Performance metrics for the objective assessment of capacitive deionization systems

Hawks, Steven A.; Ramachandran, Ashwin; Porada, S.; Campbell, Patrick G.; Suss, Matthew E.; Biesheuvel, P.M.; Santiago, Juan G.; Stadermann, Michael

doi:10.1016/j.watres.2018.10.074

Cited by 217 publications

(198 citation statements)

References 73 publications

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“…After the complete inversion of CDAC, there was no observable decrease in desalination performance, and the SAC value after the long‐term operation (6.67 mg g −1 ) was substantially higher than those obtained with the commercial ACs, which were 0.11, 0.66, and 1.47 mg g −1 for MSP20X, S51HF, and YS2, respectively. The current profiles of initial and final cycle are displayed in Figure S9 (Supporting Information), and the average salt adsorption rates (ASARs), energy consumption, and charge efficiencies (CEs) are also shown in Table S1 (Supporting Information) . It was noteworthy that commercial ACs manifested higher CEs than that of CDAC in early stage of CDI operations; however, due to the drop and rise of CEs in commercial ACs and CDAC, respectively, CDAC's CE was more than four times larger than those of commercial ACs.…”

Section: Resultsmentioning

confidence: 99%

Rapid Inversion of Surface Charges in Heteroatom‐Doped Porous Carbon: A Route to Robust Electrochemical Desalination

Kang

Kim

Chung

et al. 2019

Adv Funct Materials

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Given that a considerably large population suffers from shortage of water, there are numerous on‐going efforts to turn seawater into freshwater, and electrochemical desalination processes—particularly capacitive deionization (CDI)—have gained significant attention due to their high energy efficiency and reliable performance. Meanwhile, carbonaceous electrode materials, which are most commonly used in CDI systems, have poor long‐term stability due to unfavorable interactions with oxygen in saline water. Herein, rapid and vigorous inversion of surface charges in heteroatom‐doped carbon electrodes, which leads to a robust operation of CDI with high desalination capacity, is reported for the first time. By carbonization of coffee wastes, nitrogen‐ and sulfur‐codoped activated carbon with hierarchical micro/mesopores are prepared in an environmentally‐friendly manner, and this carbon results in a significantly higher inverted capacity than that of various activated carbon counterparts in long‐term CDI operations, without any sign of drop in performance. Investigations on the changes in physicochemical properties of the electrodes during the inversion disclose the favorable roles of nitrogen and sulfur dopants, which can be summarized as enlarging the difference between the surface charges of the two electrodes by chemical interactions with oxygen in the anode and carbon in the cathode.

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Section: Resultsmentioning

confidence: 99%

Rapid Inversion of Surface Charges in Heteroatom‐Doped Porous Carbon: A Route to Robust Electrochemical Desalination

Kang

Kim

Chung

et al. 2019

Adv Funct Materials

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“…4 shows, after reversal of the current direction, there is also a small "area" which corresponds to energy "output" (e.g. from 1 to 1.15 hr), i.e., where energy recovery is in theory possible [41], after which a much longer period follows where energy must be invested to run the cell (from 1.15 to 3 hr for Mode 2).…”

Section: Two Modes Of Operation Of Charge/discharge Cyclesmentioning

confidence: 99%

Theory of Water Desalination with Intercalation Materials

et al. 2018

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We present porous electrode theory for capacitive deionization (CDI) with electrodes containing nanoparticles that consist of a redox-active intercalation material. A geometry of a desalination cell is considered which consists of two porous electrodes, two flow channels and an anion-exchange membrane, and we use Nernst-Planck theory to describe ion transport in the aqueous phase in all these layers. A single-salt solution is considered, with unequal diffusion coefficients for anions and cations. Similar to previous models for CDI and electrodialysis, we solve the dynamic two-dimensional equations by assuming that flow of water, and thus the advection of ions, is zero in the electrode, and in the flow channel only occurs in the direction along the electrode and membrane. In all layers, diffusion and migration are only considered in the direction perpendicular to the flow of water. Electronic as well as ionic transport limitations within the nanoparticles are neglected, and instead the Frumkin isotherm (or regular solution model) is used to describe local chemical equilibrium of cations between the nanoparticles and the adjacent electrolyte, as a function of the electrode potential. Our model describes the dynamics of key parameters of the CDI process with intercalation electrodes, such as effluent salt concentration, the distribution of intercalated ions, cell voltage, and energy consumption.

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“…where, , v res E is the volumetric (resistive) energy consumption at resonant operation, P is the throughput productivity (volume of freshwater produced per unit electrode area, per unit time), and the water recovery is implicitly 50% (see Hawks et al, 2018b for a discussion of these metrics).…”

Section: Discussionmentioning

confidence: 99%

“…Moreover, CDI is inherently periodic 3 because electrical charging and discharging forcing functions result in periodic salt removal and regeneration phases. CDI performance can be evaluated using a recently proposed set of metrics (Hawks et al, 2018b).…”

Section: Introductionmentioning

confidence: 99%

Frequency analysis and resonant operation for efficient capacitive deionization

et al. 2018

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Capacitive deionization (CDI) performance metrics can vary widely with operating methods. Conventional CDI operating methods such as constant current and constant voltage show advantages in either energy or salt removal performance, but not both. We here develop a theory around and experimentally demonstrate a new operation for CDI that uses sinusoidal forcing voltage (or sinusoidal current). We use a dynamic system modeling approach, and quantify the frequency response (amplitude and phase) of CDI effluent concentration. Using a wide range of operating conditions, we demonstrate that CDI can be modeled as a linear time invariant system. We validate this model with experiments, and show that a sinusoid voltage operation can simultaneously achieve high salt removal and strong energy performance, thus very likely making it superior to other conventional operating methods. Based on the underlying coupled phenomena of electrical charge (and ionic) transfer with bulk advection in CDI, we derive and validate experimentally the concept of using sinusoidal voltage forcing functions to achieve resonance-type operation for CDI. Despite the complexities of the system, we find a simple relation for the resonant time scale: the resonant time period (frequency) is proportional (inversely proportional) to the geometric mean of the flow residence time and the electrical (RC) charging time. Operation at resonance implies the optimal balance between absolute amount of salt removed (in moles) and dilution (depending on the feed volume processed), thus resulting in the maximum average concentration reduction for the desalinated water. We further develop our model to generalize the resonant time-scale operation, and provide responses for square and triangular voltage waveforms as two examples. To this end, we develop a general tool that uses Fourier analysis to construct CDI effluent dynamics for arbitrary input waveforms. Using this tool, we show that most of the salt removal (∼95%) for square and triangular voltage forcing waveforms is achieved by the fundamental Fourier (sinusoidal) mode. The frequency of higher Fourier modes precludes high flow efficiency for these modes, so these modes consume additional energy for minimal additional salt removed. This deficiency of higher frequency modes further highlights the advantage of DC-offset sinusoidal forcing for CDI operation.

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Performance metrics for the objective assessment of capacitive deionization systems

Cited by 217 publications

References 73 publications

Rapid Inversion of Surface Charges in Heteroatom‐Doped Porous Carbon: A Route to Robust Electrochemical Desalination

Rapid Inversion of Surface Charges in Heteroatom‐Doped Porous Carbon: A Route to Robust Electrochemical Desalination

Theory of Water Desalination with Intercalation Materials

Frequency analysis and resonant operation for efficient capacitive deionization

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