Search

Your search keyword '"Sauceda, Daniel"' showing total 23 results
Start Over Author "Sauceda, Daniel" Search Limiters Academic (Peer-Reviewed) Journals
23 results on '"Sauceda, Daniel"'

1. Deciphering Chemical Ordering in High Entropy Materials: A Machine Learning-Accelerated High-throughput Cluster Expansion Approach

Author

Vazquez, Guillermo, Sauceda, Daniel, and Arróyave, Raymundo

Subjects
Condensed Matter - Materials Science
Abstract

The Cluster Expansion (CE) Method encounters significant computational challenges in multicomponent systems due to the computational expense of generating training data through density functional theory (DFT) calculations. This work aims to refine the cluster and structure selection processes to mitigate these challenges. We introduce a novel method that significantly reduces the computational load associated with the calculation of fitting parameters. This method employs a Graph Neural Network (GNN) model, leveraging the M3GNet network, which is trained using a select subset of DFT calculations at each ionic step. The trained surrogate model excels in predicting the volume and energy of the final structure for a relaxation run. By employing this model, we sample thousands of structures and fit a CE model to the energies of these GNN-relaxed structures. This approach, utilizing a large training dataset, effectively reduces the risk of overfitting, yielding a CE model with a root-mean-square error (RMSE) below 10 meV/atom. We validate our method's effectiveness in two test cases: the (Cr,Hf,Mo,Ta,Ti,Zr)B$_2$ diboride system and the Refractory High-Entropy Alloy (HEA) AlHfNbTaTiZr system. Our findings demonstrate the significant advantages of integrating a GNN model, specifically the M3GNet network, with CE methods for the efficient predictive analysis of chemical ordering in High Entropy Materials. The accelerating capabilities of the hybrid ML-CE approach to investigate the evolution of Short Range Ordering (SRO) in a large number of stoichiometric systems. Finally, we show how it is possible to correlate the strength of chemical ordering to easily accessible alloy parameters., Comment: 20 pages, 11 figures, presented at TMS 2024

Published
2024

2. Efficient machine-learning model for fast assessment of elastic properties of high-entropy alloys

Author

Vazquez, Guillermo, Singh, Prashant, Sauceda, Daniel, Couperthwaite, Richard, Britt, Nicholas, Youssef, Khaled, Johnson, Duane D., and Arróyave, Raymundo

Subjects
Condensed Matter - Materials Science
Abstract

We combined descriptor-based analytical models for stiffness-matrix and elastic-moduli with mean-field methods to accelerate assessment of technologically useful properties of high-entropy alloys, such as strength and ductility. Model training for elastic properties uses Sure-Independence Screening (SIS) and Sparsifying Operator (SO) method yielding an optimal analytical model, constructed with meaningful atomic features to predict target properties. Computationally inexpensive analytical descriptors were trained using a database of the elastic properties determined from density functional theory for binary and ternary subsets of Nb-Mo-Ta-W-V refractory alloys. The optimal Elastic-SISSO models, extracted from an exponentially large feature space, give an extremely accurate prediction of target properties, similar to or better than other models, with some verified from existing experiments. We also show that electronegativity variance and elastic-moduli can directly predict trends in ductility and yield strength of refractory HEAs, and reveals promising alloy concentration regions., Comment: 17 Pages; 10 Figures; 3 Tables

Published
2022
Full Text
View/download PDF

4. Uncertainty Propagation in a Multiscale CALPHAD-Reinforced Elastochemical Phase-field Model

Author

Attari, Vahid, Honarmandi, Pejman, Duong, Thien, Sauceda, Daniel J, Allaire, Douglas, and Arroyave, Raymundo

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Applied Physics
Abstract

ICME approaches provide decision support for materials design by establishing quantitative process-structure-property relations. Confidence in the decision support, however, must be achieved by establishing uncertainty bounds in ICME model chains. The quantification and propagation of uncertainty in computational materials science, however, remains a rather unexplored aspect of computational materials science approaches. Moreover, traditional uncertainty propagation frameworks tend to be limited in cases with computationally expensive simulations. A rather common and important model chain is that of CALPHAD-based thermodynamic models of phase stability coupled to phase field models for microstructure evolution. Propagation of uncertainty in these cases is challenging not only due to the sheer computational cost of the simulations but also because of the high dimensionality of the input space. In this work, we present a framework for the quantification and propagation of uncertainty in a CALPHAD-based elasto-chemical phase field model. We motivate our work by investigating the microstructure evolution in Mg$_2$(Si$_x$Sn$_{1-x}$) thermoelectric materials. We first carry out a Markov Chain Monte Carlo-based inference of the CALPHAD model parameters for this pseudobinary system and then use advanced sampling schemes to propagate uncertainties across a high-dimensional simulation input space. Through high-throughput phase field simulations we generate 200,000 time series of synthetic microstructures and use machine learning approaches to understand the effects of propagated uncertainties on the microstructure landscape of the system under study. The microstructure dataset has been curated in the Open Phase-field Microstructure Database (OPMD), available at \href{http://microstructures.net}{http://microstructures.net}.

Published
2019
Full Text
View/download PDF

5. The Effect of Chemical Disorder on Defect Formation and Migration in Disordered MAX Phases

Author

Singh, Prashant, Sauceda, Daniel, and Arroyave, Raymundo

Subjects
Condensed Matter - Materials Science
Abstract

MAX phases have attracted increased attention due to their unique combination of ceramic and metallic properties. Point-defects are known to play a vital role in the structural, electronic and transport properties of alloys in general and this system in particular. As some MAX phases have been shown to be stable in non-stoichiometric compositions, it is likely that such alloying effects will affect the behavior of lattice point defects. This problem, however, remains relatively unexplored. In this work, we investigate the alloying effect on the structural-stability, energy-stability, electronic-structure, and diffusion barrier of point defects in MAX phase alloys within a first-principles density functional theory framework. The vacancy (V$_{M}$, V$_{A}$, V$_{X}$) and antisite (M-A; M-X) defects are considered with M and A site disorder in (Zr-M)$_{2}$(AA${'}$)C, where M=Cr,Nb,Ti and AA${'}$=Al, Al-Sn, Pb-Bi. Our calculations suggest that the chemical disorder helps lower the V$_{A}$ formation energies compared to V$_{M}$ and V$_{X}$. The V$_{A}$ diffusion barrier is also significantly reduced for M-site disorder compared to their ordered counterpart. This is very important finding because reduced barrier height will ease the Al diffusion at high-operating temperatures, which will help the formation of passivating oxide layer (i.e., Al$_{2}$O$_{3}$ in aluminum-based MAX phases) and will slow down or stop the material degradation. We believe that our study will provide a fundamental understanding and an approach to tailor the key properties that can lead to the discovery of new MAX phases., Comment: 26 pages, 18 figures, 2 Tables

Published
2019
Full Text
View/download PDF

16. Design and construction of an air cooled ammonia absorber

Author

Velazquez, Nicolas, Sauceda, Daniel, Quintero-Nunez, Margarito, and Best, Roberto

Subjects
Ammonia -- Usage, Ammonia -- Thermal properties, Engineering and manufacturing industries, Environmental issues
Abstract

This paper presents the design criteria, methodology, and results of the basic and detailed engineering for a descending film ammonia absorber using air cooled finned tubes, which is part of an advanced absorption cooling system (solar generator absorber heat exchange cycle). The design consists in determining all the construction parameters for the air cooled ammonia absorption unit, starting with the operating conditions defined by a thermodynamical simulation of the process considering both physical and operational design restrictions. The chosen option was based on a comparison between the advantages and disadvantages of each possible array, type, and geometry. After performing the operational simulation, thermal and mechanical designs, and the consistency analysis, it was found that an absorption unit using 29 5/8 NPT 14 (BWG) steel carbon ASTM A-179 tubes, with pure SB-234 aluminum fins was the best option. The tubes are arranged in an equilateral triangle fashion, with crossed airflow cooling. [DOI: 10.1115/1.3097273] Keywords: solar cooling, absorbers, refrigeration systems, cooling cycle, air conditioning

Published
2009

17. A theoretical investigation of the effect of Ga alloying on thermodynamic stability, electronic-structure, and oxidation resistance of Ti2AlC MAX phase.

Author

Sauceda, Daniel, Singh, Prashant, and Arroyave, Raymundo

Subjects
GALLIUM alloys, TRANSITION metal carbides, HEAT of formation, SURFACE segregation, TRANSITION metal alloys, OXIDATION, CHEMICAL structure
Abstract

We present a systematic investigation of thermodynamic stability, phase-reaction, and chemical activity of Al containing disordered Ti2(Al-Ga)C MAX phases using machine-learning driven high-throughput framework to understand the oxidation resistance behavior with increasing temperature and exposure to static oxygen. The A-site (at Al) disordering in Ti2AlC MAX (M=Ti, A=Al, X=C) with Ga shows significant change in the chemical activity of Al with increasing temperature and exposure to static oxygen, which is expected to enable surface segregation of Al, thereby, the formation of Al2O3 and improved oxidation resistance. We performed in-depth convex hull analysis of ternary Ti–Al–C, Ti–Ga–C, and Ti–Al–Ga–C based MAX phase, and provide detailed contribution arising from electronic, chemical and vibrational entropies. The thermodynamic analysis shows change in the Gibbs formation enthalpy (ΔGform) at higher temperatures, which implies an interplay of temperature-dependent enthalpy and entropic contributions in oxidation resistance Ga doped Ti2AlC MAX phases. A detailed electronic structure and chemical bonding analysis using crystal orbital Hamilton population method reveal the origin of change in phases stability and in oxidation resistance in disorder Ti2(Al1−xGax)C MAX phases. Our electronic structure analysis correlate well with the change in oxidation resistance of Ga doped MAX phases. We believe our study provides a useful guideline to understand to role of alloying on electronic, thermodynamic, and oxidation related mechanisms of bulk MAX phases, which can work as a precursor to understand oxidation behavior of two-dimensional MAX phases, i.e., MXenes (transition metal carbides, carbonitrides and nitrides). [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
View/download PDF

21. Experimental study on the potential of combining TiO2, ZnO, and Al2O3 nanoparticles to improve the performance of a double-slope solar still equipped with saline water preheating.

Author

Carranza, Francisco, Villa, Claudia-Daniella, Aguilar, José, Borbón-Nuñez, Hugo A., and Sauceda, Daniel

Subjects
SOLAR stills, SALINE waters, TITANIUM dioxide, NANOPARTICLES, HEAT transfer, METAL nanoparticles
Abstract

Solar stills are an excellent option for providing freshwater to isolated communities living near the coast of Baja California, Mexico, and facing scarcity. Double-slope solar stills are simple and easy to operate; however, they normally produce low volumes of condensate. To overcome this, changes to the architecture of the still, implementation of mechanical items, or addition of nanoparticles to the water have been proposed. Since coupling the still with a solar water preheater and adding nanomaterials can be done without incurring in costly designs, and provided that using two types of nanoparticles simultaneously has the potential to further enhance the heat transfer capabilities, these options were investigated here. A spiral solar heater, utilized to increase the feedwater temperature, and combinations of TiO2, ZnO, and Al2O3 nanoparticles were implemented to augment the yield of a double-slope solar still. The nanostructures were specifically synthesized for this application and experiments were done at the climate of Ensenada, Baja California. Nanostructures whose shape allowed wide contact with the water and with adequate absorptivity were produced. Peak yields and efficiencies of 5.46 L/m2 and 59.9% were achieved combining TiO2 + Al2O3, and 4.72 L/m2 and 50.2% with TiO2 + ZnO at costs between 0.034 and 0.038 US$/L. [ABSTRACT FROM AUTHOR]

Published
2021
Full Text
View/download PDF

22. Experimental study on the potential of combining TiO2, ZnO, and Al2O3nanoparticles to improve the performance of a double-slope solar still equipped with saline water preheating

Author

Carranza, Francisco, Villa, Claudia-Daniella, Aguilar, José, Borbón-Nuñez, Hugo A., and Sauceda, Daniel

Abstract

Solar stills are an excellent option for providing freshwater to isolated communities living near the coast of Baja California, Mexico, and facing scarcity. Double-slope solar stills are simple and easy to operate; however, they normally produce low volumes of condensate. To overcome this, changes to the architecture of the still, implementation of mechanical items, or addition of nanoparticles to the water have been proposed. Since coupling the still with a solar water preheater and adding nanomaterials can be done without incurring in costly designs, and provided that using two types of nanoparticles simultaneously has the potential to further enhance the heat transfer capabilities, these options were investigated here. A spiral solar heater, utilized to increase the feedwater temperature, and combinations of TiO2, ZnO, and Al2O3nanoparticles were implemented to augment the yield of a double-slope solar still. The nanostructures were specifically synthesized for this application and experiments were done at the climate of Ensenada, Baja California. Nanostructures whose shape allowed wide contact with the water and with adequate absorptivity were produced. Peak yields and efficiencies of 5.46 L/m2and 59.9% were achieved combining TiO2+ Al2O3, and 4.72 L/m2and 50.2% with TiO2+ ZnO at costs between 0.034 and 0.038 US$/L.

Published
2021
Full Text
View/download PDF

23. Theoretical investigation of a direct-contact humidification-dehumidification desalination system.

Author

Alvarez, Alejandro, Carranza, Francisco, Zavala, Ivett, and Sauceda, Daniel

Subjects
SEAWATER distillation, HUMIDITY control, ENERGY conservation
Abstract

In this paper, a numerical investigation of a direct-contact humidification-dehumidification desalination system is presented. The system functions in an open loop for both the air and the water and does not have packing materials inside the humidifier and dehumidifier. The air is humidified by spraying hot seawater into it and then dehumidified by spraying cold freshwater. Both processes occur in a counterflow arrangement. The mass and energy conservation equations at steady-state conditions were solved through a finite difference scheme. During the solution, the properties of the fluids were evaluated for each discrete element. The influence of the geometry was also examined through the variation of the humidifier and dehumidifier height ratio. From the results, it was observed that for a fixed geometry, the freshwater production is enhanced through small droplet diameter and velocity and high seawater temperature and mass flow rate. The largest production achieved was 242.2 kg/h at a height ratio of 2.0. Increasing the height ratio was in general beneficial; however, the gains after it exceeded 1.5 were not significant. Since no attempt of heat recovery was done for this system, the gained output ratio was consistently low for all the cases analyzed. The largest value obtained was 0.58. [ABSTRACT FROM AUTHOR]

Published
2019
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results