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Controlling the band gap energy of cluster-assembled materials
Sukhendu Mandal
, Arthur C. Reber
, Meichun Qian
, Paul S. Weiss
, Shiv N. Khanna
,
Ayusman Sen
Chemistry
Research output
:
Contribution to journal
›
Article
›
peer-review
90
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Scopus citations
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Keyphrases
Band Gap Energy
100%
Cluster-assembled Materials
100%
Counterion
54%
Conduction Band Edge
27%
Arsenic
18%
Valence Band
18%
Composite Construction
18%
Internal Electric Field
18%
Cluster Assembly
18%
Physical Mechanism
9%
Band Gap
9%
High Dimension
9%
Alkali Metals
9%
Bulky Ligands
9%
Emergent Properties
9%
Highly Tunable
9%
Linker
9%
Ion Cluster
9%
Theoretical Description
9%
Tunable Electronic Properties
9%
Lone Pair
9%
Valence Band Edge
9%
Ionic Solids
9%
Two-dimensional Assembly
9%
Band Broadening
9%
Charge Transfer Complex
9%
Enabling Control
9%
Orbital Theory
9%
Electronic Characters
9%
Material Science
Arsenic
100%
Composite Material
100%
Magnetic Property
50%
Alkali Metal
50%
Electronic Property
50%
Phase Composition
50%
Energy Levels
50%
Engineering
Band Gap Energy
100%
Valence Band
27%
Conduction Band Edge
27%
Arsenic
18%
Building Block
18%
Dimensionality
18%
Internal Electric Field
18%
Nanoscale
9%
Broadening
9%
Two Dimensional
9%
Band Edge
9%
Ionic Cluster
9%
Great Variety
9%
Phase Composition
9%
Electronic State
9%
Energy Levels
9%
Band Gap
9%
Orbital Theory
9%