| Literature DB >> 33523975 |
Jingxu Zheng1, Lynden A Archer2,3.
Abstract
Scalable approaches for precisely manipulating the growth of crystals are of broad-based science and technological interest. New research interests have reemerged in a subgroup of these phenomena-electrochemical growth ofEntities:
Year: 2021 PMID: 33523975 PMCID: PMC7787491 DOI: 10.1126/sciadv.abe0219
Source DB: PubMed Journal: Sci Adv ISSN: 2375-2548 Impact factor: 14.136
Fig. 1Assessment of the requirements for affordable EES technologies that are suitable for integration into clean energy generation systems.
(A) Hourly power profiles for typical power demand and supply from solar-PV. Adapted with permission from (). (B) Levelized costs of energy (LCOE) production from solar-PV compared with levelized energy of storage (LCOS) costs of representative battery chemistries. Replotted according to (). Zn-based batteries show the lowest LCOS of ~$0.3/kWh. (C) The plating/stripping Coulombic efficiency (CE) requirements for metal anodes to achieve the cycle life targets. Each curve depicts the correlation between N:P ratio and the Coulombic inefficiency (=1 − CE), assuming 80% capacity retention after a certain number of cycles as specified in the legend. For example, the red curve depicts the relation between N:P ratio and Coulombic inefficiency to meet the goal of a battery cycle life equal to 1000 cycles. N:P ratio is defined as the ratio between the capacities of active materials in the negative electrode(anode) and the positive electrode(cathode), respectively, assuming the materials operate at their theoretical specific capacities. The curves are plotted by solving , where y is N:P ratio, x is Coulombic inefficiency, and T is the cycle life target. (D) Schematic cartoon showing the two key irreversibilities associated with Zn metal electrodes. Noncompact Zn electrodeposits lose electrochemical activity after they chemically react with the electrolyte (chemical instability) or physically detach from the current collector (physical orphaning).
Fig. 2Representative morphologies of Zn metal deposits obtained in electrodeposition or chemical reactions.
Scanning electron microscopy (SEM) images of electrodeposited (A) wire-like, (B) moss-like, (C) randomly oriented plate-like, (D) horizontally aligned plate-like, and (E) dendritic Zn metal. SEM images of chemically synthesized (F) horizontally aligned plate-like and (G) moss-like Zn metal. Adapted with permission from (, , , , ).
Fig. 3Classical electrochemistry framework of Zn metal electrodeposition.
(A) Schematic diagram showing the four fluxes near the electrochemical interface. The red curve shows the concentration (conc.) profile of the metal cations. (B) Current density–overpotential relation of Zn deposition in a 0.05 M ZnSO4 aqueous electrolyte. (C) Mass transport limit induced dendritic growth of Zn electrodeposits and corresponding concentration profile. Adapted with permission from (, ). (D) Electroconvection formed near an ion-selective membrane or metal electrodeposits. Adapted with permission from (, ). (E) Effects of dimensionless Damköhler numbers on electrodeposition morphology. (E-1) Exchange current density versus diffusion-limited current density, and (E-2) reaction rate versus self-diffusion rate. Adapted with permission from (, ).
Fig. 4Designing electrolytes for highly reversible Zn metal plating/stripping.
(A) Spider chart comparing electrolytes for Zn batteries. (B) Distribution of chemical species in aqueous Zn2+ electrolytes. (B-1) Pourbaix diagram. The top and bottom dashed lines represent oxygen evolution and hydrogen evolution reactions (HERs), respectively. (B-2) Fractions of different Zn2+-based species. (C) Transmission electron microscopy (TEM) characterization of Zn electrodeposits. Adapted with permission from (). (C-1 and C-2) TEM images and (C-3) selected area electron diffraction pattern. (D) Water-in-salt electrolyte for Zn metal deposition. Adapted with permission from (). (D-1) SEM image of Zn after cycling in water-in-salt electrolyte. (D-2) The plating/stripping voltage profile of Zn in water-in-salt electrolyte. (E) The molality-dependent parameters of high-concentration electrolytes. (F) Schematic diagram showing reaction kinetics of adsorbed (ads.) solvated Zn2+ in acetonitrile (AN) on electrode surface. Adapted with permission from (). (G) Cyclic voltammetry of organic Zn battery electrolytes: (G-1) AN-Zn(TFSI)2, (G-2) AN-Zn triflate (OTf), and (G-3) propylene carbonate (PC)–Zn(TFSI)2. Adapted with permission from ().
Fig. 5Crystallographic characteristics of zinc.
(A) Crystal model of HCP Zn metal. The red lattice denotes the primitive unit cells. The front, light blue layer and the back, dark blue layer are two close-packed layers that stack periodically (…ABABAB…) along the [002] direction (also called the c axis). (B) Weighted surface energy and surface energy anisotropy αγ of representative anode metals., where γ is the surface energy of (hkl), and is the area fraction of the (hkl) family in the Wulff shape. . αγ can be viewed as a normalized coefficient of variation of surface energy. A greater αγ value implies a larger anisotropy in the surface energies of the crystal facets exposed in its Wulff shape. In an extreme case of a perfectly isotropic crystal, αγ = 0. Plotted according to data reported in (). (C) Wulff shapes for metals of contemporary interest as battery anode materials. They depict the shape of the crystals at thermodynamic equilibrium. Adapted with permission using the database reported in (). (D) XRD analysis of the crystallographic texturing of Zn metal electrodeposits. (D-1) θ−2θ XRD line scans of Zn electrodeposits. (D-2) Peak intensity ratio I002:I101 of the scans shown in Fig. 5D-1. (D-3) 2D XRD of samples #3 and #4 shown in Fig. 5D-1. Adapted with permission from (). A.U., arbitrary units.
Fig. 6Approaches for regulating Zn electrodeposition morphology at the anode.
(A to C) Red: Design of electrode substrate/architecture. Adapted with permission from (, , , ). (D to F) Green: Design of artificial SEI (ASEI) . Adapted with permission from (, , ). (G to I) Blue: Design of electrolyte. Adapted with permission from (, , , , ). (J to L) Purple: Design of external factors. Adapted with permission from (, , , ).