Improved charge carrier transport across grain boundaries in N‐type PbSe by dopant segregation
Abstract: Doping is an important and routine method to tune the properties of semiconductors. Dopants accumulated at grain boundaries (GBs) can exert a profound influence on microstructures and transport properties of heat and charge. To unravel the effect of dopant accumulation at GBs on the scattering of electrons, individual high-angle GBs in three PbSe samples doped with different amounts of Cu using a home-designed correlative characterization platform combining electron backscatter diffraction, microcircuit transport property measurements, and atom probe tomography are studied. The findings reveal that the segregation of Cu dopants to GBs reduces the GB potential barrier height. Once the GB phase reaches an equilibrium with saturated Cu, the extra Cu dopants distribute homogeneously inside the grains, compensating for vacancies and improving the electrical conductivity of the PbSe grains. The results correlate the Cu distribution at GBs and grains with local electrical properties, enlightening strategies for manipulating advanced functional materials by GB segregation engineering
- Location
-
Deutsche Nationalbibliothek Frankfurt am Main
- Extent
-
Online-Ressource
- Language
-
Englisch
- Notes
-
Small science. - 5, 3 (2025) , 2300299, ISSN: 2688-4046
- Classification
-
Physik
- Event
-
Veröffentlichung
- (where)
-
Freiburg
- (who)
-
Universität
- (when)
-
2024
- Creator
-
Zhang, Huaide
Shen, Minghao
Stenz, Christian
Teichrib, Christian
Wu, Riga
Schäfer, Lisa
Nan, Lin
Zhou, Yiming
Zhou, Chongjian
Cojocaru-Mirédin, Oana
Wuttig, Matthias
Yu, Yuan
- DOI
-
10.1002/smsc.202300299
- URN
-
urn:nbn:de:bsz:25-freidok-2534009
- Rights
-
Open Access; Der Zugriff auf das Objekt ist unbeschränkt möglich.
- Last update
-
15.08.2025, 7:22 AM CEST
Data provider
Deutsche Nationalbibliothek. If you have any questions about the object, please contact the data provider.
Associated
- Zhang, Huaide
- Shen, Minghao
- Stenz, Christian
- Teichrib, Christian
- Wu, Riga
- Schäfer, Lisa
- Nan, Lin
- Zhou, Yiming
- Zhou, Chongjian
- Cojocaru-Mirédin, Oana
- Wuttig, Matthias
- Yu, Yuan
- Universität
Time of origin
- 2024
Other Objects (12)
Atom Probe Tomography Advances Chalcogenide Phase‐Change and Thermoelectric Materials
Metavalent bonding impacts charge carrier transport across grain boundaries
Atom probe tomography advances chalcogenide phase‐change and thermoelectric materials
Atom Probe Tomography Advances Chalcogenide Phase-Change and Thermoelectric Materials
Chalcogenide Thermoelectrics Empowered by an Unconventional Bonding Mechanism
Improved Charge Carrier Transport Across Grain Boundaries in N‐type PbSe by Dopant Segregation
Improved Charge Carrier Transport Across Grain Boundaries in N‐type PbSe by Dopant Segregation
Chalcogenide Thermoelectrics Empowered by an Unconventional Bonding Mechanism
Strong charge carrier scattering at grain boundaries of PbTe caused by the collapse of metavalent bonding
Employing Interfaces with Metavalently Bonded Materials for Phonon Scattering and Control of the Thermal Conductivity in TAGS‐ x Thermoelectric Materials
Chalcogenides by Design: Functionality through Metavalent Bonding and Confinement
Dopant-segregation to grain boundaries controls electrical conductivity of n-type NbCo(Pt)Sn half-Heusler alloy mediating thermoelectric performance
Atom Probe Tomography Advances Chalcogenide Phase‐Change and Thermoelectric Materials
Metavalent bonding impacts charge carrier transport across grain boundaries
Atom probe tomography advances chalcogenide phase‐change and thermoelectric materials
Atom Probe Tomography Advances Chalcogenide Phase-Change and Thermoelectric Materials
Chalcogenide Thermoelectrics Empowered by an Unconventional Bonding Mechanism
Improved Charge Carrier Transport Across Grain Boundaries in N‐type PbSe by Dopant Segregation
Improved Charge Carrier Transport Across Grain Boundaries in N‐type PbSe by Dopant Segregation
Chalcogenide Thermoelectrics Empowered by an Unconventional Bonding Mechanism
Strong charge carrier scattering at grain boundaries of PbTe caused by the collapse of metavalent bonding
Employing Interfaces with Metavalently Bonded Materials for Phonon Scattering and Control of the Thermal Conductivity in TAGS‐ x Thermoelectric Materials
Chalcogenides by Design: Functionality through Metavalent Bonding and Confinement
Dopant-segregation to grain boundaries controls electrical conductivity of n-type NbCo(Pt)Sn half-Heusler alloy mediating thermoelectric performance
Atom Probe Tomography Advances Chalcogenide Phase‐Change and Thermoelectric Materials
Metavalent bonding impacts charge carrier transport across grain boundaries
Atom probe tomography advances chalcogenide phase‐change and thermoelectric materials
Atom Probe Tomography Advances Chalcogenide Phase-Change and Thermoelectric Materials
Chalcogenide Thermoelectrics Empowered by an Unconventional Bonding Mechanism
Improved Charge Carrier Transport Across Grain Boundaries in N‐type PbSe by Dopant Segregation
Improved Charge Carrier Transport Across Grain Boundaries in N‐type PbSe by Dopant Segregation
Chalcogenide Thermoelectrics Empowered by an Unconventional Bonding Mechanism
Strong charge carrier scattering at grain boundaries of PbTe caused by the collapse of metavalent bonding
Employing Interfaces with Metavalently Bonded Materials for Phonon Scattering and Control of the Thermal Conductivity in TAGS‐ x Thermoelectric Materials
Chalcogenides by Design: Functionality through Metavalent Bonding and Confinement