The System Lithium Nitrate–ethanol–water and Its Component Binary Systems

Campbell, A. N.; Bailey, R.A.

doi:10.1139/v58-074

Cited by 21 publications

(29 citation statements)

References 9 publications

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Section: Solubility In the Binary System (Lino 3 + H 2 O)supporting

confidence: 47%

“…Also presented in figure 1 are the data from the literature [5,[7][8][9]. Generally, our data are in good agreement with those of Campbell in 1958 [9] and quite different from those reported by Donnan [7] and Campbell in 1942 [8]. The solubility data of Campbell in 1958 [9] are somewhat scattered and obviously higher than our results at temperatures near 273 K. Based on all of their scattered experimental points Campbell et al drew a liquidus line (see figure 4 in [9]), which also shows negative salt concentration deviation from the scattered points at T = 273 K and is in agreement with our data.…”

Section: Solubility In the Binary System (Lino 3 + H 2 O)mentioning

confidence: 99%

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Thermodynamic study of the system (LiCl+LiNO3+H2O)

Zeng¹,

Ming²,

Voigt³

2008

The Journal of Chemical Thermodynamics

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Section: Solubility In the Binary System (Lino 3 + H 2 O)supporting

confidence: 47%

Section: Solubility In the Binary System (Lino 3 + H 2 O)mentioning

confidence: 99%

Thermodynamic study of the system (LiCl+LiNO3+H2O)

Zeng¹,

Ming²,

Voigt³

2008

The Journal of Chemical Thermodynamics

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“…These samples were cooled at a rate of 10 °C/min (or at different cooling rates, as specified in the text). Undercooling was calculated as the difference between the onset of crystallization (as measured by a large deviation in the heat signal from the DSC) and the equilibrium melting temperature of 29.6 °C [4]. These are exacting conditions, and undercooling is expected to be smaller for both slower cooling rates and for larger sample volumes.…”

Section: Methodsmentioning

confidence: 99%

“…Furthermore, it is very difficult for phase segregation to occur at eutectic compositions, as the two (or more) solid phases typically co-solidify in an inseparable fashion, such that the average local composition also remains constant. In the specific case of the lithium nitrate-water system, stoichiometric LiNO 3 -3H 2 O (56.1 wt% LiNO 3 ) melts congruently (29.6 °C), while eutectic melting between LiNO 3 -3H 2 O and LiNO 3 occurs at ~59 wt% LiNO 3 (27.9 °C) [4].…”

Section: Phase Segregation In Salt Hydratesmentioning

confidence: 99%

“…This paper describes the recent development of composite materials based on one candidate salt hydrate system, lithium nitrate trihydrate (LiNO 3 -3H 2 O), at the USAF Research Laboratory. Lithium nitrate trihydrate melts at 29.6 °C, and offers double the volumetric energy densities (~0.4 MJ/m 3 ) and double the thermal conductivities (~0.5-0.6 W/m/K) of comparable melting-point paraffins (Table 1) [3][4][5]. Here, we describe approaches to overcoming limitations associated with lithium nitrate trihydrate, but which are generally applicable to other salt hydrate systems.…”

mentioning

confidence: 99%

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Agile Thermal Management STT-RX. Towards High Energy Density, High Conductivity Thermal Energy Storage Composites (PREPRINT)

Shamberger¹,

Forero²

2011

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The public reporting burden for this collection of information is estimated to average 1 hour per response, including the time for reviewing instructions, searching existing data sources, searching existing data sources, gathering and maintaining the data needed, and completing and reviewing the collection of information. Send comments regarding this burden estimate or any other aspect of this collection of information, including suggestions for reducing this burden, to Department of Defense, Washington Headquarters Services, Directorate for Information SPONSORING/MONITORING AGENCY REPORT NUMBER(S)AFRL-RX-WP-TP-2011-4417 DISTRIBUTION/AVAILABILITY STATEMENTApproved for public release; distribution unlimited. SUPPLEMENTARY NOTESThe U.S. Government is joint author of this work and has the right to use, modify, reproduce, release, perform, display, or disclose the work. PA Case Number and clearance date: 88ABW-2011-5381, 11 Oct 2011. Preprint journal article to be submitted to Proceedings of the ASME 2012 3rd Micro/Nanoscale Heat & Mass Transfer International Conference, March 3-6, 2012, Atlanta, Georgia. This document contains color. © 2011 by ASME ABSTRACTThermal energy storage (TES) materials absorb transient pulses of heat, allowing for rapid storage of low-quality thermal energy for later use, and effective temperature regulation as part of a thermal management system. This paper describes recent development of salt hydrate-based TES composites at the Air Force Research Laboratory. Salt hydrates are known to be susceptible to undercooling and chemical segregation, and their bulk thermal conductivities remain too low for rapid heat transfer. Here, we discuss recent progress towards solving these challenges in the composite system lithium nitrate trihydrate/graphitic foam. This system takes advantage of both the high volumetric thermal energy storage density of lithium nitrate trihydrate and the high thermal conductivity of graphitic foams. We demonstrate a new stable nucleation agent specific to lithium nitrate trihydrate which decreases undercooling by up to ~70% relative to previously described nucleation agents. Furthermore, we demonstrate the compatibility of lithium nitrate trihydrate and graphitic foam with the addition of a commercial nonionic silicone polyether surfactant. Finally, we show that thermal conductivity across water-graphite interfaces is optimized by tuning the surfactant concentration. These advances demonstrate a promising route to synthesizing high energy density, high thermal conductivity TES composites. ABSTRACTThermal energy storage (TES) materials absorb transient pulses of heat, allowing for rapid storage of low-quality thermal energy for later use, and effective temperature regulation as part of a thermal management system. This paper describes recent development of salt hydrate-based TES composites at the Air Force Research Laboratory. Salt hydrates are known to be susceptible to undercooling and chemical segregation, and their bulk thermal conductivities remain too low for rapi...

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A Comprehensive Formulation of Aqueous Electrolytes for Low‐Temperature Supercapacitors

et al. 2023

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Safer-by-design and sustainable energy storage devices are envisioned to be among the required 2.0 solutions to satisfy the fast growing energy demands. Responding to this evolution cannot be freed from a global and synergetic approach to design the requisite electrolytes taking into account the toxicity, the eco-compatibility and the cost of their constituents. To target low-temperature applications, a non-toxic and costefficient eutectic system comprising LiNO 3 in water with 1,3propylene glycol as co-solvent was selected to design a ternary electrolyte with a wide liquid range. By using this electrolyte in an electrochemical double-layer capacitor (EDLC), the operating voltage of the device reaches an optimum of 2.0 V at À 40 °C over more than 100 h of floating. Moreover, after being set up at 20 °C, the temperature resilience of the capacitance is near total, demonstrating thus a promising feature related to the suitable thermal and electrochemical behaviours of the tested EDLC devices.

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The System Lithium Nitrate–ethanol–water and Its Component Binary Systems

Cited by 21 publications

References 9 publications

Thermodynamic study of the system (LiCl+LiNO3+H2O)

Thermodynamic study of the system (LiCl+LiNO3+H2O)

Agile Thermal Management STT-RX. Towards High Energy Density, High Conductivity Thermal Energy Storage Composites (PREPRINT)

A Comprehensive Formulation of Aqueous Electrolytes for Low‐Temperature Supercapacitors

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