Indu Dhiman scite author profile

Lithium (Li) metal has the highest theoretical capacity and is essential for energy storage technologies beyond conventional Li chemistries. However, its utilization inevitably leads to dendrite growth from repeated plating and stripping, eventually shorts the battery. The process that leads to shorting and the consequential electrochemical impacts are not well understood due to its dynamic features. Herein, we apply neutron radiography to study the Li dendrite growth in real time. The dynamic distribution of Li flowing from the anode to cathode during charge, induced by the internal short circuit due to Li dendrite growth, has been observed. Furthermore, a competing mechanism after battery shorting between the short-induced self-discharge and charge is proposed to explain the voltage drop/rise during the extended charging time. Our work provides mechanistic insights with a deep understanding of dendrite Li shorting and redistribution. This can lead to safe design principles of Li metal electrodes in batteries.

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Influence of A-site ionic radii on the magnetic structure of charge-orderedLa0.5Ca0.5−xSrxMn
Dhiman
¹
,
Das
²
,
Mishra
³

et al. 2008
Phys. Rev. B
34
9
32
0
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Effect of molecular shape on rotation under severe confinement

Dhiman

Bhowmik

Shrestha

et al. 2018

Chemical Engineering Science

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Study of CeNi4Mn by neutron diffraction

Dhiman¹,

Das²,

Dhar³

et al. 2007

Solid State Communications

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We report neutron diffraction measurements on CeNi4Mn, which has recently been identified as a soft ferromagnet (Tc ~ 140 K) with a sizeable spin-transport polarization. Our data show conclusively that the Mn atoms occupy a unique site (4c) in the unit cell, which has the symmetry of the cubic MgCu4Sn-type structure. We infer a moment of 4.6 mu_B on Mn at 17 K, which is oriented ferromagnetically along the {101} plane. The amplitude of the Mn vibrational motion is found to be larger than that of Ce and Ni atoms at all temperatures, thereby lending support to theoretical prediction of rattling phonon modes in this compound.Comment: Accepted for publication in Solid State Commu

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Spontaneous Imbibition of a Wetting Fluid Into a Fracture With Opposing Fractal Surfaces: Theory and Experimental Validation

et al. 2019

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Spontaneous imbibition (SI) is a capillary-driven flow process, in which a wetting fluid moves into a porous medium displacing an existing non-wetting fluid. This process likely contributes to the loss of fracking fluids during hydraulic fracturing operations. It has also been proposed as a method for an enhanced recovery of hydrocarbons from fractured unconventional reservoirs. Numerous analytical and numerical approaches have been employed to model SI. Invariably, these idealize a fracture as the gap formed between parallel flat surfaces. In reality, rock fracture surfaces are rough over multiple scales, and this roughness will influence the contact angle and rate of fluid uptake. We derived an analytical model for the early-time SI behavior within a fracture bounded by parallel impermeable surfaces with fractal roughness assuming laminar flow. The model was tested by fitting it to experimental data for the SI of deionized water into air-filled rock fractures. Twenty cores from two rock types were investigated: a tight sandstone (Crossville) and a gas shale (Mancos). A simple Mode I longitudinal fracture was produced in each core by compressive loading between parallel flat plates using the Brazilian method. Half of the Mancos cores were fractured perpendicular to bedding, while the other half were fractured parallel to bedding. The two main parameters in the SI model are the mean separation distance between the fracture surfaces, [Formula: see text], and the fracture surface fractal dimension [Formula: see text]. The [Formula: see text] was estimated for each core by measuring the geometric mean fracture aperture width through image analysis of the top and bottom faces, while [Formula: see text] was estimated inversely by fitting the SI model to measurements of water uptake obtained using dynamic neutron radiography. The [Formula: see text] values ranged from 45[Formula: see text][Formula: see text]m to 190[Formula: see text][Formula: see text]m, with a median of 93[Formula: see text][Formula: see text]m. The SI model fitted the height of uptake versus time data very well for all of the rock cores investigated; medians of the resulting root mean squared errors and coefficients of determination were 0.99[Formula: see text]mm and 0.963, respectively. Estimates of [Formula: see text] ranged from 2.04 to 2.45, with a median of 2.24. Statistically, all of the [Formula: see text] values were significantly greater than two, confirming the fractal nature of the fracture surfaces. Future research should focus on forward prediction through independent measurements of [Formula: see text] and extension of the existing SI model to late times (through the inclusion of gravity) and fractures with permeable surfaces.

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Indu Dhiman

Dynamic Lithium Distribution upon Dendrite Growth and Shorting Revealed by Operando Neutron Imaging

Influence of A-site ionic radii on the magnetic structure of charge-orderedLa0.5Ca0.5−xSrxMn
Dhiman
¹
,
Das
²
,
Mishra
³

et al. 2008
Phys. Rev. B
34
9
32
0
View full text Add to dashboard Cite

Effect of molecular shape on rotation under severe confinement

Study of CeNi4Mn by neutron diffraction

Spontaneous Imbibition of a Wetting Fluid Into a Fracture With Opposing Fractal Surfaces: Theory and Experimental Validation

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Resources

About

Indu Dhiman

Dynamic Lithium Distribution upon Dendrite Growth and Shorting Revealed by Operando Neutron Imaging

Influence of A-site ionic radii on the magnetic structure of charge-orderedLa0.5Ca0.5−xSrxMnDhiman1, Das2, Mishra3 et al. 2008Phys. Rev. B349320View full textAdd to dashboardCite

Effect of molecular shape on rotation under severe confinement

Study of CeNi4Mn by neutron diffraction

Spontaneous Imbibition of a Wetting Fluid Into a Fracture With Opposing Fractal Surfaces: Theory and Experimental Validation

Contact Info

Product

Resources

About

Influence of A-site ionic radii on the magnetic structure of charge-orderedLa0.5Ca0.5−xSrxMn
Dhiman
¹
,
Das
²
,
Mishra
³

et al. 2008
Phys. Rev. B
34
9
32
0
View full text Add to dashboard Cite