CN103776884B - A kind of preparation method of integrated microarray electrode - Google Patents
A kind of preparation method of integrated microarray electrode Download PDFInfo
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Abstract
The invention provides a kind of preparation method of integrated microarray electrode, the first electrode material is injected in glass capillary, obtains the first glass capillary; By the second electrode material sealing by fusing in one end of thin glass tube, add the first conducting medium from the other end, connect the first wire sealing, obtain contrast electrode and hold concurrently to electrode; Being held concurrently by contrast electrode injects in glass tube to electrode and many first glass capillaries, and space adopts glassware to fill, more filling second conducting medium, connects the second wire sealing, obtains integrated microarray electrode.Compared with prior art, first the present invention all adopts glass tube encapsulation and integration to decline array electrode, thus make it be integrated in one, easy to use, and electrode separation is fixed, sample batch detection experiment error is less, and adopt glass tube encapsulation to make the tiny array electrode of preparation is corrosion-resistant, resistance tocrocking is comparatively strong, stability is better simultaneously; Secondly, contrast electrode of the present invention is held concurrently and is integrated electrode, makes simple, easy to maintenance.
Description
Technical field
The invention belongs to Technology of Microelectrodes field, particularly relate to a kind of preparation method of integrated microarray electrode.
Background technology
Microelectrode refers to the electrode being at least less than 25 μm in unidimensional scale, and this yardstick is called critical dimension.Can prepare now the little electrode to 0.1 μm of critical dimension, the electrode that critical dimension is less is commonly called nano electrode.Owing to will possess the character of microelectrode, electrode only needs in a dimension enough little just passable, so microelectrode can have many shapes: modal is micro-disk electrode, is that to be encapsulated in by tinsel the interface obtained in insulator be discoid microelectrode; In addition, also have micro-strip electrode, be encapsulated in insulator by metal forming and obtain; Micro-cylinder electrode, simple exposure one end tinsel or carbon fiber obtain.
Relative to the electrode of stock size, small-sized microelectrode has much unusual advantage.The steady-state current density of microelectrode is better than the electric current of conventional electrodes under forced convertion, and meanwhile, the steady-state current of microelectrode is all obtained than being easier to by theory calculate and laboratory facilities.As prerequisite, much the work of research dynamics or reaction mechanism is all based on microelectrode, as: the small size that research stock size electrode cannot be close or the In vivo detection in little space; Effects on surface carries out imaging, as scan-type electrochemical microscope; Be used for the change of other electroactive surface electroactive materials of glitch-free detection/monitor.
Tiny array electrode refers to and integrates formed electrode by multiple microelectrode, and its electric current is the algebraic sum of each unitary electrode electric current.Tiny array electrode maintains the characteristic of original unitary electrode, can obtain larger strength of current again, and conventional electrochemical apparatus can detect its signal, is conducive to analytical applications.
H.X.He(Langmuir16, 2000, 9684) by the method for soft printing stencil, H.Kaden(Electrochem.Commun.2, 2000, 606) with exact instrument, micro-array electrode is prepared in electrode material sealing in the epoxy, but above-mentioned preparation method needs special exact instrument, cost is higher, common lab is difficult to preparation, and wire electrode stochastic distribution, easily cause the overlap of electric capacity between adjacent electrode and diffusion, micro-array electrode is caused to present the electrochemical behavior of conventional large electrode, lose the good characteristic of microelectrode, and surface is difficult to process after each test.
Publication number is the preparation method that the Chinese patent of CN1544928A discloses micro-array electrode, it makes array electrode with quartz capillary encapsulated electrode material, but the method curing materials is epoxy resin, it can also make golden tiny array electrode, but electrode very easily pollutes, limit its range of application.
At present, three-electrode system generally adopts the working electrode of dispersion, contrast electrode and forms electrode, very inconvenient for the measurement in roving environment, and the distance between electrode is also not easily fixed, and causes larger error.It is that glass tube silver/silver chloride being placed in a band ceramic core is made that silver/silver chloride (Ag/AgCl) contrast electrode of generally acknowledging has a kind of, and due in method, this electrode easily pollutes, and not easy cleaning; And directly adopt filamentary silver to there is the shortcoming of current potential instability as contrast electrode, so that using conventional electrochemical method as cannot be accurately measured during cyclic voltammetry.
Application number is that to disclose a kind of preparation method of compound microelectrode and application number be that the Chinese patent of ZL03266018.9 discloses needle three-in-one microelectrodes to the Chinese patent of ZL03137469.7, refer in these two patents and three electrodes are compounded in one, although have lot of advantages and purposes widely, but three electrodes are just simply assembled together, and do not organically blend.Detection electric current on microelectrode, usually in nA level, detects so little electric current very high to the requirement of detecting device, and in actual applications, the electric current due to single microelectrode is less than the Monitoring lower-cut of Conventional electrochemical instrument sometimes, so application is restricted.
Summary of the invention
In view of this, the technical problem to be solved in the present invention is the preparation method providing a kind of integrated microarray electrode, and the integrated microarray electrode prepared of the method is easy to use and stability is better.
The invention provides a kind of preparation method of integrated microarray electrode, comprise the following steps:
First electrode material is injected in glass capillary, obtains the first glass capillary; The length of length < first electrode material of described glass capillary;
By the second electrode material sealing by fusing in one end of thin glass tube, then add the first conducting medium from the other end, connect the first wire, by the thin glass tube sealing after connection first wire, obtain contrast electrode and hold concurrently to electrode; Or the second electrode material is injected in thin glass tube, seal after then the second electrode material being drawn thin glass tube, obtain contrast electrode and hold concurrently to electrode;
Being held concurrently by described contrast electrode injects in glass tube to electrode and many described first glass capillaries, and described first glass capillary, described contrast electrode are held concurrently and adopted glassware to fill to the space between electrode and described glass tube, obtain the first glass tube; Described in the length < of glass tube described in the length < of described first glass capillary, contrast electrode is held concurrently to the length of electrode;
By filling for described first glass tube the second conducting medium, connect the second wire, by the first glass tube sealing after connection second wire, obtain integrated microarray electrode.
Preferably, the internal diameter of described glass capillary is less than or equal to 3 times of the first electrode material diameter.
Preferably, the pipe thickness of described glass capillary is greater than 3 times of the first electrode material radius.
Preferably, described first electrode material and the second electrode material are fibrous electrodes material.
Preferably, described first electrode material is one or more in carbon fiber, platinum, gold, copper, palladium, silver, nickel, iridium, iron, tin oxide and indium oxide.
Preferably, described second electrode material is platinum, platinum black or carbon.
Preferably, described first conducting medium and the second conducting medium are dag, silver powder or conducting resinl independently of one another.
Preferably, described glassware is glass bar, glass dust or glass tube.
Preferably, after the first electrode material being injected in glass capillary, also comprise:
By one end end-blocking of the glass capillary of reeve first electrode material.
Preferably, after the first glass tube sealing after connection second wire, also comprise:
Adopt ultrasound wave to process, obtain integrated microarray electrode.
The invention provides a kind of preparation method of integrated microarray electrode, comprise the following steps: the first electrode material is injected in glass capillary, obtains the first glass capillary; The length of length < first electrode material of described glass capillary; By the second electrode material sealing by fusing in one end of thin glass tube, then add the first conducting medium from the other end, connect the first wire, by the thin glass tube sealing after connection first wire, obtain contrast electrode and hold concurrently to electrode; Or the second electrode material is injected in thin glass tube, seal after then the second electrode material being drawn thin glass tube, obtain contrast electrode and hold concurrently to electrode; Being held concurrently by described contrast electrode injects in glass tube to electrode and many described first glass capillaries, and described first glass capillary, described contrast electrode are held concurrently and adopted glassware to fill to the space between electrode and described glass tube, obtain the first glass tube; Described in the length < of glass tube described in the length < of described first glass capillary, contrast electrode is held concurrently to the length of electrode; By filling for described first glass tube the second conducting medium, connect the second wire, by the first glass tube sealing after connection second wire, obtain integrated microarray electrode.Compared with prior art, first, the present invention all adopts glass tube encapsulation and integration to decline array electrode, thus make it be integrated in one, easy to use, and electrode separation is fixed, sample batch detection experiment error is less, meanwhile, the tiny array electrode of preparation is corrosion-resistant, resistance tocrocking is comparatively strong, stability is better to adopt glass tube encapsulation to make; Secondly, the second electrode material is prepared as contrast electrode and holds concurrently to electrode by the present invention, makes simple, easy to maintenance; Again, the electric current of integrated microarray electrode is large compared with microelectrode, and sensitivity is higher.
Accompanying drawing explanation
Fig. 1 is the structural representation of the integrated microarray electrode that the embodiment of the present invention 1 prepares;
Fig. 2 is the electric current-frequency curve figure of the integrated microarray electrode that the embodiment of the present invention 1 prepares.
Embodiment
The invention provides a kind of preparation method of integrated microarray electrode, comprise the following steps:
First electrode material is injected in glass capillary, obtains the first glass capillary; The length of length < first electrode material of described glass capillary;
By the second electrode material sealing by fusing in one end of thin glass tube, then add the first conducting medium from the other end, connect the first wire, by the thin glass tube sealing after connection first wire, obtain contrast electrode and hold concurrently to electrode; Or the second electrode material is injected in thin glass tube, seal after then the second electrode material being drawn thin glass tube, obtain contrast electrode and hold concurrently to electrode;
Being held concurrently by described contrast electrode injects in glass tube to electrode and many described first glass capillaries, and described first glass capillary, described contrast electrode are held concurrently and adopted glassware to fill to the space between electrode and described glass tube, obtain the first glass tube; Described in the length < of glass tube described in the length < of described first glass capillary, contrast electrode is held concurrently to the length of electrode;
By filling for described first glass tube the second conducting medium, connect the second wire, by the first glass tube sealing after connection second wire, obtain integrated microarray electrode.
According to the present invention, the first electrode material is injected in glass capillary, obtains the first glass capillary.Wherein, described first electrode material is preferably fibrous electrodes material; Described first electrode material is electrode material well known to those skilled in the art, the present invention be preferably in carbon fiber, platinum, gold, copper, palladium, silver, nickel, iridium, iron, tin oxide and indium oxide one or more.Adopt different electrode materials can make the different tiny array electrode of performance; The internal diameter of described glass capillary is preferably greater than the diameter of the first electrode material, and is less than or equal to 3 times of the first electrode material diameter; The pipe thickness of described glass capillary is preferably more than 3 times of the first electrode material radius.
In the present invention, after the first electrode material being injected in glass capillary, preferably by one end end-blocking of the glass capillary of reeve first electrode material.The method of described end-blocking is method well known to those skilled in the art, is preferably heating and melting end-blocking.Length due to glass capillary is less than the length of the first electrode material, therefore obtains one end end-blocking after end-blocking, the first glass capillary that the other end first electrode material exposes.
By the second electrode material sealing by fusing in one end of thin glass tube, then add the first conducting medium from the other end.Wherein, described second electrode material is preferably fibrous electrodes material; Described second electrode material is well known to those skilled in the artly can be used as contrast electrode and electrode material to electrode, and there is no special restriction, the present invention is preferably platinum, platinum black or carbon; Described first conducting medium is conducting medium well known to those skilled in the art, there is no special restriction, and the present invention is preferably dag, silver powder or conducting resinl.
After adding the first conducting medium, connect the first wire, described first wire is wire well known to those skilled in the art, there is no special restriction, is preferably copper wire in the present invention.By the thin glass tube sealing after connection first wire, obtain contrast electrode and hold concurrently to electrode.Described sealing preferably adopts sealed membrane to seal.
According to the present invention, described contrast electrode is held concurrently and following methods also can be adopted to be prepared to electrode: injected by the second electrode material in thin glass tube, seals after then the second electrode material being drawn thin glass tube, obtains contrast electrode and holds concurrently to electrode.The method directly adopts second electrode material of whole to draw thin glass tube, without the need to adding conducting medium.
Many described first glass capillaries and described contrast electrode being held concurrently injects in glass tube to electrode, and described first glass capillary, described contrast electrode are held concurrently and are adopted glassware to fill to the space between electrode and described glass tube, thus obtain the first glass tube.Wherein, described glassware is preferably glass bar, glass dust or glass tube, holds concurrently to electrode in order to fix the first glass capillary and contrast electrode.In the present invention preferably between many first glass capillary electrode materials, the first glass capillary and contrast electrode to hold concurrently to electrode material between spacing be greater than the radius of first electrode material of 6 times.If the spacing between described electrode material is too small, then easily causes the diffusion closed between electrode overlapping, cause integrated microarray electrode to present the electrochemical behavior of large electrode.
According to the present invention, the preparation method of described first glass tube is specially: many described first glass capillaries and described contrast electrode are held concurrently and inject in glass tube to electrode, described first glass capillary, described contrast electrode is held concurrently and is adopted glassware to fill to the space between electrode and described glass tube, by the first glass capillary of end-blocking, the contrast electrode of end-blocking is held concurrently and is flushed with glass tube electrode, and by described glass tube, described first glass capillary and described contrast electrode are held concurrently and are carried out fusing end-blocking to one end that electrode flushes, vacuumize, and from end-blocking to upper end heating and melting, with after annealing, cooling, namely the first glass tube is obtained.In the process of above-mentioned preparation first glass tube, described heating and melting and the described operation vacuumized are all to prevent air to be enclosed in glass tube, thus affect electrode performance.
After obtaining the first glass tube, in described first glass tube, filling second conducting medium, connects the second wire, by the first glass tube sealing after connection second wire, obtains integrated microarray electrode.Wherein, described second conducting medium is conducting medium well known to those skilled in the art, there is no special restriction, is preferably dag, silver powder or conducting resinl in the present invention; Described second wire is preferably copper wire or copper rod.
According to the present invention, after the first glass tube sealing after connection second wire, preferably also carry out ultrasound wave process.Ultrasound wave process can make conducting medium tightly packed, strengthens electric conductivity, reduces measuring-signal noise.
In the present invention, after obtaining integrated microarray electrode, preferably carried out pre-service.Described pretreated step is specially: by integrated microarray electrode successively with 600 orders, 1200 orders, 2000 order 3000 orders, 5000 orders and 7000 object abrasive paper for metallograph are from coarse to fine that end face is polished cunning, then use successively 0.5 μm with the α-Al of 0.03 μm
2o
3electrode surface polishes by polishing sponge cloth, and be finally placed on ethanol and secondary deionized water ultrasonic cleaning three times respectively, each 1 ~ 3min, can carry out performance test by integrated microarray electrode.
The present invention all adopts glass tube encapsulation and integration to decline array electrode, thus make it be integrated in one, easy to use, and electrode separation is fixed, sample batch detection experiment error is less, meanwhile, the tiny array electrode of preparation is corrosion-resistant, resistance tocrocking is comparatively strong, stability is better to adopt glass tube encapsulation to make; In addition, the second electrode material is prepared as contrast electrode and holds concurrently to electrode by the present invention, makes simple, easy to maintenance; Further, the electric current of integrated microarray electrode is large compared with microelectrode, and sensitivity is higher.
In order to further illustrate the present invention, below in conjunction with embodiment, the preparation method to a kind of integrated microarray electrode provided by the invention is described in detail.
In following examples, agents useful for same is commercially available.
Embodiment 1
1.1 get one section of raw glass pipe, clean glass tube inside and outside wall successively by ethanol, secondary deionized water, dry, and gaslight heating is drawn into glass capillary (wall thickness more than 100 μm), is cut into 15mm segment, obtains glass capillary; Be that the platinum filament of 20 μm is cut into the long segment of 20mm by diameter, pierce in glass capillary, one section of heating and melting end-blocking, obtains the first glass capillary.
1.2, thin glass tube one end sealing by fusing one section of platinum filament (Φ=1.0mm), add dag from the other end, contact with the platinum filament exposed in thin glass tube, then inserted by copper wire as the first wire in dag, with sealed membrane sealing, obtain contrast electrode and hold concurrently to electrode.
The first glass capillary obtained in many 1.1 is filled in (external diameter 4mm in the glass tube cleaned up in advance by difformity arrangement by 1.3, internal diameter 3mm, long 7cm) in, the contrast electrode of preparation in 1.2 that also has inserted in the lump in glass tube is held concurrently to electrode, full space is filled with the empty glass tube not wearing platinum filament, to ensure that position is fixed each other, first glass capillary of end-blocking, the contrast electrode of end-blocking is held concurrently concordant with glass tube to electrode, platinum filament indentation 3mm, with spirit lamp by glass tube, first glass capillary and contrast electrode are held concurrently to the thin glass tube melting end-blocking of electrode, the other end inserts syringe needle, seal with sealed membrane, connect vacuum pump, vacuumize, to upper end heating and melting from end-blocking, annealing, filling dag after cooling, insertion copper rod is drawn, sealing compound seals, ultrasound wave process makes dag tightly packed.Melted ends 3mm is clipped after cooling with glass cutter, use 600 orders, 2000 orders, 3000 orders, 5000 orders and 7000 order abrasive paper for metallograph successively by thick to thin by interface polishing, " 8 " font alternating direction is milled, and prevents electrode from grinding partially, then use successively 0.5 μm with the α-Al of 0.03 μm
2o
3electrode surface is polished into minute surface by polishing sponge cloth, and be finally placed on ethanol and secondary deionized water ultrasonic cleaning three times respectively, each 1min, obtains integrated microarray electrode.
Fig. 1 is the schematic diagram of the integrated microarray electrode obtained in 1.3.Wherein, 1 is the first wire copper wire; 2 is thin glass tube; 3 is dag; 4 is platinum filament; 5 is micron order platinum filament; 6 is dag; 7 is glass tube; 8 is the second wire copper rod.
The integrated microarray electrode obtained in 1.3 is measured its current value (getting value during 10s) in 25mM potassium ferrocyanide (0.1MKCl solution is as supporting electrolyte) solution, obtains the electric current-frequency curve of this integrated microarray electrode, as shown in Figure 2.This integrated microarray electrode pair sample batch detection experiment error is less as seen from Figure 2.
Embodiment 2
2.1 get one section of raw glass pipe, clean glass tube inside and outside wall successively by ethanol, secondary deionized water, dry, and gaslight heating is drawn into glass capillary (wall thickness more than 100 μm), is cut into 15mm segment, obtains glass capillary; Be that the carbon fiber of 7 μm is cut into the long segment of 20mm by diameter, pierce in glass capillary, one section of heating and melting end-blocking, obtains the first glass capillary.
2.2, thin glass tube one end sealing by fusing one section of platinum filament (Φ=1.0mm), add dag from the other end, contact with the platinum filament exposed in thin glass tube, then inserted by copper wire as the first wire in dag, with sealed membrane sealing, obtain contrast electrode and hold concurrently to electrode.
The first glass capillary obtained in many 2.1 is filled in (external diameter 4mm in the glass tube cleaned up in advance by difformity arrangement by 2.3, internal diameter 3mm, long 7cm) in, the contrast electrode of preparation in 2.2 that also has inserted in the lump in glass tube is held concurrently to electrode, full space is filled with the empty glass tube not wearing carbon fiber, to ensure that position is fixed each other, first glass capillary of end-blocking, the contrast electrode of end-blocking is held concurrently concordant with glass tube to electrode, carbon fiber indentation 3mm, with spirit lamp by glass tube, first glass capillary and contrast electrode are held concurrently to the thin glass tube melting end-blocking of electrode, the other end inserts syringe needle, seal with sealed membrane, connect vacuum pump, vacuumize, to upper end heating and melting from end-blocking, annealing, filling dag after cooling, insertion copper rod is drawn, sealing compound seals, ultrasound wave process makes dag tightly packed.Melted ends 3mm is clipped after cooling with glass cutter, use 600 orders, 2000 orders, 3000 orders, 5000 orders and 7000 order abrasive paper for metallograph successively by thick to thin by interface polishing, " 8 " font alternating direction is milled, and prevents electrode from grinding partially, then use successively 0.5 μm with the α-Al of 0.03 μm
2o
3electrode surface is polished into minute surface by polishing sponge cloth, and be finally placed on ethanol and secondary deionized water ultrasonic cleaning three times respectively, each 1min, obtains integrated microarray electrode.
Embodiment 3
3.1 get one section of raw glass pipe, clean glass tube inside and outside wall successively by ethanol, secondary deionized water, dry, and gaslight heating is drawn into glass capillary (wall thickness more than 100 μm), is cut into 15mm segment, obtains glass capillary; Be that the palladium silk of 10 μm is cut into the long segment of 20mm by diameter, pierce in glass capillary, one section of heating and melting end-blocking, obtains the first glass capillary.
3.2, thin glass tube one end sealing by fusing one section of platinum filament (Φ=1.0mm), add dag from the other end, contact with the platinum filament exposed in thin glass tube, then inserted by copper wire as the first wire in dag, with sealed membrane sealing, obtain contrast electrode and hold concurrently to electrode.
The first glass capillary obtained in many 3.1 is filled in (external diameter 4mm in the glass tube cleaned up in advance by difformity arrangement by 3.3, internal diameter 3mm, long 7cm) in, the contrast electrode of preparation in 3.2 that also has inserted in the lump in glass tube is held concurrently to electrode, full space is filled with the empty glass tube not wearing palladium silk, to ensure that position is fixed each other, first glass capillary of end-blocking, the contrast electrode of end-blocking is held concurrently concordant with glass tube to electrode, palladium silk indentation 3mm, with spirit lamp by glass tube, first glass capillary and contrast electrode are held concurrently to the thin glass tube melting end-blocking of electrode, the other end inserts syringe needle, seal with sealed membrane, connect vacuum pump, vacuumize, to upper end heating and melting from end-blocking, annealing, filling dag after cooling, insertion copper rod is drawn, sealing compound seals, ultrasound wave process makes dag tightly packed.Melted ends 3mm is clipped after cooling with glass cutter, use 600 orders, 2000 orders, 3000 orders, 5000 orders and 7000 order abrasive paper for metallograph successively by thick to thin by interface polishing, " 8 " font alternating direction is milled, and prevents electrode from grinding partially, then use successively 0.5 μm with the α-Al of 0.03 μm
2o
3electrode surface is polished into minute surface by polishing sponge cloth, and be finally placed on ethanol and secondary deionized water ultrasonic cleaning three times respectively, each 1min, obtains integrated microarray electrode.
Embodiment 4
4.1 get one section of raw glass pipe, clean glass tube inside and outside wall successively by ethanol, secondary deionized water, dry, and gaslight heating is drawn into glass capillary (wall thickness more than 100 μm), is cut into 15mm segment, obtains glass capillary; Be that the spun gold of 25 μm is cut into the long segment of 20mm by diameter, pierce in glass capillary, one section of heating and melting end-blocking, obtains the first glass capillary.
4.2, thin glass tube one end sealing by fusing one section of platinum filament (Φ=1.0mm), add dag from the other end, contact with the platinum filament exposed in thin glass tube, then inserted by copper wire as the first wire in dag, with sealed membrane sealing, obtain contrast electrode and hold concurrently to electrode.
The first glass capillary obtained in many 4.1 is filled in (external diameter 4mm in the glass tube cleaned up in advance by difformity arrangement by 4.3, internal diameter 3mm, long 7cm) in, the contrast electrode of preparation in 4.2 that also has inserted in the lump in glass tube is held concurrently to electrode, full space is filled with the empty glass tube not wearing spun gold, to ensure that position is fixed each other, first glass capillary of end-blocking, the contrast electrode of end-blocking is held concurrently concordant with glass tube to electrode, spun gold indentation 3mm, with spirit lamp by glass tube, first glass capillary and contrast electrode are held concurrently to the thin glass tube melting end-blocking of electrode, the other end inserts syringe needle, seal with sealed membrane, connect vacuum pump, vacuumize, to upper end heating and melting from end-blocking, annealing, filling dag after cooling, insertion copper rod is drawn, sealing compound seals, ultrasound wave process makes dag tightly packed.Melted ends 3mm is clipped after cooling with glass cutter, use 600 orders, 2000 orders, 3000 orders, 5000 orders and 7000 order abrasive paper for metallograph successively by thick to thin by interface polishing, " 8 " font alternating direction is milled, and prevents electrode from grinding partially, then use successively 0.5 μm with the α-Al of 0.03 μm
2o
3electrode surface is polished into minute surface by polishing sponge cloth, and be finally placed on ethanol and secondary deionized water ultrasonic cleaning three times respectively, each 1min, obtains integrated microarray electrode.
Embodiment 5
5.1 get one section of raw glass pipe, clean glass tube inside and outside wall successively by ethanol, secondary deionized water, dry, and gaslight heating is drawn into glass capillary (wall thickness more than 100 μm), is cut into 15mm segment, obtains glass capillary; Be that the filamentary silver of 15 μm is cut into the long segment of 20mm by diameter, pierce in glass capillary, one section of heating and melting end-blocking, obtains the first glass capillary.
5.2, thin glass tube one end sealing by fusing one section of platinum filament (Φ=1.0mm), add dag from the other end, contact with the platinum filament exposed in thin glass tube, then inserted by copper wire as the first wire in dag, with sealed membrane sealing, obtain contrast electrode and hold concurrently to electrode.
The first glass capillary obtained in many 5.1 is filled in (external diameter 4mm in the glass tube cleaned up in advance by difformity arrangement by 5.3, internal diameter 3mm, long 7cm) in, the contrast electrode of preparation in 5.2 that also has inserted in the lump in glass tube is held concurrently to electrode, full space is filled with the empty glass tube not wearing filamentary silver, to ensure that position is fixed each other, first glass capillary of end-blocking, the contrast electrode of end-blocking is held concurrently concordant with glass tube to electrode, filamentary silver indentation 3mm, with spirit lamp by glass tube, first glass capillary and contrast electrode are held concurrently to the thin glass tube melting end-blocking of electrode, the other end inserts syringe needle, seal with sealed membrane, connect vacuum pump, vacuumize, to upper end heating and melting from end-blocking, annealing, filling dag after cooling, insertion copper rod is drawn, sealing compound seals, ultrasound wave process makes dag tightly packed.Melted ends 3mm is clipped after cooling with glass cutter, use 600 orders, 2000 orders, 3000 orders, 5000 orders and 7000 order abrasive paper for metallograph successively by thick to thin by interface polishing, " 8 " font alternating direction is milled, and prevents electrode from grinding partially, then use successively 0.5 μm with the α-Al of 0.03 μm
2o
3electrode surface is polished into minute surface by polishing sponge cloth, and be finally placed on ethanol and secondary deionized water ultrasonic cleaning three times respectively, each 1min, obtains integrated microarray electrode.
The above is only the preferred embodiment of the present invention; it should be pointed out that for those skilled in the art, under the premise without departing from the principles of the invention; can also make some improvements and modifications, these improvements and modifications also should be considered as protection scope of the present invention.
Claims (10)
1. a preparation method for integrated microarray electrode, is characterized in that, comprises the following steps:
First electrode material is injected in glass capillary, obtains the first glass capillary; The length of length < first electrode material of described glass capillary;
By the second electrode material sealing by fusing in one end of thin glass tube, then add the first conducting medium from the other end, connect the first wire, by the thin glass tube sealing after connection first wire, obtain contrast electrode and hold concurrently to electrode; Or the second electrode material is injected in thin glass tube, seal after then the second electrode material being drawn thin glass tube, obtain contrast electrode and hold concurrently to electrode;
Being held concurrently by described contrast electrode injects in glass tube to electrode and many described first glass capillaries, and described first glass capillary, described contrast electrode are held concurrently and adopted glassware to fill to the space between electrode and described glass tube, obtain the first glass tube; Described in the length < of glass tube described in the length < of described first glass capillary, contrast electrode is held concurrently to the length of electrode;
By filling for described first glass tube the second conducting medium, connect the second wire, by the first glass tube sealing after connection second wire, obtain integrated microarray electrode.
2. preparation method according to claim 1, is characterized in that, the internal diameter of described glass capillary is less than or equal to 3 times of the first electrode material diameter.
3. preparation method according to claim 1, is characterized in that, the pipe thickness of described glass capillary is greater than 3 times of the first electrode material radius.
4. preparation method according to claim 1, is characterized in that, described first electrode material and the second electrode material are fibrous electrodes material.
5. preparation method according to claim 1, is characterized in that, described first electrode material is one or more in carbon fiber, platinum, gold, copper, palladium, silver, nickel, iridium, iron, tin oxide and indium oxide.
6. preparation method according to claim 1, is characterized in that, described second electrode material is platinum, platinum black or carbon.
7. preparation method according to claim 1, is characterized in that, described first conducting medium and the second conducting medium are dag, silver powder or conducting resinl independently of one another.
8. preparation method according to claim 1, is characterized in that, described glassware is glass bar, glass dust or glass tube.
9. preparation method according to claim 1, is characterized in that, after being injected by the first electrode material in glass capillary, also comprises:
By one end end-blocking of the glass capillary of reeve first electrode material.
10. preparation method according to claim 1, is characterized in that, after the first glass tube sealing after connection second wire, also comprises:
Adopt ultrasound wave to process, obtain integrated microarray electrode.
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