default search action
Jia Zhao 0004
Person information
- affiliation: Utah State University, Logan, UT, USA
- affiliation: University of South Carolina, Department of Mathematics, Columbia, SC, USA
- affiliation: University of North Carolina, Department of Mathematics, Chapel Hill, NC, USA
Other persons with the same name
- Jia Zhao — disambiguation page
- Jia Zhao 0001
— Nanchang Institute of Technology, School of Information Engineering, China
- Jia Zhao 0002
- Jia Zhao 0003
- Jia Zhao 0005
- Jia Zhao 0006
Refine list
refinements active!
zoomed in on ?? of ?? records
view refined list in
export refined list as
2020 – today
- 2025
- [j39]Zengyan Zhang, Jia Zhao
General numerical framework to derive structure preserving reduced order models for thermodynamically consistent reversible-irreversible PDEs. J. Comput. Phys. 521: 113562 (2025) - [j38]Qi Hong, Zengyan Zhang, Jia Zhao
Auxiliary relaxation method to derive thermodynamically consistent phase field models with constraints and structure preserving numerical approximations. J. Comput. Phys. 522: 113598 (2025) - 2024
- [j37]Jiansong Zhang, Xinxin Guo, Maosheng Jiang, Tao Zhou, Jia Zhao
Linear relaxation method with regularized energy reformulation for phase field models. J. Comput. Phys. 515: 113225 (2024) - 2023
- [j36]Maosheng Jiang, Jia Zhao
Linear relaxation schemes for the Allen-Cahn-type and Cahn-Hilliard-type phase field models. Appl. Math. Lett. 137: 108477 (2023) - [j35]Qi Hong, Yuezheng Gong, Jia Zhao
Thermodynamically consistent hydrodynamic phase-field computational modeling for fluid-structure interaction with moving contact lines. J. Comput. Phys. 492: 112409 (2023) - [i11]Zengyan Zhang, Jia Zhao:
General Numerical Framework to Derive Structure Preserving Reduced Order Models for Thermodynamically Consistent Reversible-Irreversible PDEs. CoRR abs/2312.02363 (2023) - 2022
- [j34]Jia Zhao
A general framework to derive linear, decoupled and energy-stable schemes for reversible-irreversible thermodynamically consistent models. Comput. Math. Appl. 110: 91-109 (2022) - [j33]Maosheng Jiang, Jia Zhao
Linear energy stable numerical schemes for a general chemo-repulsive model. J. Comput. Appl. Math. 415: 114436 (2022) - [j32]Maosheng Jiang, Zengyan Zhang, Jia Zhao
Improving the accuracy and consistency of the scalar auxiliary variable (SAV) method with relaxation. J. Comput. Phys. 456: 110954 (2022) - 2021
- [j31]Jia Zhao
A revisit of the energy quadratization method with a relaxation technique. Appl. Math. Lett. 120: 107331 (2021) - [j30]Qi Hong, Jia Zhao, Qi Wang:
Energy-production-rate preserving numerical approximations to network generating partial differential equations. Comput. Math. Appl. 84: 148-165 (2021) - [j29]Jia Zhao
Second-order decoupled energy-stable schemes for Cahn-Hilliard-Navier-Stokes equations. J. Comput. Phys. 443: 110536 (2021) - [j28]Yakun Li
Second order linear decoupled energy dissipation rate preserving schemes for the Cahn-Hilliard-extended-Darcy model. J. Comput. Phys. 444: 110561 (2021) - [i10]Jia Zhao:
A General Framework to Derive Linear, Decoupled and Energy-stable Schemes for Reversible-Irreversible Thermodynamically Consistent Models: Part I Incompressible Hydrodynamic Models. CoRR abs/2103.02203 (2021) - [i9]Jia Zhao:
Second-order Decoupled Energy-stable Schemes for Cahn-Hilliard-Navier-Stokes equations. CoRR abs/2103.02210 (2021) - [i8]Jia Zhao:
A Revisit of The Energy Quadratization Method with A Relaxation Technique. CoRR abs/2103.08855 (2021) - [i7]Maosheng Jiang, Zengyan Zhang, Jia Zhao:
Improving the Accuracy and Consistency of the Scalar Auxiliary Variable (SAV) Method with Relaxation. CoRR abs/2104.06620 (2021) - [i6]Zengyan Zhang, Yuezheng Gong, Jia Zhao:
A Remark on the Invariant Energy Quadratization (IEQ) Method for Preserving the Original Energy Dissipation Laws. CoRR abs/2111.12920 (2021) - 2020
- [j27]Jun Zhang, Jia Zhao
A non-uniform time-stepping convex splitting scheme for the time-fractional Cahn-Hilliard equation. Comput. Math. Appl. 80(5): 837-850 (2020) - [j26]Cheng Lei, Yu Wang, Jia Zhao
A patient specific forecasting model for human albumin based on deep neural networks. Comput. Methods Programs Biomed. 196: 105555 (2020) - [j25]Yuezheng Gong, Jia Zhao
Arbitrarily high-order unconditionally energy stable SAV schemes for gradient flow models. Comput. Phys. Commun. 249: 107033 (2020) - [j24]Jun Zhang
Error analysis of full-discrete invariant energy quadratization schemes for the Cahn-Hilliard type equation. J. Comput. Appl. Math. 372: 112719 (2020) - [j23]Jun Zhang
Energy-stable predictor-corrector schemes for the Cahn-Hilliard equation. J. Comput. Appl. Math. 376: 112832 (2020) - [j22]Yuezheng Gong, Jia Zhao
Arbitrarily high-order linear energy stable schemes for gradient flow models. J. Comput. Phys. 419: 109610 (2020) - [j21]Lizhen Chen, Jia Zhao
A novel second-order linear scheme for the Cahn-Hilliard-Navier-Stokes equations. J. Comput. Phys. 423: 109782 (2020) - [j20]Shouwen Sun, Jun Li, Jia Zhao, Qi Wang
Structure-Preserving Numerical Approximations to a Non-isothermal Hydrodynamic Model of Binary Fluid Flows. J. Sci. Comput. 83(3): 50 (2020) - [j19]Yuezheng Gong
Arbitrarily High-Order Unconditionally Energy Stable Schemes for Thermodynamically Consistent Gradient Flow Models. SIAM J. Sci. Comput. 42(1): B135-B156 (2020) - [i5]Jun Zhang, Jia Zhao, JinRong Wang:
A Non-uniform Time-stepping Convex Splitting Scheme for the Time-fractional Cahn-Hilliard Equation. CoRR abs/2006.02061 (2020) - [i4]Jia Zhao:
Discovering Phase Field Models from Image Data with the Pseudo-spectral Physics Informed Neural Networks. CoRR abs/2007.04535 (2020)
2010 – 2019
- 2019
- [j18]Yuezheng Gong, Jia Zhao
Energy-stable Runge-Kutta schemes for gradient flow models using the energy quadratization approach. Appl. Math. Lett. 94: 224-231 (2019) - [j17]Yucan Zhao, Jun Li, Jia Zhao, Qi Wang:
A linear energy and entropy-production-rate preserving scheme for thermodynamically consistent crystal growth models. Appl. Math. Lett. 98: 142-148 (2019) - [j16]Jia Zhao
On power law scaling dynamics for time-fractional phase field models during coarsening. Commun. Nonlinear Sci. Numer. Simul. 70: 257-270 (2019) - [j15]Xiaofeng Yang
Efficient linear schemes for the nonlocal Cahn-Hilliard equation of phase field models. Comput. Phys. Commun. 235: 234-245 (2019) - [j14]Lizhen Chen, Jun Zhang, Jia Zhao
An accurate and efficient algorithm for the time-fractional molecular beam epitaxy model with slope selection. Comput. Phys. Commun. 245 (2019) - [j13]Jun Li, Jia Zhao
Energy and entropy preserving numerical approximations of thermodynamically consistent crystal growth models. J. Comput. Phys. 382: 202-220 (2019) - [i3]Yuezheng Gong, Jia Zhao, Qi Wang:
Arbitrarily High-order Unconditionally Energy Stable Schemes for Gradient Flow Models Using the Scalar Auxiliary Variable Approach. CoRR abs/1907.04254 (2019) - [i2]Yuezheng Gong, Jia Zhao, Qi Wang:
Arbitrarily High-order Unconditionally Energy Stable Schemes for Thermodynamically Consistent Gradient Flow Models. CoRR abs/1907.05341 (2019) - [i1]Yuezheng Gong, Jia Zhao, Qi Wang:
Arbitrarily High-order Linear Schemes for Gradient Flow Models. CoRR abs/1910.07211 (2019) - 2018
- [j12]Yuezheng Gong, Jia Zhao, Qi Wang:
Linear second order in time energy stable schemes for hydrodynamic models of binary mixtures based on a spatially pseudospectral approximation. Adv. Comput. Math. 44(5): 1573-1600 (2018) - [j11]Huan Liu, Aijie Cheng
Time-fractional Allen-Cahn and Cahn-Hilliard phase-field models and their numerical investigation. Comput. Math. Appl. 76(8): 1876-1892 (2018) - [j10]Xiaofeng Yang
Linear, second order and unconditionally energy stable schemes for the viscous Cahn-Hilliard equation with hyperbolic relaxation using the invariant energy quadratization method. J. Comput. Appl. Math. 343: 80-97 (2018) - [j9]Yuezheng Gong, Jia Zhao
Fully Discrete Second-Order Linear Schemes for Hydrodynamic Phase Field Models of Binary Viscous Fluid Flows with Variable Densities. SIAM J. Sci. Comput. 40(1) (2018) - [j8]Yuezheng Gong, Jia Zhao
Second Order Fully Discrete Energy Stable Methods on Staggered Grids for Hydrodynamic Phase Field Models of Binary Viscous Fluids. SIAM J. Sci. Comput. 40(2) (2018) - 2017
- [j7]Yuezheng Gong, Jia Zhao
An energy stable algorithm for a quasi-incompressible hydrodynamic phase-field model of viscous fluid mixtures with variable densities and viscosities. Comput. Phys. Commun. 219: 20-34 (2017) - [j6]Xiaofeng Yang
Numerical approximations for the molecular beam epitaxial growth model based on the invariant energy quadratization method. J. Comput. Phys. 333: 104-127 (2017) - [j5]Jia Zhao
Decoupled Energy Stable Schemes for a Phase Field Model of Three-Phase Incompressible Viscous Fluid Flow. J. Sci. Comput. 70(3): 1367-1389 (2017) - 2016
- [j4]Jia Zhao
A decoupled energy stable scheme for a hydrodynamic phase-field model of mixtures of nematic liquid crystals and viscous fluids. J. Comput. Phys. 305: 539-556 (2016) - [j3]Jia Zhao
Semi-Discrete Energy-Stable Schemes for a Tensor-Based Hydrodynamic Model of Nematic Liquid Crystal Flows. J. Sci. Comput. 68(3): 1241-1266 (2016) - [j2]Maryna Kapustina, Denis Tsygankov
Modeling the Excess Cell Surface Stored in a Complex Morphology of Bleb-Like Protrusions. PLoS Comput. Biol. 12(3) (2016) - [j1]Jia Zhao
Energy Stable Numerical Schemes for a Hydrodynamic Model of Nematic Liquid Crystals. SIAM J. Sci. Comput. 38(5) (2016)
Coauthor Index
manage site settings
To protect your privacy, all features that rely on external API calls from your browser are turned off by default. You need to opt-in for them to become active. All settings here will be stored as cookies with your web browser. For more information see our F.A.Q.
Unpaywalled article links
Add open access links from to the list of external document links (if available).
Privacy notice: By enabling the option above, your browser will contact the API of unpaywall.org to load hyperlinks to open access articles. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Unpaywall privacy policy.
Archived links via Wayback Machine
For web page which are no longer available, try to retrieve content from the of the Internet Archive (if available).
Privacy notice: By enabling the option above, your browser will contact the API of archive.org to check for archived content of web pages that are no longer available. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Internet Archive privacy policy.
Reference lists
Add a list of references from ,
, and
to record detail pages.
load references from crossref.org and opencitations.net
Privacy notice: By enabling the option above, your browser will contact the APIs of crossref.org, opencitations.net, and semanticscholar.org to load article reference information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Crossref privacy policy and the OpenCitations privacy policy, as well as the AI2 Privacy Policy covering Semantic Scholar.
Citation data
Add a list of citing articles from and
to record detail pages.
load citations from opencitations.net
Privacy notice: By enabling the option above, your browser will contact the API of opencitations.net and semanticscholar.org to load citation information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the OpenCitations privacy policy as well as the AI2 Privacy Policy covering Semantic Scholar.
OpenAlex data
Load additional information about publications from .
Privacy notice: By enabling the option above, your browser will contact the API of openalex.org to load additional information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the information given by OpenAlex.
last updated on 2025-05-12 21:37 CEST by the dblp team
all metadata released as open data under CC0 1.0 license
see also: Terms of Use | Privacy Policy | Imprint
dblp was originally created in 1993 at:
since 2018, dblp has been operated and maintained by:
the dblp computer science bibliography is funded and supported by: