| • Shao, Z.J., Zhang, M.Y., Yu, Q. * (2024) Stimulus representation in human frontal cortex supports flexible control in working memory.
eLife. 13: RP100287 |
| • Shi, D.,Yu, Q. * (2024) Distinct neural signatures underlying information maintenance and manipulation in working memory.
Cerebral Cortex. 34(3): bhae063 |
| • Hu, Y.,Yu, Q. * (2023) Spatiotemporal dynamics of self-generated imagery reveal a reverse cortical hierarchy from cue-induced imagery.
Cell Reports 42(10): 113242. |
| • Li, S., Zeng, X.M., Shao, Z.J.,Yu, Q. * (2023) Neural representations in visual and parietal cortex differentiate between imagined, perceived, and illusory experiences.
The Journal of Neuroscience 43(38): 6508-6524.(Featured as a Cover Article and in This Week in the Journal) |
| • Yu, Q.*, Postle, B. (2021) The neural codes underlying internally generated representations in visual working memory.
Journal of Cognitive Neuroscience 33(6): 1142-1157 |
| • Yu, Q.*, Panichello, M., Cai, Y., Postle, B., Buschman, T. (2020) Delay-period activity in frontal, parietal, and occipital cortex tracks noise and biases in visual working memory.
PLOS Biology 18(9): e3000854 |
| • Yu, Q.*#, Teng, C.#, Postle, B. (2020) Different states of priority recruit different neural representations in visual working memory.
PLOS Biology 18: e3000769 |
| • Liu, S.*#, Yu, Q.#, Tse, P., Cavanagh, P. (2019) Neural correlates of the conscious perception of visual location lie outside visual cortex.
Current Biology 29: 4036-4044 |
| • Yu, Q.*, Shim, WM. (2019) Temporal-order-based attentional priority modulates mnemonic representations in parietal and frontal cortices.
Cerebral Cortex 29(7): 3182-3192 |
| • Gosseries, O.#, Yu, Q.#, LaRocque, J., Starrett, M., Rose, N., Cowan, N., Postle, B. (2018) Parietal-occipital interactions underlying control- and representation-related processes in working memory for nonspatial visual features.
The Journal of Neuroscience 38(18): 4357-4366 |
| • Yu, Q.*, Shim, WM. (2017) Occipital, parietal, and frontal cortices selectively maintain task-relevant features of multi-feature objects in visual working memory.
NeuroImage 157: 97-107 |
| • Yu, Q., Shim, WM. (2016) Modulating foveal representation can influence visual discrimination in the periphery.
Journal of Vision 16(3): 15,1-12 |
| • Fulvio, J.,Yu, Q., Postle, B. (2023) Strategic control of location and ordinal context in visual working memory.
Cerebral Cortex : 1-14 |
| • Postle, B., Yu, Q. (2020) Neuroimaging and the localization of function in visual cognition.
Visual Cognition 28: 447-452 |
| • Cai, Y., Fulvio, J., Yu, Q.,Sheldon, A., Postle, B. (2020) The role of location-context binding in nonspatial visual working memory.
eNeuro 7(6): 1-14. |
| • Cai, Y., Sheldon, A., Yu, Q., Postle, B. (2019) Overlapping and distinct contributions of stimulus location and of spatial context to nonspatial visual short-term memory.
Journal of Neurophysiology 121(4): 1222-1231 |
| • Yu, Q.*, Postle, B. (2018) Separating the present and the future.
eLife 7: e43339 |
| • Chen, J., Yu, Q., Zhu Z., Peng Y., Fang, F. (2016) Spatial summation revealed in the earliest visual evoked component C1 and the effect of attention on its linearity.
Journal of Neurophysiology 115(1): 500-509 |
