Abstract
Most metallic elements possess one relatively close packed structure of body-centered cubic (BCC), face-centered cubic (FCC) and hexagonal close packed (HCP) structures. Access to these structures as a function of temperature and pressure varies for different groups in the periodic table. Under low pressures, the copper group elements (copper (Cu), silver (Ag) and gold (Au)) only has a FCC structure regardless of temperatures. Recently, BCC Au was detected under extreme compression. The structural preference for a given metal element is still not understood. In this work, we surprisingly observed formation of BCC Au from amorphous Au as well as FCC Au within an electron self-transferred Au nanoparticle supported by our synthesized zirconium hydroxide nitrate tube. We propose a theory behind this unexpected phase formation: the increase in atomic electron cloud densities of Au atoms enabled by the electron transfer contributes more free electrons over the Au nanoparticle, enhancing metallic bonding strength to hold Au atoms closer to form a BCC structure that can store denser electron states within a Fermi sphere in first Brillouin zone as compared to FCC Au. This can also explain formation of BCC Au under compression. Our theory and strategy can guide how to expand the structure world of metals under ambient conditions for beneficial applications.
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Experimental details and supplementary results.
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