2011年8月获得美国University of Louisiana at Lafayette应用数学专业博士学位

2016年至今， 西南大学数学与统计学院，教授

2011年8月至2016年6月，加拿大 University of Alberta, 生物数学中心，博士后，合作导师为 Mark Lewis 教授 （加拿大皇家科学院院士， Canada Research Chair in Mathematical Biology）

生物数学，偏微分方程，数值分析

1.研究生课程：生物数学，应用偏微分方程

2.本科生课程：常微分方程，数学建模，概率统计，高等数学，线性代数

1.Mathematical Biosciences 编委

2. 美国“数学评论”评论员

3.湖北科技学院“揽月学者”特聘教授

1.国家自然科学基金面上项目：斑块和树状河流生态系统研究，2023年1月至2026年12月，主持。

2.国家自然科学基金面上项目：污染物对河流种群生态系统的影响，2019年1月至2022年12月，主持。

3.重庆市留学人员回国创新支持计划重点项目：2019年4月至2022年4月，主持。

(* 表示通讯作者)

1. X. Deng, Q. Huang*, Z-A Wang, Global dynamics and pattern formation in a diffusive population-toxicant model with toxicant-taxis, SIAM Journal on Applied Mathematics, 83 (2023), 2212–2236.

2. P. Zhou, Q. Huang*, A spatiotemporal model for the effects of toxicants on population in a polluted river，SIAM Journal on Applied Mathematics, 82 (2022), 95-118.

附注：该论文被SIAM News的Associate Editor撰文在美国工业与应用数学的官方网站上进行了报道，详见：“New model examines the effects of toxicants on populations in polluted rivers"，链接：https://sinews.siam.org/Details-Page/new-model-examines-the-effects-of-toxicants-on-populations-in-polluted-rivers

3. K. Deng, Q. Huang*, A hybrid parabolic and hyperbolic equation model for a population with separate dispersal and stationary stages: well-posedness and population persistence, SIAM Journal on Applied Mathematics, 79 (2019), 2265-2287.

4. Q. Huang*, H. Wang, M. A. Lewis, A hybrid continuous/discrete-time model for invasion dynamics of zebra mussels in rivers, SIAM Journal on Applied Mathematics, 77 (2017), 854-880.

附注：该论文被SIAM News的Associate Editor专门撰文在美国工业与应用数学的官方网站上进行了报道详见："Modeling invasive activity zebra mussels infiltration of  North American rivers",

链接：https://sinews.siam.org/Details-Page/modeling-invasive-activity-zebra-mussels-infiltration-of-north-american-rivers

5. Q. Huang*, Y. Jin, M. A. Lewis, R0 analysis of a benthic-drift model for a stream population, SIAM Journal on Applied Dynamical Systems, 15 (2016), 287-321.

6. Q. Huang, Y. Zhang*, Spread rates of a juvenile-adult population in constant and temporally variable environments, Theoretical Ecology, 14 (2021), 145-160.

7. Q. Huang*, M. A. Lewis, Homing fidelity and reproductive rate for migratory populations, Theoretical Ecology, 8 (2015), 187-205.

8. Z. Ni, Q. Huang*, A nonautonomous model for the interaction between a size-structured consumer and an unstructured resource, Journal of Mathematical Biology, 88 (2024), Article number: 49, 28 pages.

9. C. Shan, Q. Huang*, Direct and indirect effects of toxins on competition dynamics of species in an aquatic environment, Journal of Mathematical Biology, 78 (2019), 739-766.

10. M. Wang, Y. Zhang, Q. Huang*, A stage-structured continuous-/discrete-time population model: persistence and spatial spread, Bulletin of Mathematical Biology, 84 (2022), Article number: 135, 29 pages.

11. Q. Huang*, H. Wang, A. Ricciardi, M. A. Lewis, Temperature- and turbidity- dependent competitive interactions between invasive freshwater mussels, Bulletin of Mathematical Biology, 78 (2016), 353-380.

12. Q. Huang, G. Seo*, C. Shan, Bifurcations and global dynamics in a toxin-dependent aquatic population model, Mathematical Biosciences, 296 (2018), 26-35.

13. Q. Huang*, H. Wang, M. A. Lewis, The impact of environmental toxins on predator-prey dynamics, Journal of Theoretical Biology, 378 (2015), 12-30.

14. Q. Huang*, L. Parshotam, H. Wang, C. Bampfylde, M. A. Lewis, A model for the impact of contaminants on fish population dynamics, Journal of Theoretical Biology, 334 (2013), 71-79.