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Bio
During his career, Lambert has produced over 310 publications and trained over 80 PhD students. During the 20 months since 2015 alone, he produced 44 publications, including 20 papers in high-impact-factor journals Nature Materials, Nature Communications, Nanoletters, PNAS, JACS, Angewandte Chemie, Nanoscale and Chem. Soc. Rev.
Lambert is a Research Professor, QinetiQ Fellow, a Member of Academia Europaea and recent Founding Director of the Lancaster Quantum Technology Centre. His theories of quantum interference in single molecules aim to control and exploit quantum interference in real world applications. Nowadays, to conduct world-leading research in molecular-scale dynamics, it is necessary to establish a triangle of groups specialising in theory, synthesis and measurement. Lambert’s group of 4 postdocs and 14 PhD students is the theory apex of several such triangles.
As the theorist within the MOLESCO (2012-16) and FUNMOLS (2008-2012) European networks, involving 9 other teams, all of which are experimentalists, his group has stimulated new targets for synthesis and measurement, leading to experimental implementations of several of his theoretical schemes for quantum interference and molecular-scale thermoelectricity. These activities are founded on his theoretical tools for predicting charge, spin and thermal transport through superconducting nanostructures and single molecules, including the internationally recognised SMEAGOL code [Nature Materials 2005 4, 335; Phys. Rev. 2006 B73 085414]] (>1300 citations), which is used by over 150 groups in 29 countries.
Lambert is a Research Professor, QinetiQ Fellow, a Member of Academia Europaea and recent Founding Director of the Lancaster Quantum Technology Centre. His theories of quantum interference in single molecules aim to control and exploit quantum interference in real world applications. Nowadays, to conduct world-leading research in molecular-scale dynamics, it is necessary to establish a triangle of groups specialising in theory, synthesis and measurement. Lambert’s group of 4 postdocs and 14 PhD students is the theory apex of several such triangles.
As the theorist within the MOLESCO (2012-16) and FUNMOLS (2008-2012) European networks, involving 9 other teams, all of which are experimentalists, his group has stimulated new targets for synthesis and measurement, leading to experimental implementations of several of his theoretical schemes for quantum interference and molecular-scale thermoelectricity. These activities are founded on his theoretical tools for predicting charge, spin and thermal transport through superconducting nanostructures and single molecules, including the internationally recognised SMEAGOL code [Nature Materials 2005 4, 335; Phys. Rev. 2006 B73 085414]] (>1300 citations), which is used by over 150 groups in 29 countries.
Research Interests
Papers共 169 篇Author StatisticsCo-AuthorSimilar Experts
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Nature Nanotechnologypp.1-7, (2024)
Zi-Xian Yang, Shadiah Albalawi,Shiqiang Zhao, Yao-Guang Li, Hewei Zhang, Yu-Ling Zou, Songjun Hou, Li-Chuan Chen,Jia Shi,Yang Yang, Qingqing Wu,Colin J Lambert,
Chemistry (Weinheim an der Bergstrasse, Germany)pp.e202402095-e202402095, (2024)
The journal of physical chemistry. C, Nanomaterials and interfacesno. 28 (2023): 13751-13758
Inorganic chemistryno. 51 (2023): 20940-20947
Nature communicationsno. 1 (2023): 7695-7695
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