Journal Articles
Electronic versions are provided as a professional courtesy to ensure timely dissemination of academic work for individual, noncommercial purposes. Copyright and all rights therein reside with the respective copyright holders, as stated in each paper. These files may not be reposted without permission.
Code and data can be found on our lab Github.
2024 and in press
Chiu, T.Y., & Golomb, J. (in press). The influence of saccade target status on the reference frame of object-location binding. Journal of Experimental Psychology: General
Lu, Z. and Golomb, J.D (2024). Human EEG and artificial neural networks reveal disentangled representations of object real-world size in natural images. eLife 13:RP98117. https://doi.org/10.7554/eLife.98117.1
Choi, Y.M., & Golomb, J. (in press). The perceptual and mnemonic effects of ensemble representation on individual size representation. Attention, Perception, & Performance.
Lu, Z. and Golomb, J.D (2024). Dynamic saccade context triggers more stable object-location binding. Journal of Experimental Psychology: General. 153(4), 873–888. [link] [pdf]
Gao, M., Starks, M.D., Golomb, J.D, and Sloutsky, V. (2024). The development of visual cognition: The emergence of spatial congruency bias. Developmental Science. e13482. [link] [pdf]
McNally, J.A., Narhi-Martinez, W., Leber, A.B., and Golomb, J.D. (2024). Learned relevance of a distracting cue can influence feature interference errors. Journal of Vision.
Strzelczyk, D., Clayson, P.E., …, Lu, Z., Choi, Y.M., Lout, E., Golomb, J.D., …, Langer, N. (accepted, stage 1 registered replication). Contralateral delay activity as a marker of visual working memory capacity: a multi-site registered replication. Cortex. Preprint on PsyArXiv: https://psyarxiv.com/shdea/ .
Pre-prints & manuscripts under review
Choi, Y.M., Chiu, T-Y., Ferreira, J., & Golomb, J. (2024, preprint). Maintaining Visual Stability in Naturalistic Scenes: The Roles of Trans-Saccadic Memory and Default Assumptions. Preprint on PsyArXiv: https://osf.io/preprints/psyarxiv/m9wa4 .
Lout, E., Golomb, J.D, and Dube, B. (under revision). Items in visual working memory are more susceptible to visual interference while in-use. Preprint on PsyArXiv: https://osf.io/preprints/psyarxiv/28xds
Lu, Z., Wang, Y., and Golomb, J.D (under review). ReAlnet: Achieving More Human Brain-Like Vision via Human Neural Representational Alignment. Preprint on ArXiv: https://arxiv.org/abs/2401.17231
Narhi-Martinez, W., Choi, Y.M., Dube, B., and Golomb, J.D. (under revision). Allocation of Spatial Attention in Human Visual Cortex as a Function of Endogenous Cue Validity.
Chang, S. and Golomb, J.D. (under review). From the eye to the world: Spatial suppression is primarily coded in retinotopic coordinates but can be learned in spatiotopic coordinates. Preprint on PsyArXiv: https://osf.io/preprints/psyarxiv/thmp7/
Ran, M., Lu, Z., & Golomb, J. (under review). The influence of a moving object’s location on object identity judgments. Preprint onPsyArXiv: https://doi.org/10.31234/osf.io/qcrhu
2023
Narhi-Martinez, W., Dube, B., Chen, J., Leber, A.B., and Golomb, J.D. (2023). Suppression of a salient distractor protects the processing of target features. Psychonomic Bulletin & Review. [link] [pdf]
Chen, J., and Golomb, J.D (2023). Dynamic neural reconstructions of attended object location and features using EEG. Journal of Neuropsychology. 130(1), 139-154. [link] [pdf]
Lu, Z. and Golomb, J.D (2023, forthcoming). Object Real-World Size Representations in Human Brains and Artificial Neural Networks. Proceedings of the Conference on Cognitive Computational Neuroscience 2023.
Lu, Z. and Golomb, J.D (2023, forthcoming). Generate your neural signals from mine: individual-to- individual EEG converters. Proceedings of the Annual Meeting of the Cognitive Science Society. Preprint on arXiv: https://arxiv.org/abs/2304.10736.
Chang, S. , Dube, B., Golomb, J.D., & Leber, A.B. (2023). Learned spatial suppression is not always proactive. Journal of Experimental Psychology: Human Perception & Performance. Advance online publication. https://doi.org/10.1037/xhp0001133
Babu, A.S., Scotti, P.S., and Golomb, J.D. (2023). The dominance of spatial information in object identity judgments: A persistent congruency bias even amidst conflicting statistical regularities. Journal of Experimental Psychology: Human Perception & Performance. 49(5), 672–686. https://doi.org/10.1037/xhp0001104
Narhi-Martinez, W., Chen, J., and Golomb, J.D (2023). Probabilistic visual attentional guidance triggers “feature avoidance” response errors. Journal of Experimental Psychology: Human Perception & Performance. Advance online publication. https://doi.org/10.1037/xhp0001095
2022
Lu, Z., Shafer-Skelton, A., and Golomb, J.D (2022). Gaze-centered spatial representations in human hippocampus. Proceedings of the Conference on Cognitive Computational Neuroscience 2022. Available at https://2022.ccneuro.org/proceedings/0000614.pdf
Narhi-Martinez, W. , Dube, B , & Golomb, J.D. (2022). Attention as a multi-level system of weights and balances. Wiley Interdisciplinary Reviews (WIREs) Cognitive Science. [link]
Dube, B. , Pidaparthi, L. , and Golomb, J.D. (2022). Visual distraction disrupts category-tuned filters in ventral visual cortex. Journal of Cognitive Neuroscience. [link] [pdf]
Scotti, P.S., Chen, J., and Golomb, J.D. (preprint). An enhanced inverted encoding model for neural reconstructions. Preprint on BioRxiv: https://doi.org/10.1101/2021.05.22.445245.
2021
Jones, C.M.., Dowd, E.W., and Golomb, J.D. (2021). Shifting Expectations: Lapses in Spatial Attention are Driven by Anticipatory Attentional Shifts. Attention, Perception, & Psychophysics. 83, 2822–2842. [link] [pdf]
Golomb, J.D. and Mazer, J.A. (2021). Visual Remapping. Annual Review of Vision Science. Vol 7. https://doi.org/10.1146/annurev-vision-032321-100012. [link] [pdf]
Dube, B. and Golomb, J.D. (2021). Perceptual distraction causes visual memory encoding intrusions. Psychonomic Bulletin & Review. [link] [pdf]
Zhang, X. and Golomb, J.D. (2021). Neural representations of covert attention across saccades: comparing pattern similarity to shifting and holding attention during fixation. eNeuro. [link] [pdf]
Scotti, P., Hong, Y., Leber, A.B., and Golomb, J.D. (2021). Visual working memory items drift apart due to active, not passive, maintenance. Journal of Experimental Psychology: General. [link] [Preprint] [pdf]
Scotti, P., Hong, Y., Golomb, J.D., and Leber, A.B. (2021). Statistical Learning as a Reference Point for Memory Distortions: Swap and Shift Errors. Attention, Perception, & Psychophysics. [link] [Preprint] [pdf]
Chen, J., Scotti, P.S., Dowd, E.W., and Golomb, J.D. (preprint). Neural Representations of Task-relevant and Task-irrelevant Features of Attended Objects. Preprint on BioRxiv: https://doi.org/10.1101/2021.05.21.445168.
2020
Dube, B. and Golomb, J.D. (2020). Revisiting mixture models of memory. Nature Human Behavior. 4: 1098-99. [link] [pdf]
Starks, M., Shafer-Skelton, A., Paradiso, M., Martinez, A.M., and Golomb, J.D. (2020). The influence of spatial location on same–different judgments of facial identity and expression. Journal of Experimental Psychology: Human Perception & Performance. Online First Version. [pdf]
Dowd, E.W. and Golomb, J.D. (2020). The Binding Problem after an eye movement. Attention, Perception, & Psychophysics. (Special issue in honor of Anne Treisman). 82(1): 168-180. [pdf]
Zhang, X., Jones, C.M., and Golomb, J.D. (preprint) Decoding 3D spatial location across saccades in human visual cortex. Preprint on BioRxiv: https://doi.org/10.1101/2020.07.05.188458
2019
Chen, J., Leber, A.B, and Golomb, J.D. (2019). Attentional capture alters feature perception. Journal of Experimental Psychology: Human Perception & Performance. 45(11). 1443-54. [pdf]
Golomb, J.D. (2019). Remapping locations and features across saccades: A dual-spotlight theory of attentional updating. Current Opinion in Psychology. 29:211-18. [pdf]
Dowd, E.W. and Golomb, J.D. (2019). Object feature binding survives dynamic shifts of spatial attention. Psychological Science. 30(3), 343-361. [pdf]
Nag, S. , Berman, D., and Golomb, J.D. (2019). Category-selective areas in human visual cortex exhibit preferences for stimulus depth. NeuroImage. 196: 289-301. [pdf]
Dowd, E.W., Nag, S., and Golomb, J.D. (2019). Working memory-driven attention towards a distractor does not interfere with target feature perception. Visual Cognition. [pdf]
2018
Zhang, X. and Golomb, J.D. (2018). Target localization after saccades and at fixation: Nontargets both facilitate and bias responses. Visual Cognition. 26(9), 734-752. [pdf]
Golomb, J.D. (2018; conference proceedings paper). Representations of 3D visual space in human cortex: Population receptive field models of position-in-depth. Cognitive Computational Neuroscience 2018. Available at https://ccneuro.org/2018/proceedings/1024.pdf.
Shafer-Skelton, A. and Golomb, J.D. (2018). Memory for retinotopic locations is more accurate than memory for spatiotopic locations, even for visually guided reaching. Psychonomic Bulletin & Review. 25(4): 1388-98. [pdf]
2017
Berman, D., Golomb, J.D., and Walther, D.B. (2017). Scene content is predominantly conveyed by high spatial frequencies in scene-selective visual cortex. PLOS One. 12(12). e0189828. [pdf]
Finlayson, N.J., Zhang, X., and Golomb, J.D. (2017). Differential patterns of 2D location versus depth decoding along the visual hierarchy. NeuroImage. 147: 507-516. [pdf]
Finlayson, N.J and Golomb, J.D. (2017). 2D location biases depth-from-disparity judgments but not vice versa. Visual Cognition. 25(9-10): 841-52. [pdf]
Bapat, A., Shafer-Skelton, A., Kupitz, C.N., and Golomb, J.D. (2017). Binding object features to locations: Does the “Spatial Congruency Bias” update with object movement? Attention, Perception, and Psychophysics. 79: 1682-94. [pdf]
Shafer-Skelton, A., Kupitz, C.N., and Golomb, J.D. (2017). Object-location binding across a saccade: A retinotopic Spatial Congruency Bias. Attention, Perception, and Psychophysics. 79(3): 765-81. [pdf]
2016
Finlayson, N.J and Golomb, J.D. (2016). Feature-location binding in 3D: Feature judgments are biased by 2D location but not position-in-depth. Vision Research. 127: 49-56. [pdf]
Lescroart, M.D., Kanwisher, N., and Golomb, J.D. (2016). No evidence for automatic remapping of stimulus features or location found with fMRI. Frontiers in Systems Neuroscience. 10: 53. (Special Issue on Perisaccadic Vision.) [pdf]
Srinivasan, R., Golomb, J.D., and Martinez, A.M. (2016). A neural basis of facial action recognition in humans. Journal of Neuroscience. 36(16): 4434-4442. [pdf]
Tower-Richardi, S.M., Leber, A.B., and Golomb, J.D. (2016). Spatial priming in ecologically relevant reference frames. Attention, Perception, and Psychophysics. 78: 114-132. [pdf]
2012-2015
Golomb, J.D. (2015). Divided spatial attention and feature-mixing errors. Attention, Perception, and Psychophysics. 77: 2562-69. [pdf]
Golomb, J.D., Kupitz, C.N., and Thiemann, C.T. (2014). The influence of object location on identity: A “spatial congruency bias”. Journal of Experimental Psychology: General. 143(6): 2262-78. [pdf]
Golomb, J.D., L’Heureux, Z.E., and Kanwisher, N. (2014). Feature-binding errors after eye movements and shifts of attention. Psychological Science. 25(5): 1067-78. [pdf]
Turk-Browne, N.B., Golomb, J.D., and Chun, M.M. (2013). Complementary attentional components of successful memory encoding. NeuroImage. 66: 553-562. [pdf]
Golomb, J.D. and Kanwisher, N. (2012). Retinotopic memory is more precise than spatiotopic memory. Proc Natl Acad Sci USA. 109(5): 1796-1801. [pdf]
Golomb, J.D. and Kanwisher, N. (2012). Higher-level visual cortex represents retinotopic, not spatiotopic, object location. Cerebral Cortex. 22: 2794-2810. [pdf] [supp]
pre-2011
Golomb, J.D., Albrecht, A.R., Park, S.-J., and Chun, M.M. (2011). Eye movements help link different views in scene-selective cortex. Cerebral Cortex. 21: 2094–2102. [pdf]
Chun, M.M., Golomb, J.D., and Turk-Browne, N.B. (2011). A taxonomy of external and internal attention. Annual Review of Psychology. 62: 73-101. [pdf]
Golomb, J.D., Marino, A.C., Chun, M.M., and Mazer, J.A. (2011). Attention doesn’t slide: Spatiotopic updating after eye movements instantiates a new, discrete attentional locus. Attention, Perception, and Psychophysics. 73(1): 7-14. [pdf]
Golomb, J.D., Nguyen-Phuc, A.Y., Mazer, J.A., McCarthy, G., and Chun, M.M. (2010). Attentional facilitation throughout human visual cortex lingers in retinotopic coordinates after eye movements. Journal of Neuroscience. 30(31), 10493-10506. [pdf]
Golomb, J.D., Pulido, V.Z., Albrecht, A.R., Chun, M.M., and Mazer, J.A. (2010). Robustness of the retinotopic attentional trace after eye movements. Journal of Vision. 10(3):19, 1-12, http://journalofvision.org/10/3/19/. [pdf]
Englot, D.J., Yang, L., Hamid, H., Danielson, N., Bai, X., Marfeo, A., Yu, L., Gordon, A., Purcaro, M.J., Motelow, J.E., Agarwal, R., Ellens, D.J., Golomb, J.D., Shamy, M.C.F., Zhang, H., Carlson, C., Doyle, W., Devinsky, O., Vives, K., Spencer, D.D., Spencer, S.S., Schevon, C., Zaveri, H.P, and Blumenfeld, H. (2010). Impaired consciousness in temporal lobe seizures: role of cortical slow activity. Brain. 133, 3764-3777. [pdf]
Golomb, J.D., McDavitt, J.R.B., Ruf, B.M., Chen, J.I., Saricicek, A., Maloney, K.H., Hu, J., Chun, M.M., and Bhagwagar, Z. (2009). Enhanced visual motion processing in Major Depressive Disorder. Journal of Neuroscience. 29(28), 9072-77. [pdf]
Golomb, J.D., Chun, M.M., and Mazer, J.A. (2008). The native coordinate system of spatial attention is retinotopic. Journal of Neuroscience. 28(42), 10654-662. [pdf]
Golomb, J.D., Peelle, J.E., Addis, K., Kahana, M.J., and Wingfield, A. (2008). Effects of adult aging on utilization of temporal and semantic associations during free and serial recall. Memory and Cognition. 36(5), 947-56. [pdf]
Golomb, J.D., Peelle, J.E., and Wingfield, A. (2007). Effects of stimulus variability and adult aging on adaptation to time-compressed speech. Journal of the Acoustical Society of America. 123(3), 1701-8. [pdf]
Sekuler, R., Kahana, M.J., McLaughlin, C., Golomb, J., and Wingfield, A. (2005). Preservation of episodic visual recognition memory in aging. Experimental Aging Research. 31(1), 1-13. [pdf]