CN101059490A - Ion liquid type humidity sensor - Google Patents

Ion liquid type humidity sensor Download PDF

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CN101059490A
CN101059490A CN 200710041406 CN200710041406A CN101059490A CN 101059490 A CN101059490 A CN 101059490A CN 200710041406 CN200710041406 CN 200710041406 CN 200710041406 A CN200710041406 A CN 200710041406A CN 101059490 A CN101059490 A CN 101059490A
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electrode
ion liquid
ionic liquid
humidity sensor
room temperature
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王荣
朱国阳
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Shanghai Normal University
University of Shanghai for Science and Technology
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Shanghai Normal University
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Abstract

The invention relates to a humidity sensitive element and a relative preparation based on room temperature ion liquid, in particular to a humidity sensitive element composed of a room temperature ion liquid, an ion liquid carrier and at least two electrodes. The invention is characterized in that the room temperature ion liquid is used as humidity sensitive component, the cooperation between water molecule and the room temperature ion liquid material can affect the properties of ion liquid as conductivity and viscosity or the like, to realize humidity detect. The inventive humidity sensitive element has simple structure, low cost, better exchangeability, stable property and high sensitivity or the like.

Description

A kind of ion liquid type humidity sensor
Technical field
The invention belongs to technical field of electrochemistry, particularly relating to a kind of is the electronic devices and components and preparation method thereof of humidity-sensitive material with the ionic liquid.
Background technology
Humidity is not only in commercial production, quality management, and environment control aspect plays an important role, and is and the closely-related physical quantity of we human lives.In the moisture measurement field, humidity-sensitive material carries out the measurement of humidity to the adsorptive power of hydrone or to the method for hydrone generation physical influence often to use humidity-sensitive element to utilize wherein.According to the difference of the humidity-sensitive material that uses, humidity-sensitive element comprises electrolyte humidity sensor, high-molecular organic material humidity-sensitive element (CN1423123A), metal oxide film humidity-sensitive element (CN2168250Y) and metal oxide ceramic humidity-sensitive element (CN1571184A) etc.Chen has summarized employed humidity-sensitive material of various humidity-sensitive elements and sensor mechanism at " sensor letters " 2005 on the 3:274-295.Different humidity-sensitive elements is because its different Response Mechanism and response characteristic often have different humidity response and usable range.At present, employed various humidity-sensitive materials are generally heterogeneous material in humidity-sensitive element, and material depends on accurate control to the material synthesis condition to a great extent to the response sensitivity of ambient humidity.Therefore, the control of the interchangeability between humidity-sensitive element is still relatively more difficult.
Ionic liquid at room temperature is meant the material that is in a liquid state and is made of ion under near temperature room temperature or the room temperature, be another class green solvent system behind water and supercritical carbon dioxide.In twentieth century nineties, the ionic liquid stable to water and air synthesized to come out successively.These ionic liquids are mostly by being made up of with fluo anion respectively organic cations such as alkyl pyridine kation, alkyl imidazole kation, quaternary ammonium alkyl salt cation and alkyl quaternary microcosmic salts.Because they have good physicochemical characteristicss such as low-steam pressure, high ionic conductivity, Heat stability is good, electrochemical window be wide and all are with a wide range of applications in fields such as galvanochemistry, chemosynthesis, detachment process, catalysis.The water wettability ionic liquid at room temperature can with water immiscible phase, even hydrophobic ionic liquid also can have a spot of water-soluble separating therein.After water is dissolved in ionic liquid, can exert an influence to physicochemical properties such as ion liquid viscosity, electric conductivity, in addition, the liquid water content in the ionic liquid also can make the coefficient of diffusion that is dissolved in the solute in the ionic liquid change.Having not yet to see any humidity-sensitive element, is to utilize liquid water content that ionic liquid character is changed, and is that humidity-sensitive material is realized hygrometric report with the ionic liquid at room temperature.
Summary of the invention
Technical matters to be solved
Technical matters to be solved by this invention provides a kind of ionic liquid humidity-sensitive element, and existing humidity-sensitive element sensor interchangeability is poor to overcome, unstable properties, the low defective of sensitivity.
Technical scheme
One of technical scheme of the present invention provides a kind of ion liquid type humidity sensor, is made up of ionic liquid at room temperature, ionic liquid carrier and at least two electrodes.
One of preferred version of above-mentioned ion liquid type humidity sensor is that described ionic liquid at room temperature is selected from one or more in alkyl imidazole, alkyl pyridine class, quaternary ammonium salt, quaternary phosphonium salt or the benzimidazole ionic liquid.The scheme that is more preferably is that 1-ethyl-3 methylimidazole is cut in described ionic liquid at room temperature choosing] [tetrafluoro boric acid], [1-butyl-3 methylimidazole] [hexafluorophosphoric acid], [1-Kui Ji-3-methyl] [tetrafluoro boric acid], [N-butyl-pyridinium] [hexafluorophosphoric acid], [N-butyl-pyridinium] [tetrafluoro boric acid], [N-heptyl pyridine] [hexafluorophosphoric acid], [dimethyl ethanol base 3-sulfonic acid propyl ammonium] [p-methyl benzenesulfonic acid], [three ethanol based 3-sulfonic acid propyl ammoniums] [p-toluenesulfonic acid], [diethyl alcohol radical sulfonic acid butyl ammonium] [hydrogen sulfate], [tetrabutyl phosphorus] [two-(trifluoromethyl) sulfimides], [tributyl-methyl phosphonium phosphorus] [methane-sulforic acid], [tributyl myristyl phosphorus] [two-(trifluoromethyl) sulfimides], [1-ethyl-3-butyl benzimidazole] [tetrafluoro boric acid], [1-ethyl-3-butyl benzimidazole] [[hexafluorophosphoric acid], in [1-ethyl-3-butyl benzimidazole] [p-methyl benzenesulfonic acid] 1-ethyl-3 methyl imidazolium tetrafluoroborate one or more.
Two of the preferred version of above-mentioned ion liquid type humidity sensor is, but described ionic liquid carrier is ion liquid container immobilized ionic liquid film or gel, adsorbable ion liquid cotton-shaped carrier or semiconductor substrate.
Three of the preferred version of above-mentioned ion liquid type humidity sensor is that described electrode is metal electrode or nonmetal electrode.Further preferred, described nonmetal electrode is carbon electrode or silicon electrode.
Four of the preferred version of above-mentioned ion liquid type humidity sensor is, when described electrode was three, three electrodes were respectively working electrode, contrast electrode and to electrode.
Five of the preferred version of above-mentioned ion liquid type humidity sensor is, when described electrode is two, and one of them double as contrast electrode and to electrode.
Two of technical scheme of the present invention provides a kind of preparation method of ion liquid type humidity sensor, and its step comprises: the preparation room temperature ionic liquid; With ionic liquid at room temperature, ionic liquid carrier and at least two combination of electrodes are become humidity-sensitive element.
The preparation method's of above-mentioned ion liquid type humidity sensor preferred version is that described ionic liquid at room temperature is selected from one or more in alkyl imidazole, alkyl pyridine class, quaternary ammonium salt, quaternary phosphonium salt or the benzimidazole ionic liquid.
Used herein, " interchangeability " is meant: the humidity-sensitive element of batch making is to humidity response basically identical, and element can be exchanged easily mutually like this, avoids humidity-sensitive element is done to demarcate one by one.
Beneficial effect
The present invention is a kind of novel ion liquid type humidity sensor.Its topmost characteristics are: with ionic liquid at room temperature as the humidity sensitive composition.As the homogeneous phase sensitive material with definite molecular structure, the use ionic liquid at room temperature can improve the interchangeability between humidity-sensitive element effectively, and this performance has significant advantage to batch process.
Wherein selected ionic liquid at room temperature can be ionic liquid at room temperature such as various common alkyl imidazoles, alkyl pyridine class, quaternary ammonium salt, quaternary phosphonium salt, benzimidazole, the perhaps derivant of these ionic liquid kinds.Also can adopt the combination of the above ionic liquid at room temperature of two kinds or both, prepare described humidity-sensitive element, have the advantage that raw material is inexpensive, the sensitive material molecular structure is determined.
Ionic liquid can be fixed in the element simply, includes but not limited to ionic liquid solution is adsorbed in the porous polyethylene film, realizes the immobilization of ionic liquid at room temperature.Variation because of humidity in the air, make the water yield that is dissolved in the ionic liquid change, and cause physicochemical properties such as ion liquid viscosity, electric conductivity to change, changed the coefficient of diffusion of electroactive material and the electric double layer capacitance of electrode, thereby made the current signal that records become good linear relationship with relative humidity.This humidity-sensitive element has highly sensitive, and the range of linearity is wide, be not subjected to that oxygen content influences in the air, working temperature is wide, good stability, and is easy to make, advantage such as cost is low.
Description of drawings
Fig. 1 is the ion liquid type humidity sensor synoptic diagram.M: immobilized room temperature ionic liquid film; GC: contrast electrode; Ag: silver electrode; Pt: platinum electrode.
Fig. 2 is an ion liquid type humidity sensor work system synoptic diagram.1: gas bomb; 2: the Drexel bottle that distilled water is housed; 3: gas mixer; 4: humidity-sensitive element; 5: air chamber; 6: current return; 7: electrochemical workstation; 8: computing machine.
Fig. 3 is the cyclic voltammetric response of TCNQ in ionic liquid under dry (a) and water saturation (b) condition in nitrogen (solid line) and oxygen (dotted line) atmosphere.
Fig. 4 be humidity-sensitive element under nitrogen atmosphere, the cyclic voltammogram during different relative humidity.From a to f, relative humidity is respectively: 0%, 20%, 40%, 60%, 80%, 100%.
The reduction peak current that Fig. 5 is a humidity-sensitive element in the cyclic voltammetric response and the graph of a relation of relative humidity.
Fig. 6 be humidity-sensitive element in continuous 8 dryings and water saturated atmosphere transfer process, the stable circulation voltammogram under water saturated atmosphere.
Fig. 7 be humidity-sensitive element in continuous 8 dryings and water saturated atmosphere transfer process, the stable circulation voltammogram under dry atmosphere.
Fig. 8 be humidity-sensitive element in nitrogen atmosphere, the differentiated pulse voltammogram under the different relative humidity.From a to f, relative humidity is respectively: 0%, 20%, 40%, 60%, 80%, 100%.
Fig. 9 be humidity-sensitive element in nitrogen atmosphere, oxidation and the difference of reduction current and the graph of a relation of relative humidity in the differentiated pulse response.
Figure 10 be humidity-sensitive element in oxygen atmosphere, the differentiated pulse voltammogram during different relative humidity.From a to f, relative humidity is respectively: 0%, 20%, 40%, 60%, 80%, 100%.
Figure 11 be humidity-sensitive element under oxygen atmosphere, the oxidation in the differentiated pulse response and the difference of reduction current are mapped to relative humidity content.
Continuous 10 circle differentiated pulse voltammograms when Figure 12 converts water saturated atmosphere for humidity-sensitive element to by dry atmosphere.
Continuous 10 circle differentiated pulse voltammograms when Figure 13 converts dry atmosphere for humidity-sensitive element to by water saturated atmosphere.
Figure 14 be humidity-sensitive element in continuous 8 dryings and water saturated atmosphere transfer process, the stable differentiated pulse voltammogram under water saturated atmosphere.
Figure 15 be humidity-sensitive element in continuous 8 dryings and water saturated atmosphere transfer process, the stable differentiated pulse voltammogram under dry atmosphere.
Figure 16 is in the humidity-sensitive element nitrogen atmosphere, the square wave voltammogram under the different relative humidity.From a to f, relative humidity is respectively: 0%, 20%, 40%, 60%, 80%, 100%.
Figure 17 be humidity-sensitive element under nitrogen atmosphere, the graph of a relation of the difference of oxidation and reduction current and relative humidity in the square wave voltammogram.
Figure 18 be humidity-sensitive element in continuous 8 dryings and water saturated atmosphere transfer process, the stable square wave voltammogram under water saturated atmosphere.
Figure 19 be humidity-sensitive element in continuous 8 dryings and water saturated atmosphere transfer process, the stable square wave voltammogram under dry atmosphere.
Figure 20 is the multi-form synoptic diagram of humidity sensor element.1: the immobilized room temperature ionic liquid film; 2 electrodes; 3 silicon chips.
Embodiment
Below in conjunction with specific embodiment, further set forth the present invention.Should be understood that these embodiment only to be used to the present invention is described and be not used in and limit the scope of the invention.Should be understood that in addition those skilled in the art can make various changes or modifications the present invention after the content of having read the present invention's instruction, these equivalent form of values fall within the application's appended claims institute restricted portion equally.
The experimental technique of unreceipted actual conditions in the following example, usually according to normal condition, as operation manual, or the condition of advising according to manufacturer.The part preparation process of room temperature ionic liquid is according to Chinese patent application 200610025808.0 " a kind of double-functional group ionic liquid and preparation method ".
Embodiment 1
The preparation of 1-ethyl-3-methylimidazole bromine salt
Under room temperature, the stirring condition, the bromoethane (0.126mol) of 9.1ml slowly is added drop-wise in the N-methylimidazole of 10ml, behind the 24h, after ethyl acetate washing 3 times, filters vacuum drying.Reaction equation:
Embodiment 2
[1-ethyl-3-methylimidazole] [tetrafluoride boric acid] ion liquid preparation
Under room temperature, the quick stirring condition, with HBF 4Acid (15.2cm 30.116mol) add Ag slowly 2(13.49g 0.058molAg in the O mud 2O dissolves in 50cm 3In the water), stir fast.The container of reaction encases with aluminium foil, prevents that light from falling.Stir 1h again, until Ag 2The O complete reaction obtains colourless solution.Resulting 1-ethyl-3-methylimidazole inner salt adds wherein among the embodiment 1 with 22.24g0.116mol, stirs 2h under the room temperature, filters, and separates.Under 70 ℃, vacuum drying, product is a white liquid.Reaction equation is:
Figure A20071004140600102
Embodiment 3
The preparation of 1-butyl-3-methylimidazole bromine salt
Under room temperature, the stirring condition, the positive n-butyl bromide of 6.46ml (0.06mol) is slowly splashed in the N-methylimidazole of 4.76ml, behind the 24h, with ethyl acetate washing 3 times.Filter vacuum drying.Reaction equation is:
Embodiment 4
[1-butyl-3 methylimidazole] [hexafluorophosphoric acid] ion liquid preparation
The ice bath lower magnetic force stirs, with KPF 6Slowly add in equimolar 1-butyl-3-methylimidazole bromine brine solution, again with ultrapure water 20ml washing 5 times, vacuum drying.Reaction equation is:
Figure A20071004140600112
Embodiment 5
The preparation of 1-Kui Ji-3-methylimidazole bromine salt
Under room temperature, the stirring condition, the positive Kui n-butyl bromide of 1.32g (0.06mol) is slowly splashed in the N-methylimidazole of 4.76ml, behind the 24h, take off a layer solution, with ethyl acetate washing 3 times, again with ultrapure water 20ml washing 5 times, vacuum drying.Reaction equation is:
Figure A20071004140600121
Embodiment 6
[1-Kui Ji-3-methylimidazole] [tetrafluoro boric acid] ion liquid preparation
The ice bath lower magnetic force stirs, with NaBF 4Slowly add in equimolar 1-Kui Ji-3-methylimidazole bromine brine solution, after 12 hours, again with ultrapure water 20ml washing 5 times, vacuum drying.Reaction equation is:
Figure A20071004140600122
Embodiment 7
The preparation of N-butyl-pyridinium bromine salt
The room temperature lower magnetic force stirs, and positive n-butyl bromide slowly is added drop-wise in the equimolar pyridine solution, after 24 hours, with ethyl acetate washing 3 times, vacuum drying.Reaction equation is:
Figure A20071004140600123
Embodiment 8
[N-butyl-pyridinium] [tetrafluoro boric acid] ion liquid preparation
The ice bath lower magnetic force stirs, with NaBF 4Slowly add in the aqueous solution of equimolar N-butyl-pyridinium bromine salt, after 12 hours, use dichloromethane extraction,, revolve and steam evaporation final vacuum drying again with ultrapure water 20ml washing 5 times.Reaction equation is:
Figure A20071004140600131
Embodiment 9
[N-butyl-pyridinium] [hexafluorophosphoric acid] ion liquid preparation
The ice bath lower magnetic force stirs, with KPF 6Slowly add in the aqueous solution of equimolar N-butyl-pyridinium bromine salt, after 12 hours, take off a layer solution,, revolve and steam evaporation final vacuum drying at every turn with ultrapure water 20ml extraction 5 times.Reaction equation is:
Figure A20071004140600132
Embodiment 10
The preparation of N-heptyl pyridinium tribromide salt
The room temperature lower magnetic force stirs, and positive bromine butane in heptan slowly is added drop-wise in the equimolar pyridine solution, after 24 hours, with ethyl acetate washing 3 times, vacuum drying.Reaction equation is:
Figure A20071004140600133
Embodiment 11
[N-heptyl pyridine] [hexafluorophosphoric acid] ion liquid preparation
The ice bath lower magnetic force stirs, with KBF 6Slowly add in the aqueous solution of equimolar N-butyl-pyridinium bromine salt, after 12 hours, get organic phase, again with ultrapure water 20ml washing 5 times, vacuum drying.Reaction equation is:
Figure A20071004140600141
Embodiment 12
The preparation of sulfonic acid propyl group ethanol based Dimethyl Ammonium inner salt
Under ice bath, the stirring condition, with 8.8mL 1,3-propane sultone (0.1mol) slowly is added drop-wise to and contains 10.1mL N, in the 30mL acetone mixed solution of N-dimethylethanolamine (0.1mol), promptly the mol ratio of reaction raw materials is 1: 1, and very fast adularescent solid is separated out, after 1 hour, white solid with acetone, ether washing 3 times, is filtered 50 ℃ of following vacuum drying.Reaction equation is:
Figure A20071004140600142
Embodiment 13
[sulfonic acid propyl group ethanol based Dimethyl Ammonium] [p-methyl benzenesulfonic acid] ion liquid preparation
Under ice bath, the stirring condition,, after 3 hours, be heated to 70 ℃ to all becoming liquid, cooling final vacuum drying with the dimethyl ethanol base 3-sulfonic acid propyl ammonium inner salt and 1.81g p-toluenesulfonic acid (0.01mol) mixing of 1.95g (0.01mol) embodiment 12 gained.Product is a colourless transparent liquid, and reaction equation is:
Embodiment 14
[sulfonic acid propyl group ethanol based Dimethyl Ammonium] [trifluoromethane sulfonic acid] ion liquid preparation
N 2Under atmosphere, ice bath, the electronic stirring condition, the trifluoromethanesulfonic acid (0.02mol) of 1.80mL slowly is added drop-wise in the dimethyl ethanol base 3-sulfonic acid propyl ammonium inner salt of 4.23g (0.02mol) embodiment 12 gained, after 12 hours, be heated to 50 ℃ to all becoming liquid, cooling final vacuum drying.Product is a light yellow transparent liquid, and reaction equation is:
Figure A20071004140600152
Embodiment 15
[sulfonic acid propyl group ethanol based Dimethyl Ammonium] [hydrogen sulfate] ion liquid preparation
Under ice bath, the stirring condition, the concentrated sulphuric acid (0.014mol) of 0.8mL slowly is added drop-wise in the dimethyl ethanol base 3-sulfonic acid propyl ammonium inner salt (0.014mol) of resultant embodiment 12 gained of 3.04g, be heated to 85 ℃ after 3 hours, all become liquid after 10 hours, cooling final vacuum drying.Product is a light yellow transparent liquid, and reaction equation is:
Figure A20071004140600161
Embodiment 16
The preparation of three ethanol based sulfonic acid propyl ammonium inner salts
Under ice bath, the stirring condition, with 13.2mL1,3-propane sultone (0.15mol) slowly is added drop-wise in toluene (30mL) mixed solution that contains 25.5mL triethanolamine (0.15mol), after 1 day, the adularescent solid generates, after usefulness toluene, ether wash 3 times, filter 50 ℃ of vacuum drying.Reaction equation is:
Figure A20071004140600162
Embodiment 17
[sulfonic acid propyl group three ethanol based ammoniums] [p-toluenesulfonic acid] ion liquid preparation
Under ice bath, the stirring condition, will mix, after 3 hours, be heated to 70 ℃ to all becoming liquid, cooling final vacuum drying by embodiment 16 resulting three ethanol based 3-sulfonic acid propyl ammonium inner salt 7.76g (0.028mol) and 5.16g p-toluenesulfonic acid (0.028mol).Product is a colourless transparent liquid, and reaction equation is:
Figure A20071004140600171
Embodiment 18
[sulfonic acid propyl group three ethanol based ammoniums] [trifluoromethane sulfonic acid] ion liquid preparation
N 2Under atmosphere, ice bath, the stirring condition, the trifluoromethanesulfonic acid (0.029mol) of 2.6mL slowly is added drop-wise to by in embodiment 16 resulting 7.8g (0.029mol) the three ethanol based 3-sulfonic acid propyl ammonium inner salts, after 12 hours, be heated to 50 ℃ to all becoming liquid, cooling final vacuum drying.Product is a light yellow transparent liquid, and reaction equation is:
Figure A20071004140600172
Embodiment 19
[sulfonic acid propyl group three ethanol based ammoniums] [pyrovinic acid] ion liquid preparation
Under ice bath, the stirring condition, the Loprazolam (0.03mol) of 2.0mL slowly is added drop-wise to 8.60g (0.03mol) by in the embodiment 16 resulting three ethanol based 3-sulfonic acid propyl ammonium inner salts, after 3 hours, be heated to 70 ℃ to all becoming liquid, cooling final vacuum drying.Product is a colourless transparent liquid, and reaction equation is:
Figure A20071004140600181
Embodiment 20
The preparation of diethyl alcohol radical sulfonic acid butyl ammonium inner salt
Under room temperature, the stirring condition, the diethanolamine (0.1mol) of 9.6mL is scattered in the 20mL toluene solution, slowly drip 1 of 10.23mL again, behind the 4-sultones (0.1mol), be heated to 50 ℃, the adularescent solid generates after 15 hours, and white solid is washed 3 times with ethanol, filter 50 ℃ of following vacuum drying.Reaction equation is:
Figure A20071004140600182
Embodiment 21
[diethyl alcohol radical sulfonic acid butyl ammonium] [hydrogen sulfate] ion liquid preparation
Under ice bath, the stirring condition, the concentrated sulphuric acid (0.012mol) of 0.65mL slowly is added drop-wise in the diethyl alcohol radical sulfonic acid butyl ammonium inner salt (0.012mol) that resulting 2.81g obtains by embodiment 20, be heated to 70 ℃ after 3 hours, all become liquid after 6 hours, cooling final vacuum drying.Product is a colourless transparent liquid, and reaction equation is:
Embodiment 22
The preparation of bromination tributyl myristyl microcosmic salt
The room temperature lower magnetic force stirs, and positive bromo-tetradecane slowly is added drop-wise in the equimolar tributyl phosphorus solution, after 24 hours, with ethyl acetate washing 3 times, vacuum drying.Reaction equation is:
Figure A20071004140600191
Embodiment 23
The ion liquid preparation of [myristyl tributyl phosphorus] [two-(trifluoromethyl) sulfimides]
The ice bath lower magnetic force stirs, and two-(trifluoromethyl) sulfimide lithiums are slowly added in the aqueous solution of equimolar bromination tributyl myristyl microcosmic salt, after 12 hours, takes off a layer solution, at every turn with ultrapure water 20ml extraction 5 times, revolves and steams evaporation final vacuum drying.
Figure A20071004140600192
Embodiment 24
The preparation of tributyl-methyl phosphonium iodide microcosmic salt
The room temperature lower magnetic force stirs, and iodomethane slowly is added drop-wise in the equimolar tributyl phosphorus solution, after 24 hours, with ethyl acetate washing 3 times, vacuum drying.Reaction equation is:
Figure A20071004140600193
Embodiment 25
The ion liquid preparation of [tributyl-methyl phosphonium phosphorus] [two-(trifluoromethyl) sulfimides]
The ice bath lower magnetic force stirs, and two-(trifluoromethyl) sulfimide lithiums are slowly added in the aqueous solution of equimolar tributyl-methyl phosphonium iodide microcosmic salt, after 12 hours, takes off a layer solution, with ultrapure water 20ml washing 5 times, vacuum drying.
Embodiment 26
The preparation of bromination tetrabutyl microcosmic salt
The room temperature lower magnetic force stirs, and positive n-butyl bromide slowly is added drop-wise in the equimolar tributyl phosphorus solution, after 24 hours, with ethyl acetate washing 3 times, vacuum drying.Reaction equation is:
(CH 3CH 2CH 2CH 2) 3P+CH 3(CH 2) 13Br→(CH 3CH 2CH 2CH 2) 4P +Br -
Embodiment 27
The ion liquid preparation of [tetrabutyl phosphorus] [two-(trifluoromethyl) sulfimides]
The ice bath lower magnetic force stirs, and two-(trifluoromethyl) sulfimide lithiums are slowly added in the aqueous solution of equimolar bromination tetrabutyl microcosmic salt, after 12 hours, takes off a layer solution, at every turn with ultrapure water 20ml extraction 5 times, vacuum drying.
(CH 3CH 2CH 2CH 2) 4P +Br -+Li(CF 3SO 2) 2N→(CH 3CH 2CH 2CH 2) 4P +(CF 3SO 2) 2N -
Embodiment 28
The preparation of bromination 1-butyl-3-ethyl benzo imidazole salt
The room temperature lower magnetic force stirs, and positive n-butyl bromide slowly is added drop-wise in the equimolar 1-ethyl benzo imidazole solution, after 24 hours, with ethyl acetate washing 3 times, vacuum drying.Reaction equation is:
Figure A20071004140600211
Embodiment 29
[1-butyl-3-ethyl benzo imidazole] [hexafluorophosphoric acid] ion liquid preparation
The ice bath lower magnetic force stirs, with KPF 6Slowly add in the aqueous solution of equimolar bromination 1-ethyl-3-butyl benzene benzimidazole salt, after 12 hours, get organic phase, at every turn with ultrapure water 20ml washing extraction 5 times, vacuum drying.
Figure A20071004140600212
Embodiment 30
[1-butyl-3-ethyl benzo imidazole] [tetrafluoro phosphoric acid] ion liquid preparation
The ice bath lower magnetic force stirs, with NaBF 4Slowly add in the aqueous solution of equimolar bromination 1-ethyl-3-butyl benzene benzimidazole salt, after 12 hours, get organic phase, at every turn with ultrapure water 20ml washing extraction 5 times, vacuum drying.
Figure A20071004140600221
Embodiment 31
[1-butyl-3-ethyl benzo imidazole] [hexafluorophosphoric acid] ion liquid preparation
The ice bath lower magnetic force stirs, and paratoluenesulfonic acid sodium salt is slowly added in the aqueous solution of equimolar bromination 1-ethyl-3-butyl benzene benzimidazole salt, after 12 hours, gets organic phase, at every turn with ultrapure water 20ml washing extraction 5 times, vacuum drying.
Figure A20071004140600222
Embodiment 32
Solid-state three electrode making
Glass carbon, silver and platinum are connected with copper wire as working electrode, contrast electrode with to electrode with silver conductive adhesive respectively.Be packaged into solid-state three electrodes shown in Figure 20 A with AB glue.
Embodiment 33
The making of solid-state two electrodes
Glass carbon is connected as working electrode with to electrode with copper wire with silver conductive adhesive respectively with platinum.With solid-state two electrodes shown in AB glue Feng Chengru Figure 20 B.
Embodiment 34
Polymer film absorbent-type humidity-sensitive element
Get the alkyl imidazole of the embodiment 1-31 preparation of certain volume, the alkyl pyridine class, quaternary ammonium salt, the quaternary phosphonium salt, benzimidazole room-temperature ion liquid liquid solution is as [1-ethyl-3 methylimidazole] [tetrafluoro boric acid], [1-butyl-3 methylimidazole] [hexafluorophosphoric acid], [1-Kui Ji-3-methyl] [tetrafluoro boric acid], [N-butyl-pyridinium] [hexafluorophosphoric acid], [N-butyl-pyridinium] [tetrafluoro boric acid], [N-heptyl pyridine] [hexafluorophosphoric acid], [dimethyl ethanol base 3-sulfonic acid propyl ammonium] [p-methyl benzenesulfonic acid], [three ethanol based 3-sulfonic acid propyl ammoniums] [p-toluenesulfonic acid], [diethyl alcohol radical sulfonic acid butyl ammonium] [hydrogen sulfate], [tetrabutyl phosphorus] [two-(trifluoromethyl) sulfimides], [tributyl-methyl phosphonium phosphorus] [methane-sulforic acid], [tributyl myristyl phosphorus] [two-(trifluoromethyl) sulfimides], [1-ethyl-3-butyl benzimidazole] [tetrafluoro boric acid], [1-ethyl-3-butyl benzimidazole] [[hexafluorophosphoric acid], [1-ethyl-3-butyl benzimidazole] [p-methyl benzenesulfonic acid].With tetracyano-p-quinodimethane, N, N, N ', N '-tetramethyl-para-phenylene diamine, ferrocene, benzoquinones, ferrocene, the potassium ferricyanide, four ammino rutheniums, metalloporphyrin or metal phthalocyanine add ionic liquid and dissolving.Respectively the above-mentioned ionic liquid that is dissolved with oxidation-reduction pair is adsorbed onto perforated membrane: in polyethylene film, Polyvinylchloride, teflon, poly-inclined to one side tetrafluoroethene, poly-cellulose acetate, again film is covered embodiment 32, the surface of 33 prepared electrodes or screen printing electrode, vapor deposited metal electrode, make humidity-sensitive element, shown in Figure 20 A and 20B.
Embodiment 35
The making of silicon chip three electrode humidity-sensitive elements
On silicon chip or potsherd, metallic films such as gold evaporation or platinum are as working electrode, to electrode.With the method for laser-induced thermal etching or chemical etching, on silicon chip, etch a certain size hole.Silicon chip or potsherd thermocompression bonding that etching is crossed silicon chip and metal-coated films, thus as shown in the figure electrode structure formed.With embodiment 34, configuration contains the ionic liquid solution of electrochemical probe, and it is added dropwise in the silicon chip groove, makes the silicon chip humidity-sensitive element shown in Figure 20 C.
Embodiment 36
The making of polymer gel type humidity-sensitive element
The ionic liquid solution that contains electrochemical probe with embodiment 34 configurations, and with its same in proportion Kynoar, poly-N, N-DMAA, polyoxyethylene, polymethylmethacrylate or polyvinylpyrrolidone/acetate ethylene copolymer etc. are dissolved in carbonic allyl ester or the 4-methyl-2 pentanone together, form colloidal sol, colloidal sol is dripped in embodiment 32, the surface of 33 prepared electrodes or screen printing electrode, vapor deposited metal electrode, promptly make polymer gel type humidity-sensitive element after the vacuum drying, structure is shown in Figure 20 A and 20B.
Embodiment 37
The making of silicon gel-type humidity-sensitive element
The ionic liquid solution that contains electrochemical probe with embodiment 34 configurations, and with its in proportion with water, ethanol, and tetramethoxysilance or tetraethoxysilance mixes formation colloidal sol, with embodiment 36 this colloidal sol is dripped in embodiment 32 again, the surface of 33 prepared electrodes or screen printing electrode, vapor deposited metal electrode, promptly make silicon polymer gel-type humidity-sensitive element after the vacuum drying, structure is shown in Figure 20 A and 20B.
Embodiment 38
The making of sandwich type humidity-sensitive element
Contain the ionic liquid solution of electrochemical probe with embodiment 34 configuration, and be impregnated among porous ceramics or apertured polymeric film such as polyethylene film, Polyvinylchloride, teflon, poly-inclined to one side tetrafluoroethene, the poly-cellulose acetate etc.As shown in the figure, it is sandwiched among carbon paper or the carbon cloth, and with stainless (steel) wire, copper mesh etc. as collector, the type that promptly sandwiches humidity-sensitive element,, structure is shown in Figure 20 D.
Embodiment 39
The test of ion liquid type humidity sensor
The device of experiment as shown in Figure 2.
1. nitrogen (oxygen) is fed in the water, make water saturation N 2(water saturation O 2), and mixing, make the atmosphere of different humidity with the dry nitrogen gas phase, the air-flow velocity that feeds sensor is 5L/min.
2. oxygen is to hygrometric interference
Measured the humidity-sensitive element that the 1-normal-butyl-3-methylimidazole hexafluorophosphoric acid ionic liquid the is made response of the cyclic voltammetric under nitrogen and oxygen atmosphere under dry and water saturation condition with the tetracyano-p-quinodimethane that contains 2mM respectively, the result as shown in Figure 3.No matter be as can be seen from the figure, illustrate that oxygen does not significantly disturb the mensuration of humidity almost consistent with the response under the oxygen atmosphere under drying or the water saturation condition at nitrogen.
3. adopt of the response of electrochemical method-cyclic voltammetry (CV) survey sensor to humidity
Fig. 4 is under the nitrogen atmosphere, and the cyclic voltammogram of the TCNQ under the different liquid water contents, Fig. 5 are that reduction peak current and the mapping of relative humidity content are linear.Adopt identical experimental technique, promptly alternately use water saturation N continuously 2With dry N 2Feed sensor, repeat 8 times, survey cyclic voltammetry simultaneously, continuous sweep 20 circles under the same case, the stability and the response time of investigation sensor.By calculating water saturation N 2Under response time be 38-42.5s, dry N 2Under response time be 33.5-38s.
Fig. 6 and Fig. 7 are respectively water saturation N 2With dry N 2Down, the CV figure of the 20th of 8 times the circle.As can be seen from the figure, adopt cyclic voltammetry, sensor stable fine.Can obtain water saturation N by calculating 2Down, the mean value of reduction current is-6.01 * 10 -7, standard deviation is 8.7535 * 10 -9, relative standard deviation is 1.4565%.Dry N 2Down, the mean value of reduction current is-4.089 * 10 -7, standard deviation is 1.8731 * 10 -9, relative standard deviation is 0.4581%.
4. adopt the response of electrochemical method-differential pulse voltammetry (DPV) survey sensor
Fig. 8 and 10 is respectively the differential pulse voltammogram under the different humidity under nitrogen and the oxygen atmosphere.The difference of oxidation current and reduction current is mapped to relative humidity, become good linear relationship (Fig. 9 and 11).Table 1 is under different humidity, reduction-oxidation current value and difference under oxygen, the nitrogen atmosphere.By table as seen: under the different atmosphere during same humidity, the reduction-oxidation current value basically identical of TCNQ, and nitrogen atmosphere lower linear pass is: Y=2.23443+0.01576X; The oxygen atmosphere lower linear is closed: Y=2.16181+0.01549X, both linear equations are basically identical also.Illustrate that oxygen is to the not influence of this sensor.
Reduction-oxidation current value and the difference of table 1 TCNQ under oxygen, the nitrogen atmosphere under different humidity
Water cut %/v/v N 2Atmosphere/A O 2Atmosphere/A
Oxidation current Reduction current Difference Oxidation current Reduction current Difference
0 1.118 -1.103 2.221 1.075 -1.072 2.147
20 1.308 -1.308 2.616 1.255 -1.249 2.504
40 1.315 -1.455 2.77 1.374 -1.38 2.754
60 1.591 -1.593 3.184 1.553 -1.542 3.095
80 1.790 -1.784 3.574 1.713 -1.706 3.419
100 1.887 -1.883 3.77 1.854 -1.844 3.698
For response time and the stability of investigating sensor, alternately use water saturation N continuously 2With dry N 2Feed sensor, repeat 8 times, survey DPV simultaneously, continuous sweep 10 circles under the same case.Figure 12 and Figure 13 are respectively water saturation N 2With dry N 2Under the condition, the 6th time 10 circle situations of change, the situation of other number of times is similar.As can be seen from the figure, water saturation N 2Down, the reduction-oxidation electric current increases to gradually and reaches stable; Dry N 2Down, the reduction-oxidation electric current is decreased to gradually and reaches stable.By calculating, can obtain the response time of this sensor, at water saturation N 2Be down 55.5-74s, at dry N 2Be down 92.5-111s.
Under the identical atmosphere, the DPV that repeats 8 times the 10th circle schemes as Figure 14 and shown in Figure 15.Can obtain water saturation N by calculating 2Down, the mean value of the difference of oxidation and reduction current is 3.5778 A, and standard deviation is 3.535 * 10 -8, relative standard deviation is 0.998%.Dry N 2Down, oxidation is 1.5556 * 10 with the mean value of the difference of reduction -7, standard deviation is 4.312 * 10 -9, relative standard deviation is 2.7719%.
5. adopt the response of electrochemical method-square wave voltammetry (SWV) survey sensor
Figure 16 is under the nitrogen atmosphere, the cyclic voltammogram of TCNQ under the different liquid water contents.Figure 17 maps to relative humidity for the difference of oxidation peak current and reduction peak current, becomes good linear relationship.Adopt identical experimental technique, that is, alternately feed sensor continuously, repeat 8 times, survey square wave voltammetry simultaneously, continuous sweep 10 circles under the same case with water saturation N2 and dry N2.By calculating, the response time under the water saturation N2 is 21-28s, and the response time under the dry N2 is 42-49s.
Figure 18 and Figure 19 are under water saturation N2 and the dry N2, and the SWV of 8 order, 10 circles schemes.Can obtain by calculating, under the water saturation N2, the mean value of the difference of oxidation peak current and reduction peak current is 4.184 * 10 -6, standard deviation is 4.6023 * 10 -8, relative standard deviation is 1.1000%.Under the dry N2, the mean value of the difference of oxidation peak current and reduction peak current is 1.7254 * 10 -6, standard deviation is 4.143 * 10 -8, relative standard deviation is 2.401%.

Claims (10)

1. an ion liquid type humidity sensor is made up of ionic liquid at room temperature, ionic liquid carrier and two electrodes at least.
2. ion liquid type humidity sensor according to claim 1 is characterized in that, described ionic liquid at room temperature is selected from one or more in alkyl imidazole, alkyl pyridine class, quaternary ammonium salt, quaternary phosphonium salt or the benzimidazole ionic liquid.
3. ion liquid type humidity sensor according to claim 2, it is characterized in that described ionic liquid at room temperature is selected from [1-ethyl-3 methylimidazole] [tetrafluoro boric acid], [1-butyl-3 methylimidazole] [hexafluorophosphoric acid], [1-Kui Ji-3-methyl] [tetrafluoro boric acid], [N-butyl-pyridinium] [hexafluorophosphoric acid], [N-butyl-pyridinium] [tetrafluoro boric acid], [N-heptyl pyridine] [hexafluorophosphoric acid], [dimethyl ethanol base 3-sulfonic acid propyl ammonium] [p-methyl benzenesulfonic acid], [three ethanol based 3-sulfonic acid propyl ammoniums] [p-toluenesulfonic acid], [diethyl alcohol radical sulfonic acid butyl ammonium] [hydrogen sulfate], [tetrabutyl phosphorus] [two-(trifluoromethyl) sulfimides], [tributyl-methyl phosphonium phosphorus] [methane-sulforic acid], [tributyl myristyl phosphorus] [two-(trifluoromethyl) sulfimides], [1-ethyl-3-butyl benzimidazole] [tetrafluoro boric acid], [1-ethyl-3-butyl benzimidazole] [[hexafluorophosphoric acid], in [1-ethyl-3-butyl benzimidazole] [p-methyl benzenesulfonic acid] 1-ethyl-3 methyl imidazolium tetrafluoroborate one or more.
4. ion liquid type humidity sensor according to claim 1 is characterized in that, but described ionic liquid carrier is ion liquid container immobilized ionic liquid film or gel, adsorbable ion liquid cotton-shaped carrier or semiconductor substrate.
5. ion liquid type humidity sensor according to claim 1 is characterized in that, described electrode is metal electrode or nonmetal electrode.
6. ion liquid type humidity sensor according to claim 5 is characterized in that, described nonmetal electrode is carbon electrode or silicon electrode.
7. ion liquid type humidity sensor according to claim 1 is characterized in that, when described electrode was three, one of them was a working electrode, one constitute electrode loop to electrode, another is a contrast electrode.
8. ion liquid type humidity sensor according to claim 1 is characterized in that, when described electrode was two, one of them was a working electrode, another simultaneously as contrast electrode and constitute electrode loop to electrode.
9. the preparation method of an ion liquid type humidity sensor, its step comprises: the preparation room temperature ionic liquid; With ionic liquid at room temperature, ionic liquid carrier and at least two combination of electrodes are become humidity-sensitive element.
10. the preparation method of ion liquid type humidity sensor according to claim 9, it is characterized in that described ionic liquid at room temperature is selected from one or more in alkyl imidazole, alkyl pyridine class, quaternary ammonium salt, quaternary phosphonium salt or the benzimidazole ionic liquid.
CN 200710041406 2007-05-29 2007-05-29 Ion liquid type humidity sensor Pending CN101059490A (en)

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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103896849A (en) * 2012-12-26 2014-07-02 陈燿腾 Novel nitrile-benzimidazole salt and preparation method thereof
CN109884138A (en) * 2019-03-27 2019-06-14 苗伟宁 A kind of flexible humidity sensor with fast-response characteristic
CN112014441A (en) * 2020-09-04 2020-12-01 北京化工大学常州先进材料研究院 Ionic gel humidity sensor, preparation method and application thereof
CN114133501A (en) * 2020-09-03 2022-03-04 中国科学院大连化学物理研究所 Preparation method of high-water-vapor adsorption polymer ionic gel

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103896849A (en) * 2012-12-26 2014-07-02 陈燿腾 Novel nitrile-benzimidazole salt and preparation method thereof
CN103896849B (en) * 2012-12-26 2017-05-24 陈燿腾 Nitrile-benzimidazole salt and preparation method thereof
CN109884138A (en) * 2019-03-27 2019-06-14 苗伟宁 A kind of flexible humidity sensor with fast-response characteristic
CN114133501A (en) * 2020-09-03 2022-03-04 中国科学院大连化学物理研究所 Preparation method of high-water-vapor adsorption polymer ionic gel
CN114133501B (en) * 2020-09-03 2023-01-24 中国科学院大连化学物理研究所 Preparation method of high-water-vapor adsorption polymer ionic gel
CN112014441A (en) * 2020-09-04 2020-12-01 北京化工大学常州先进材料研究院 Ionic gel humidity sensor, preparation method and application thereof

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