Investigation of the Origin of Voltage Generation in Potentized Homeopathic Medicine through Raman Spectroscopy

Bhattacharya, Tara Shankar; Maitra, Payaswini; Bera, Debabrata; Das, Kaushik; Bandyopadhyay, Probir K.; Das, Sukhen; Bhar, D. S.; Singha, Achintya; Nandy, Papiya

doi:10.1055/s-0038-1675821

Cited by 15 publications

(6 citation statements)

References 20 publications

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“…2a, b, O-H stretching vibration of water molecules (3000-3700 cm −1 ) shows an obvious wide peak, which is often convolved into three components. Based on previous reports 40, 41 , the Raman peak gradually blueshifts as the H-bond interaction wanes, so the major peak wavenumbers located at ∼3230, ∼3450, and ∼3620 cm −1 correspond to the water molecules with strong, weak and non H-bonds, respectively. With the addition of ZnCl 2 , the peaks narrow to high frequency, indicating the decrease of strong H-bond proportion in the solution 42 .…”

Section: Lowsupporting

confidence: 59%

Modulating electrolyte structure for ultralow temperature aqueous zinc batteries

et al. 2020

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Rechargeable aqueous batteries are an up-and-coming system for potential large-scale energy storage due to their high safety and low cost. However, the freeze of aqueous electrolyte limits the low-temperature operation of such batteries. Here, we report the breakage of original hydrogen-bond network in ZnCl2 solution by modulating electrolyte structure, and thus suppressing the freeze of water and depressing the solid-liquid transition temperature of the aqueous electrolyte from 0 to –114 °C. This ZnCl2-based low-temperature electrolyte renders polyaniline||Zn batteries available to operate in an ultra-wide temperature range from –90 to +60 °C, which covers the earth surface temperature in record. Such polyaniline||Zn batteries are robust at –70 °C (84.9 mA h g−1) and stable during over 2000 cycles with ~100% capacity retention. This work significantly provides an effective strategy to propel low-temperature aqueous batteries via tuning the electrolyte structure and widens the application range of temperature adaptation of aqueous batteries.

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Section: Lowsupporting

confidence: 59%

Modulating electrolyte structure for ultralow temperature aqueous zinc batteries

et al. 2020

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“…The O–H stretching vibration of H 2 O at 2500–4000 cm –1 is shown in Fig. 2 c. Based on previous reports, the stretching vibration can be deconvoluted into three components at 3230.2, 3417.9 and 3552.7 cm –1 , which represent the intermolecular interactions of H 2 O via strong H 2 O–H 2 O HBs, medium H 2 O–H 2 O HBs and the H 2 O bound to the HB acceptor, respectively [ 34 , 35 ]. As the content of DMF increased, the ratio of water in different H-bound states was calculated from the area of the fitted peaks.…”

Section: Resultsmentioning

confidence: 94%

N,N-dimethylformamide tailors solvent effect to boost Zn anode reversibility in aqueous electrolyte

Zhang

Liu

et al. 2022

National Science Review

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Rechargeable aqueous Zn batteries are considered as promising energy storage devices because of their high capacity, environmental friendliness, and low cost. However, the hydrogen evolution reaction (HER) and growth of dendritic Zn in common aqueous electrolytes severely restrict the application of Zn batteries. Here, we develop a simple strategy to suppress side reactions and boost the reversibility of the Zn electrode. By introducing 30% (volume fractions) N, N–dimethylformamide (DMF) to the 2 M Zn(CF3SO3)2–H2O electrolyte (ZHD30), the preferential hydrogen bonding effect between DMF and H2O effectively reduces the water activity and hinders deprotonation of the electrolyte. The ZHD30 electrolyte improves the Zn plating/stripping coulombic efficiency from ∼95.3% to ∼99.4% and enhances the cycles from 65 to 300. The Zn–polyaniline full battery employing the ZHD30 electrolyte can operate over a wide temperature range from –40°C to + 25°C and deliver capacities of 161.6, 127.4, and 65.8 mAh g–1 at 25, –20, and –40°C, respectively. This work provides insights into the role of tuning solvent effects in designing low-cost and effective aqueous electrolytes.

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“…As shown in Figure 3d, the O─H stretching vibration of water (3000∼3700 cm −1 ) gradually blueshifts with increasing ZnCl 2 concentration, indicating the weakening of hydrogen bonding interactions among water molecules. [55][56][57] The water ratios with different hydrogen bonding states, including strong, weak and non-hydrogen bonds, were calculated from the fitted peak areas (Figure 3e). Obviously, when the ZnCl 2 concentration rises from 0 m to 15m, the strong hydrogen bonds decrease but the nonhydrogen bonds increase.…”

Section: Investigating Anti-freezing Properties Of Hydrogel Electroly...mentioning

confidence: 99%

In Situ Polymerization of Hydrogel Electrolyte on Electrodes Enabling the Flexible All‐Hydrogel Supercapacitors with Low‐Temperature Adaptability

Zhang,

Sun,

Nan

et al. 2024

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All‐hydrogel supercapacitors are emerging as promising power sources for next‐generation wearable electronics due to their intrinsic mechanical flexibility, eco‐friendliness, and enhanced safety. However, the insufficient interfacial adhesion between the electrode and electrolyte and the frozen hydrogel matrices at subzero temperatures largely limit the practical applications of all‐hydrogel supercapacitors. Here, an all‐hydrogel supercapacitor is reported with robust interfacial contact and anti‐freezing property, fabricated by in situ polymerizing hydrogel electrolyte onto hydrogel electrodes. The robust interfacial adhesion is developed by the synergistic effect of a tough hydrogel matrix and topological entanglements. Meanwhile, the incorporation of zinc chloride (ZnCl2) in the hydrogel electrolyte prevents the freezing of water solvents and endows the all‐hydrogel supercapacitor with mechanical flexibility and fatigue resistance across a wide temperature range of 20 °C to –60 °C. Such all‐hydrogel supercapacitor demonstrates satisfactory low‐temperature electrochemical performance, delivering a high energy density of 11 mWh cm−2 and excellent cycling stability with a capacitance retention of 90% over 10000 cycles at −40 °C. Notably, the fabricated all‐hydrogel supercapacitor can endure dynamic deformations and operate well under 2000 tension cycles even at −40 °C, without experiencing delamination and electrochemical failure. This work offers a promising strategy for flexible energy storage devices with low‐temperature adaptability.

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Investigation of the Origin of Voltage Generation in Potentized Homeopathic Medicine through Raman Spectroscopy

Cited by 15 publications

References 20 publications

Modulating electrolyte structure for ultralow temperature aqueous zinc batteries

Modulating electrolyte structure for ultralow temperature aqueous zinc batteries

N,N-dimethylformamide tailors solvent effect to boost Zn anode reversibility in aqueous electrolyte

In Situ Polymerization of Hydrogel Electrolyte on Electrodes Enabling the Flexible All‐Hydrogel Supercapacitors with Low‐Temperature Adaptability

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