Proving and interpreting the spontaneous formation of bulk nanobubbles in aqueous organic solvent solutions: effects of solvent type and content

Jadhav, Ananda J.; Barigou, Mostafa

doi:10.1039/d0sm00111b

Cited by 30 publications

(38 citation statements)

References 61 publications

(52 reference statements)

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“…However: (i) they do not provide any concrete evidence for the presence of such hydrophobic impurities in our system; (ii) they do not specify their chemical composition; and (iii) they do not specify at what water−ethanol ratios such hydrophobic impurities are supposed to be detectable. Furthermore, Rak & Sedlak fail to address why in our work: 1,4,29 (iv) the number per mL of nanoentities (we interpret as BNBs) observed varies strongly with the water−ethanol ratio, such that it reaches a maximum at an ethanol volume fraction of about 20% and it falls off to zero at a fraction of about 60%; and (v) why these nanoentities do not disappear when ethanol is evaporated from the suspension in a rotary evaporator. Incidentally, independent relevant work has more recently reported that actual BNB suspensions in water can be concentrated in a rotary evaporator with no loss of BNBs.…”

Section: ■ Materialsmentioning

confidence: 70%

Response to “Comment on Bulk Nanobubbles or Not Nanobubbles: That is the Question”

Jadhav

Barigou

2020

Langmuir

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Advanced techniques that combine high spatial resolution with chemical sensitivity to directly probe the observed nanoentities and provide direct evidence that they are truly gas-filled nanobubbles do not exist. Therefore, in our paper, we focused on providing, for the first time, multiple types of indirect evidence using a variety of physical and chemical techniques that the nanoentities are not due to contamination and, hence, they must be bulk nanobubbles (BNBs). It should be noted that such techniques require good experimental skills, sound protocols, good scientific expertise, and reliable equipment. While no single piece of indirect evidence on its own can be considered as conclusive proof, we estimate that our results combined provide strong evidence that bulk nanobubbles do exist and they are stable. The work presented in our paper is the culmination of a series of studies, and many authors have either directly or indirectly confirmed our findings. Nonetheless, in their Comment, Rak & Sedlak reject all of the work we reported. We here address their comments point by point and show that their criticisms are unwarranted and unfounded, as follows.

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Section: ■ Materialsmentioning

confidence: 70%

Response to “Comment on Bulk Nanobubbles or Not Nanobubbles: That is the Question”

Jadhav

Barigou

2020

Langmuir

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“…22 It was found that NBs could be produced through alcohol−water exchange, which was well characterized by the nanoparticle tracking analysis (NTA), Fourier transform infrared spectroscopy (FTIR), gas chromatography−mass spectrometry (GC−MS), and inductively coupled plasmamass spectrometry (ICP-MS). 27 It was also reported that a procedure containing pressurization−depressurization steps would controllably generate NBs in different solutions, which was confirmed by the X-ray fluorescence intensity of the element of the gas in solutions and by NTA. 30 Although these independent studies provide strong evidence for the existence of NBs, they focus on aqueous solutions as liquid carriers.…”

Section: Introductionmentioning

confidence: 79%

“…They pointed out that there were no ions on the surface of organic molecules, and NBs could not be formed in such a pure organic system . Recent studies carried out by Barigou et al also indicated that NBs were formed during water–organic solvent mixing, but no NBs were detected in pure organic systems . However, it seems that the electrostatic repulsion model does not work for bulk NBs in pure water (without surfactant) as the calculation showed that the repulsive pressure associated with electrostatic force caused by surface charge was one order of magnitude smaller than the Laplace pressure inside the bubble; thus, the electrostatic repulsive pressure could not balance with the Laplace pressure at all. , In 2015, Craig et al observed the formation of surface NBs on highly oriented pyrolitic graphite (HOPG) covered by some pure organic solvents and believed the existence of a three-dimensional hydrogen bond network that promoted the formation of the surface NBs .…”

Section: Introductionmentioning

confidence: 99%

“…Various methods for producing NBs have recently been developed, and evidences of the existence of NBs have been provided in a number of studies. − ,− For instance, NBs were generated via chemical reactions and by ultrasonic irradiation . It was found that NBs could be produced through alcohol–water exchange, which was well characterized by the nanoparticle tracking analysis (NTA), Fourier transform infrared spectroscopy (FTIR), gas chromatography–mass spectrometry (GC–MS), and inductively coupled plasma-mass spectrometry (ICP-MS) . It was also reported that a procedure containing pressurization–depressurization steps would controllably generate NBs in different solutions, which was confirmed by the X-ray fluorescence intensity of the element of the gas in solutions and by NTA .…”

Section: Introductionmentioning

confidence: 99%

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Generating Bulk Nanobubbles in Alcohol Systems

Guo

Tan

et al. 2021

ACS Omega

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Bulk nanobubbles (NBs) have attracted wide attention due to their peculiar physicochemical properties and great potential in applications in various fields. However, so far there are no reports on bulk NBs generated in pure organic systems, which we think is very important as NBs would largely improve the efficiency of gas−liquid mass transfer and facilitate chemical reactions to take place. In this paper, we verified that air and N 2 NBs could be generated in a series of alcohol solutions by using various methods including acoustical cavitation, pressurization−depressurization, and vibration. The experiments proved that NBs existed in alcohol solutions, with a highest density of 5.8 × 10 7 bubble/mL in propanol. Our results also indicated that bulk NBs could stably exist for at least hours in alcohol systems. The parameters in generating NBs in alcohols were optimized. Our findings open up an opportunity for improving gas−liquid mass transfer efficiency in the field of the chemical industry.

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“…of liquids [27] . Due to these changes, when ultrasound is applied to a CXL system, the physics and chemistry of non-linearly oscillating acoustic cavitation bubbles are strongly influenced by the dissolved CO 2 [28] , and gas oversaturation is a crucial parameter in determining the population of bubbles [29] . During the rarefaction of ultrasonication, the local pressure is lower than the saturation pressure of the CO 2 -expanded DMF, resulting in a decrease in the gas solubility of the corresponding local liquid.…”

Section: Resultsmentioning

confidence: 99%

Ultrasonic cavitation in CO2-expanded N, N-dimethylformamide (DMF)

Gao

Pei

Dong

et al. 2021

Ultrasonics Sonochemistry

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Highlights Ultrasonic cavitation is recorded by high-speed camera and hydrophone in a gas-expanded liquid system. Content of CO 2 has an important influence on evolution of bubble cloud. Cavitation intensity depends on ultrasonic power and gas content. The combination of ultrasound and gas-expanded liquid system greatly promotes mass transfer.

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Proving and interpreting the spontaneous formation of bulk nanobubbles in aqueous organic solvent solutions: effects of solvent type and content

Cited by 30 publications

References 61 publications

Response to “Comment on Bulk Nanobubbles or Not Nanobubbles: That is the Question”

Response to “Comment on Bulk Nanobubbles or Not Nanobubbles: That is the Question”

Generating Bulk Nanobubbles in Alcohol Systems

Ultrasonic cavitation in CO2-expanded N, N-dimethylformamide (DMF)

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