Materials Map

Discover the materials research landscape. Find experts, partners, networks.

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The Materials Map is an open tool for improving networking and interdisciplinary exchange within materials research. It enables cross-database search for cooperation and network partners and discovering of the research landscape.

The dashboard provides detailed information about the selected scientist, e.g. publications. The dashboard can be filtered and shows the relationship to co-authors in different diagrams. In addition, a link is provided to find contact information.

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Materials Map under construction

The Materials Map is still under development. In its current state, it is only based on one single data source and, thus, incomplete and contains duplicates. We are working on incorporating new open data sources like ORCID to improve the quality and the timeliness of our data. We will update Materials Map as soon as possible and kindly ask for your patience.

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Duarte, Valdemar R.

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Universidade Nova de Lisboa

in Cooperation with on an Cooperation-Score of 37%

Topics

Publications (24/24 displayed)

  • 2024High-performance Ni-based superalloy 718 fabricated via arc plasma directed energy deposition ; effect of post-deposition heat treatments on microstructure and mechanical properties21citations
  • 2024High-strength low-alloy steel fabricated by in situ interlayer hot forging arc-based directed energy deposition assisted with direct cooling ; Microstructural and mechanical properties evaluation4citations
  • 2024High-performance Ni-based superalloy 718 fabricated via arc plasma directed energy deposition21citations
  • 2024Enhancing manufacturing and post-processing properties of WAAM ER110 HSLA steel ; in situ hot forging + post-deposited heat treatment effects on surface quality and specific cutting energy2citations
  • 2023In situ interlayer hot forging arc-based directed energy deposition of Inconel® 62533citations
  • 2023In situ interlayer hot forging arc plasma directed energy deposition of Inconel® 62519citations
  • 2023In situ interlayer hot forging arc-based directed energy deposition of Inconel® 625 ; process development and microstructure effects33citations
  • 2023In situ interlayer hot forging arc-based directed energy deposition of Inconel® 625: process development and microstructure effects33citations
  • 2023In situ interlayer hot forging arc plasma directed energy deposition of Inconel® 625: microstructure evolution during heat treatments19citations
  • 2023In situ interlayer hot forging arc plasma directed energy deposition of Inconel® 625 ; microstructure evolution during heat treatments19citations
  • 2022In-situ hot forging direct energy deposition-arc of CuAl8 alloy21citations
  • 2022In-situ hot forging directed energy deposition-arc of CuAl8 alloy21citations
  • 2021Wire and Arc Additive Manufacturing of High-Strength Low-Alloy Steel40citations
  • 2021Benchmarking of Nondestructive Testing for Additive Manufacturing33citations
  • 2021Effect of heat treatments on 316 stainless steel parts fabricated by wire and arc additive manufacturing : Microstructure and synchrotron X-ray diffraction analysis143citations
  • 2021Wire and Arc Additive Manufacturing of High‐Strength Low‐Alloy Steel: Microstructure and Mechanical Properties40citations
  • 2021Effect of heat treatments on 316 stainless steel parts fabricated by wire and arc additive manufacturing: Microstructure and synchrotron X-ray diffraction analysis143citations
  • 2020In-situ strengthening of a high strength low alloy steel during Wire and Arc Additive Manufacturing (WAAM)153citations
  • 2020Influence of processing parameters on the density of 316L stainless steel parts manufactured through laser powder bed fusion36citations
  • 2020Hot forging wire and arc additive manufacturing (HF-WAAM)148citations
  • 2020Effect of milling parameters on HSLA steel parts produced by Wire and Arc Additive Manufacturing (WAAM)114citations
  • 2019Wire and arc additive manufacturing of HSLA steel: Effect of thermal cycles on microstructure and mechanical properties306citations
  • 2019Large-dimension metal parts produced through laser powder bed fusioncitations
  • 2019Current Status and Perspectives on Wire and Arc Additive Manufacturing (WAAM)593citations

Places of action

Chart of shared publication
Santos, Telmo G.
18 / 62 shared
Oliveira, J. P.
7 / 45 shared
Schell, Norbert
12 / 180 shared
Filho, João Da Cruz Payão
8 / 9 shared
Cormier, Jonathan
2 / 68 shared
Maawad, Emad
10 / 59 shared
Fonseca, Fábio Machado Alves Da
2 / 2 shared
Bordas-Czaplicki, Mélanie
2 / 2 shared
Li, J. Y.
8 / 8 shared
Zhang, Y.
8 / 149 shared
Farias, Francisco Werley Cipriano
10 / 14 shared
Figueiredo, Arthur Ribeiro
2 / 3 shared
Amendoeira, Daniel A. E.
1 / 1 shared
Fonseca, Pedro P.
2 / 4 shared
Hassel, Thomas
1 / 33 shared
Moreno-Uribe, Andrés M.
1 / 1 shared
Oliveira, João P.
2 / 7 shared
Viebranz, Vincent F.
1 / 1 shared
Cota, Bruno S.
1 / 1 shared
Oliveira, João Pedro
12 / 98 shared
Silva, Tiago
1 / 5 shared
Cota, Bruno Silva
1 / 2 shared
Machado, Carla M.
1 / 3 shared
Avila, J. A.
3 / 8 shared
Oliveira Felice, Igor
2 / 3 shared
Santos, T. G.
4 / 5 shared
Felice, Igor Oliveira
4 / 4 shared
Rodrigues, Tiago A.
12 / 20 shared
Schell, N.
4 / 220 shared
Miranda, R. M.
7 / 58 shared
Machado, Miguel A.
1 / 11 shared
Goodwin, Carley
1 / 1 shared
Huber, Daniel E.
1 / 1 shared
Silva, Carlos M. A.
2 / 9 shared
Pombinha, Pedro
2 / 2 shared
Pragana, João P. M.
2 / 3 shared
Coutinho, Luísa
2 / 2 shared
Shen, Jiajia
2 / 40 shared
Avila, Julian A.
4 / 6 shared
Escobar, J. D.
3 / 19 shared
Ribamar, G. G.
2 / 11 shared
Miranda, Rosa M.
1 / 2 shared
Tomás, D.
1 / 1 shared
Rossinyol, Emma
1 / 4 shared
Machado, Carla
1 / 3 shared
Lopes, João G.
1 / 16 shared
Chart of publication period
2024
2023
2022
2021
2020
2019

Co-Authors (by relevance)

  • Santos, Telmo G.
  • Oliveira, J. P.
  • Schell, Norbert
  • Filho, João Da Cruz Payão
  • Cormier, Jonathan
  • Maawad, Emad
  • Fonseca, Fábio Machado Alves Da
  • Bordas-Czaplicki, Mélanie
  • Li, J. Y.
  • Zhang, Y.
  • Farias, Francisco Werley Cipriano
  • Figueiredo, Arthur Ribeiro
  • Amendoeira, Daniel A. E.
  • Fonseca, Pedro P.
  • Hassel, Thomas
  • Moreno-Uribe, Andrés M.
  • Oliveira, João P.
  • Viebranz, Vincent F.
  • Cota, Bruno S.
  • Oliveira, João Pedro
  • Silva, Tiago
  • Cota, Bruno Silva
  • Machado, Carla M.
  • Avila, J. A.
  • Oliveira Felice, Igor
  • Santos, T. G.
  • Felice, Igor Oliveira
  • Rodrigues, Tiago A.
  • Schell, N.
  • Miranda, R. M.
  • Machado, Miguel A.
  • Goodwin, Carley
  • Huber, Daniel E.
  • Silva, Carlos M. A.
  • Pombinha, Pedro
  • Pragana, João P. M.
  • Coutinho, Luísa
  • Shen, Jiajia
  • Avila, Julian A.
  • Escobar, J. D.
  • Ribamar, G. G.
  • Miranda, Rosa M.
  • Tomás, D.
  • Rossinyol, Emma
  • Machado, Carla
  • Lopes, João G.
OrganizationsLocationPeople

article

In situ interlayer hot forging arc plasma directed energy deposition of Inconel® 625

  • Schell, Norbert
  • Filho, João Da Cruz Payão
  • Oliveira Felice, Igor
  • Maawad, Emad
  • Santos, Telmo G.
  • Duarte, Valdemar R.
  • Li, J. Y.
  • Zhang, Y.
  • Farias, Francisco Werley Cipriano
  • Oliveira, João Pedro
Abstract

<p>The study reports that the combined use of in situ interlayer hot forging and post-deposition heat treatment (PDHT) could alter the typical coarse and oriented microstructure of the Ni-based superalloy 625 obtained by arc plasma directed energy deposition (DED) to a fine and non-oriented condition. In situ synchrotron X-ray diffraction and electron backscatter diffraction showed that the high-temperature (1100 °C/ 1 h) PDHT induced significant recrystallization, leading to grain refinement and low texture index, while partially dissolving deleterious Laves and δ phases. Low-temperature (980 °C/ 1 h) PDHT had a limited effect on the grain size refinement and induced the formation of secondary phases. It is shown that conventional heat treatments applied to Ni-based superalloy 625 obtained by arc plasma DED are not conducive to optimized microstructure features. In situ hot forging induced enough crystal defects to promote static recrystallization during PDHT. Besides, high-temperature PDHT met the AMS 5662 grain size requirements.</p>

Topics
  • Deposition
  • impedance spectroscopy
  • grain
  • grain size
  • phase
  • x-ray diffraction
  • texture
  • defect
  • electron backscatter diffraction
  • recrystallization
  • directed energy deposition
  • forging
  • superalloy
  • dissolving
  • Accelerator mass spectrometry