34(4), 831–841. / 1A / (2) No abrupt onsets
Burnham, B. R., & Neely, J. H. (2008). A static color discontinuity can capture spatial attention when the target is an abrupt-onset singleton. Journal of Experimental Psychology: Human Perception and Performance, 34(4), 831–841. / 1B / (2) No abrupt onsets
Burnham, B. R., Neely, J. H., Naginsky, Y., & Thomas, M. (2010). Stimulus-driven attentional capture by a static discontinuity between perceptual groups. Journal of Experimental Psychology: Human Perception and Performance, 36(2), 317–329. / 1 / (2) No abrupt onsets
Burnham, B. R., Neely, J. H., Naginsky, Y., & Thomas, M. (2010). Stimulus-driven attentional capture by a static discontinuity between perceptual groups. Journal of Experimental Psychology: Human Perception and Performance, 36(2), 317–329. / 3 / (2) No abrupt onsets