2011.09-2018.03     西安交通大學(xué)，動(dòng)力工程及工程熱物理專業(yè)，博士
2007.09-2011.06     重慶大學(xué)，熱能與動(dòng)力工程專業(yè)，學(xué)士

2023.01-至今              上海交通大學(xué)，核科學(xué)與工程學(xué)院，副教授
2020.09-2022.12        上海交通大學(xué)，核科學(xué)與工程學(xué)院，助理教授
2018.04-2020.08        上海交通大學(xué)，核科學(xué)與工程學(xué)院，博士后

一、多孔單晶材料生長(zhǎng)方法
二、納米孔道受限流體理論
三、核電站同位素分離技術(shù)


（常年招收碩士、博士研究生）

?? 科研項(xiàng)目
國(guó)家攻堅(jiān)專項(xiàng)子課題，主持

國(guó)家自然科學(xué)基金面上項(xiàng)目，主持
國(guó)家自然科學(xué)青年基金，主持
國(guó)家/教育部重點(diǎn)實(shí)驗(yàn)室開(kāi)放基金，主持
上海市科技創(chuàng)新行動(dòng)計(jì)劃，主持
博士后基金特別資助，主持
博士后基金面上項(xiàng)目，主持

?? 教書育人項(xiàng)目
上海交通大學(xué)2024年教學(xué)發(fā)展基金
上海交通大學(xué)2023年教學(xué)發(fā)展基金
上海交通大學(xué)2023年優(yōu)秀班主任基金

?? 一作
[1] Liu, L.*, Jia, Z., Yuan, J.J., Bao,R.Q., Luo, H.T. Hanyang Gu. Assessing the impact of CPs transfer on corrosion behavior in the liquid lead-bismuth eutectic cooled system. Corrosion Science 241, 112511 (2024).
[2] Liu, L.*，Li, Y.M., Gu, H.Y. Numerical study on flow field and separation performance of swirl-vane separator under rolling motion conditions. Annals of Nuclear Energy 212, 111050 (2025).
[3] Liu, L., Yuan, J.J., Bao, R.Q., Luo, H.T., Jia, Z., Chen, S., Gu, H.Y. Numerical simulation of boiling dynamics in liquid Lead-Bismuth injected with multi-rupture high-pressure water jets. International Communications in Heat and Mass Transfer,159, 108219 (2024).
[4] Liu, L.,* Luo, H.T., Yuan, J.J., Bao, R.Q., Li, D., Tian, X.Y., Gu, H.Y. Numerical simulation and model development of drag coefficient of bubbles in gas-liquid metal two-phase flow.  International Journal of Multiphase Flow 178, 104890 (2024).
[5] Liu, L., Hu, B., Liu, S., Wang, K., Gu, H.Y.* Recognition of gas-liquid flow regimes in helically coiled tube using wire-mesh sensor and KNN algorithm. International Journal of Multiphase Flow 154, 104144 (2022).
[6] Liu, L., Zhang, J.R., Hu, B., Dai, J.T., Wang, K., Gu, H.Y.* Flow pattern transition and void fraction prediction of gas-liquid flow in helically coiled tubes. Chemical Engineering Science 258, 117751 (2022).
[7] Liu, L., Zhang, J.R., Liu, S., Wang, K., Gu, H.Y.* Decay law and swirl length of swirling gas-liquid flow in a vertical pipe. International Journal of Multiphase Flow  137, 103570 (2021).
[8] Liu, L., Ying, B. B., Gu, H.Y.*, et al. Experimental study on the separation performance of a full-scale SG steam-water separator. Annals of Nuclear Energy 141, 107330 (2020).
[9] Liu, L., Ying, B.B.* Effect of water level on performance of swirl-vane separator and steam dryer in PWR SG. Nuclear Engineering and Design 370, 110918 (2020).
[10] Liu, L., Ying, B.B., Gu, H.Y.*, et al. Effect of velocity and pressure on performance of a full-scale SG steam separator package. Nuclear Engineering and Design 110551 (2020).
[11] Liu, L., Wang, K., Bai, B.F.* Experimental study on flow patterns and transition criteria for vertical swirling gas-liquid flow. International Journal of Multiphase Flow 122, 103113 (2020).
[12] Liu, L., Wang, K., Bai, B.F.* Comparative investigation of liquid film thickness and interfacial wave properties of swirling gas-liquid flows. Chemical Engineering Science 213, 115407 (2020).
[13] Liu, L., Bai, B.F.* Experimental study and similarity analysis of separation efficiency of swirl-vane separator. Nuclear Engineering and Design 359, 110442 (2020).
[14] Liu, L., Bai, B.F.* Flow regime identification of swirling gas-liquid flow using image processing technique and neural networks. Chemical Engineering Science 199, 588-601 (2019).
[15] Liu, L., Bai, B.F.* A mechanistic model for the prediction of swirling annular flow pattern transition. Chemical Engineering Science 199, 405-416 (2019).
[16] Liu, L., Bai, B.F.* Error analysis of liquid holdup measurement in gas-liquid annular flow through circular pipes using high-speed camera method. Journal of Shanghai Jiao Tong University (Science) 23(1), 34-40 (2018).
[17] Liu, L., Bai, B.F.* Generalization of droplet entrainment rate correlation for annular flow considering disturbance wave properties. Chemical Engineering Science 164, 279-291 (2017).
[18] Liu, L., Wang, S., Bai, B.F.* Thermal-hydraulic comparisons of 19-pin rod bundles with four circular and trapezoid shaped wire wraps. Nuclear Engineering and Design 318, 213-230 (2017).
[19] Liu, L., Bai, B.F.* Numerical study on swirling flow and separation performance of swirl vane separator. Interfacial Phenomena and Heat Transfer 5(1), 9-21 (2017).
[20] Liu, L., Bai, B.F.* Scaling laws for gas-liquid flow in swirl vane separators. Nuclear Engineering and Design 298, 229-239 (2016).

?? 通訊

[1] Yuan, J.J., Liu, L.*, Bao, R.Q., Luo, H.T., Jia, Z., Chen, S., Gu, H.Y. Numerical study of transient jet phenomena and system effects during the SGTR accident in lead-bismuth fast reactor. International Journal of Thermal Sciences (2025).
[2] Liu, S., Liu, L.*, Gu, H.Y., Wang, K. Experimental and theoretical study on liquid film thickness of upward annular flow in helically coiled tubes. International Journal of Multiphase Flow 182, 105041 (2025).
[3] Chen, S., Liu, S., Liu, L.*, Li, Y.M., Zhang, J.R., Cong, T.L., Gu, H.Y. Experimental study on flow patterns and pressure gradient of decaying swirling gas-liquid flow in a horizontal pipe. Progress in Nuclear Energy 177, 105445 (2024).
[4] Bao, R.Q., Liu, L.*, Liu, S., Liu, M.L., Wang, K., Gu, H.Y. Numerical analysis and structural optimization of a DLC coated capacitance wire-mesh sensor for measuring liquid metal-gas two-phase distribution. Annals of Nuclear Energy 205, 110590 (2024).
[5] Zhang, J.R., Liu, L.*, Yuan, J.J., Luo, H.T., Liu, S., Gu, H.Y. A study on bubble entrainment rate in a decaying swirling flow field based on the wire-mesh sensor. Annals of Nuclear Energy 206, 110674 （2024）.
[6] Yuan, J.J., Liu, L.*, Bao R.Q., Li, D., Tian, X.Y., Luo, H.T., Jia, Z., Liu, M.L., Gu, H.Y. Numerical simulation of jet boiling characteristics of high-pressure water injected into high-temperature liquid lead–bismuth in a confined space. Applied Thermal Engineering 250, 123432 (2024).
[7] Yuan, J.J., Liu, L.*, Bao, R.Q., Luo, H.T., Liu, M.L., Gu, H.Y. Three-dimensional numerical simulation of the interaction between high-pressure sub-cooled water jet impacting high-temperature liquid lead-bismuth metal. Applied Thermal Engineering 230, 120705 (2023).
[8] Zhang, J.R., Liu, L.*, Liu, S., Gu, H.Y. A method for predicting the breakup of gas column in a decaying swirling liquid field. Annals of Nuclear Energy 195, 110176 (2024).
[9] Zhang, J.R., Liu, L.*, Liu, S., Gu, H.Y. A theoretical model of gas column breakup under a swirling flow field based on the jet theory. Annals of Nuclear Energy204, 110552 (2024).
[10] Wang, K., Cheng, Z., Wu, N., Zhang, Q., Liu, L*. Theoretical model on the slug/churn transition based on the generation and evolution of the huge waves. Physics of Fluids 35, 043329 (2023).
[11] Wang, K., Liu, L.*, Xu, D.H., Gu, H.Y. Simulation and optimization of a conical type swirl-vane separator in nuclear SG. Nuclear Engineering and Design 408, 112325 (2023).
[12] Liu, S., Wang, K., Liu, L.*, Zhang, Q., Gu, H.Y. Characterization of liquid film distribution and sub-flow regimes of annular flow in helically coiled tubes using ring island array sensor.  International Journal of Multiphase Flow 160, 104357 (2023).
[13] Liu, S., Liu, L.*, Gu, H.Y., Wang, K. Optimization and application of the concentric conductance probes in liquid film thickness measurement in a helically coiled tube. Measurement Science and Technology 33, 085106 (2022).
[14] Liu, S., Liu, L.*, Gu, H.Y., Wang, K. Experimental study of gas-liquid flow patterns and void fraction in prototype 5×5 rod bundle channel using wire-mesh sensor. Annals of Nuclear Energy 171, 109022 (2022).
[15] Zhang, Q., Liu, L.*, Zeng, Y., Zeng, C., Gu, H.Y. Numerical simulation of inherent boric mixing phenomenon inside reactor annular down-comer. Progress in Nuclear Energy 148, 104230 (2022).

?? 其它
[1] Chen, S., Hu, Z.X., Liu, L., Liu, M.L., Gu, H.Y.* Development of a transient analysis code for trans-critical simulation of SCWR. Annals of Nuclear Energy 210, 110887 (2025).
[2] Wang, K.*, Zhang, Q., Wu, P.F., Liu, L. Numerical study of flow and heat transfer characteristics in shell-and-plate heat exchangers. Heat Transfer Research 53(8), 99-119 (2022).
[3] Zhang, Q., Liu, L., Xiao, Y., et al. Experimental study on the transverse mixing of 5× 5 helical cruciform fuel assembly by wire mesh sensor, Annals of Nuclear Energy 164, 108582 (2021).
[4] Lin, R., Wang, K.*, Liu, L., et al. Study on the characteristics of interfacial waves in annular flow by image analysis. Chemical Engineering Science 212, 115336 (2020).
[5] Lin, R., Wang, K.*, Liu, L., et al. Application of the image analysis on the investigation of disturbance waves in vertical upward annular two-phase flow. Experimental Thermal and Fluid Science 114, 110062 (2020).
[6] Wang, K.*, Wu, P., Tang, Z., Liu, L., et al. Flow patterns and pressure drop in the shell-and-plate heat exchangers. International Journal of Multiphase Flow 129, 103323 (2020).

?? 中文論文
[1] 賈政, 劉莉*, 包睿祺, 羅皓天, 袁俊杰, 顧漢洋. 鉛鉍快堆堆芯包殼多場(chǎng)耦合腐蝕行為的數(shù)值模擬研究, 原子能科學(xué)技術(shù), 2024, 58(10), 2113-2123.
[2] 袁俊杰, 劉莉*, 包睿祺, 羅皓天, 賈政, 田曉艷, 李達(dá), 顧漢洋. 密閉空間內(nèi)高壓水射流沖擊高溫鉛鉍熔池能質(zhì)傳輸數(shù)值模擬研究, 原子能科學(xué)技術(shù), 2024, 58(9), 1958-1968.
[3] 羅皓天, 劉莉*, 袁俊杰, 包睿祺, 田曉艷, 李達(dá), 顧漢洋. 氣泡在液態(tài)鉛鉍金屬中的運(yùn)動(dòng)特性及曳力系數(shù)模型研究, 核技術(shù), 2024, 47(6), 060603.
[4] 劉莉，袁俊杰，顧漢洋，包睿祺，劉茂龍，王科. 鉛鉍快堆SGTR事故下高壓過(guò)冷水注入高溫鉛鉍合金流動(dòng)傳熱數(shù)值模擬研究, 核動(dòng)力工程, 2023, 44(04), 55-64.
[5] 包睿祺, 劉莉*, 劉帥, 袁俊杰, 劉茂龍, 顧漢洋. 用于探測(cè)液態(tài)金屬-氣體的DLC涂層式絲網(wǎng)探針數(shù)值模擬與結(jié)構(gòu)優(yōu)化, 原子能科學(xué)技術(shù), 2024, 58(2): 344-356.
[6] 李亞民，應(yīng)秉斌，劉莉，顧漢洋. 搖擺條件下旋葉式分離器流場(chǎng)及效率的數(shù)值模擬研究, 原子能科學(xué)技術(shù), 2024.
[7] 劉莉, 劉帥, 張嘉榮等. 基于環(huán)-島陣列式傳感器的螺旋管內(nèi)環(huán)狀流中液膜分布特性研究[J].原子能科學(xué)技術(shù), 2022, 56(11): 2334-2342.
[8] 袁俊杰，劉莉*，顧漢洋. U型管式蒸汽發(fā)生器內(nèi)改性壁面強(qiáng)化傳熱數(shù)值研究. 核動(dòng)力工程, 2022, 43(S2), 94-99.
[9] 劉帥, 劉莉*, 顧漢洋, 張嘉榮. 基于WMS的無(wú)旋和螺旋氣液兩相流流型及空泡份額實(shí)驗(yàn)研究. 核動(dòng)力工程, 2022, 43(5), 43-50.
[10] 戴軍濤, 劉莉*, 劉帥, 顧漢洋, 王科. 基于絲網(wǎng)探針的螺旋管內(nèi)氣液兩相流氣泡行為研究. 化工學(xué)報(bào). 2022, 73(10), 4377-4388.
[11] 劉莉, 王科*, 林睿南, 戴軍濤. 基于圖像分析技術(shù)的環(huán)狀流內(nèi)界面波識(shí)別與捕捉. 科學(xué)通報(bào), 2021, 66(26), 3497-3504.
[12] 徐德輝，顧漢洋*，劉莉，黃超. 新型錐形式旋葉汽水分離器熱態(tài)試驗(yàn)與數(shù)值研究. 上海交通大學(xué)學(xué)報(bào), 2021, 55(9), 1087-1094.
[13] 劉莉, 白博峰*. 基于可視化和圖像處理的氣液螺旋兩相流流型研究. 工程熱物理學(xué)報(bào), 2022, 43(11), 2978-2985.
[14] 劉莉, 白博峰*. 氣液螺旋環(huán)狀流界面波失穩(wěn)機(jī)理. 中國(guó)科學(xué)院大學(xué)學(xué)報(bào), 2017, 34(2), 153-159.

?? 發(fā)明專利授權(quán)
【1】一種圓管內(nèi)氣液兩相環(huán)狀流截面相含率的測(cè)量及修正方法，ZL 2018 1 0327373.8.
【2】一種圓管內(nèi)氣液兩相環(huán)狀流液膜厚度的測(cè)量及修正方法，ZL 2018 1 0327886.9.
【3】一種基于蒸汽閉式循環(huán)的汽水分離性能熱態(tài)試驗(yàn)系統(tǒng)，ZL 2019 1 1018114.8.
【4】一種基于電導(dǎo)率法的在線測(cè)量蒸汽濕度的系統(tǒng)及方法，ZL 2019 1 1016913.1.
【5】一種線列陣傳感器測(cè)量誤差的修正方法，ZL 2019 1 1035085.6.
【6】一種絲網(wǎng)探針濃度探測(cè)裝置的校正系統(tǒng)及方法，ZL 2020 1 1264170.2.
【7】一種用于測(cè)量壁面液膜厚度的叉指陣列裝置及檢測(cè)方法，ZL 2021 1 0675040.6.
【8】一種用于測(cè)量原型棒束通道內(nèi)流體參數(shù)的絲網(wǎng)傳感器組件，ZL 2021 1 0675152.1.
【9】基于絲網(wǎng)探針的氣液兩相流場(chǎng)特征重構(gòu)方法、系統(tǒng)及介質(zhì)，ZL 2020 1 1141070.0.
【10】一種適用于高溫高壓流動(dòng)工況下的絲網(wǎng)傳感器組件, ZL 2021 1 0675151.7.
【11】用于測(cè)試汽水分離再熱器波形板組件分離性能的試驗(yàn)系統(tǒng), ZL 2020 1 0484524.8.
【12】一種用于評(píng)價(jià)汽水分離裝置分離效率的在線分級(jí)測(cè)量系統(tǒng)，ZL 201911018111.4.

?? 軟件著作權(quán)
【1】電導(dǎo)式絲網(wǎng)探針數(shù)據(jù)后處理軟件，登記號(hào)：2021SR0379333.
【2】圓管內(nèi)氣液兩相流中液膜厚度圖像處理軟件，登記號(hào)：2021SR0540616.
【3】基于三維空泡矩陣的復(fù)雜螺旋通道內(nèi)氣液兩相流場(chǎng)分析軟件，登記號(hào)：2022SR1049536.