Innovative lithium recovery technique from seawater by using world-first dialysis with a lithium ionic superconductor

Hoshino, Tsuyoshi

doi:10.1016/j.desal.2014.12.018

Cited by 143 publications

(53 citation statements)

References 12 publications

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“…66,67 Further, Hoshino developed a Li permeable membrane as a Li ionic superconductor through which Li passes but not the other cations in seawater. 68 More research needs to be conducted to test this membrane in recovering Li salts from seawater or seawater brine.…”

Section: Recent Enhancementsmentioning

confidence: 99%

Mining valuable minerals from seawater: a critical review

Loganathan

Naidu

Vigneswaran

2017

Environ. Sci.: Water Res. Technol.

180

116

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Section: Recent Enhancementsmentioning

confidence: 99%

Mining valuable minerals from seawater: a critical review

Loganathan

Naidu

Vigneswaran

2017

Environ. Sci.: Water Res. Technol.

180

116

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“…World reserves of Li are sufficient for many thousand years of operation of D-T fusion power plants. Studies are underway to also extract it from seawater [29]. If at a later stage the D-D reaction could be used (requiring, however, even much higher plasma temperatures), we could have at our disposal a virtually unlimited energy source, as reserves of D are sufficient for several million years of energy production.…”

Section: -Will Fusion Be a Safe Clean And Inexhaustible Energy Source?mentioning

confidence: 99%

Fusion: a true challenge for an enormous reward

Ongena

2018

EPJ Web Conf.

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Nuclear physics shows that energy can be released from both fission of heavy nuclei and fusion of light nuclei. Steady progress shows that fusion — an important additional option for energy production in the future — promises to be a clean and safe solution for mankind’s long-term energy needs with minimal environmental impact. A source of energy which would be inexhaustible, inherently safe and environmentally friendly, is this not a marvellous prospect? Nuclear fusion, a possible candidate for this role, has been the energy source of our Sun and the stars in the universe for billions of years. This process requires temperatures of tens of millions of degrees, so extremely high and foreign to our daily experience that it seems out of reach. Nevertheless, these extremely high temperatures are routinely realised in several laboratories all over the world, and since the early 1990s, tens of MW fusion power have been released from fusion reactions. We are witnessing the birth of a new technology destined to meet the gigantic future energy needs of mankind with minimal impact on the environment.

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“…At 1.0 V, peaks corresponding to Cu 2 O and Li 2 O phases begin to appear, [30] apart from the Cu 4 O 3 peak which shows that conversion reaction has taken place. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 Two more peaks below 33 degree is attributed to the formation of Li 2 O 2 which is typically observed along with Li 2 O in CuO lithiation process [19] and Li 2 CO 3 [31] possibly from the SEI layer of the electrode. Also, the Cu peaks start becoming more intense at 1.0 V (at around a 2q value of 43.6 degrees) and it may be noted that this peak showed negligible intensity even in the bare Cu-foil.…”

Section: Ex Situ Xrd Analysismentioning

confidence: 99%

Reversible Cu₄O₃ Phase Formation in CuO Nanoplate Anodes for High Capacity and High Coulombic Efficiency

et al. 2017

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Conversion materials with high specific capacity are of interest to improve energy density of Li‐ion batteries. Here, we present results concerning hydrothermally synthesized CuO nanoplates that exhibit high specific capacity of 800 and 698 mAh/g at C/2 and 1C rates respectively and 180 mAh/g at a high rate of 30C. The electrodes exhibit high Coulombic efficiencies of about 66% and 60% at C/2 and 1C rate respectively, these are high efficiency values compared to the ones reported in the literature at respective rates. To understand the high performance, ex situ x‐ray diffraction at different states of first discharge/charge is utilized that shine light on the lithiation/delithiation pathways of the CuO nanoplates. Lithiation proceeds through multiple phase transition CuO → Cu4O3 → Cu2O → Cu and it was found that Cu4O3 is reversible at the end of first charge. Cu and residual Cu2O was observed at the end of lithiation along with Li2O and Li2O2 phases. At the end of first charge, Cu4O3 phase along with CuO was observed as a major end‐product with relatively minor concentrations of Cu2O. Cu4O3 as a major constituent observed in composite electrode seems to be the key information that can explain good reversibility and high Coulombic efficiency reported in the present work.

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Innovative lithium recovery technique from seawater by using world-first dialysis with a lithium ionic superconductor

Cited by 143 publications

References 12 publications

Mining valuable minerals from seawater: a critical review

Mining valuable minerals from seawater: a critical review

Fusion: a true challenge for an enormous reward

Reversible Cu₄O₃ Phase Formation in CuO Nanoplate Anodes for High Capacity and High Coulombic Efficiency

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Innovative lithium recovery technique from seawater by using world-first dialysis with a lithium ionic superconductor

Cited by 143 publications

References 12 publications

Mining valuable minerals from seawater: a critical review

Mining valuable minerals from seawater: a critical review

Fusion: a true challenge for an enormous reward

Reversible Cu4O3 Phase Formation in CuO Nanoplate Anodes for High Capacity and High Coulombic Efficiency

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Product

Resources

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Reversible Cu₄O₃ Phase Formation in CuO Nanoplate Anodes for High Capacity and High Coulombic Efficiency