CN105070881A - High-capacity V2O5.nH2O thin-film electrode material for lithium ion battery - Google Patents

Abstract

The invention relates to a high-capacity V2O5.nH2O thin-film electrode material for a lithium ion battery. The high-capacity V2O5.nH2O thin-film electrode material is prepared by the following methods: (1) preparation of V2O5 sol, namely taking a proper amount of 30% hydrogen peroxide (H2O2) solution into a small beaker, weighing a certain amount of vanadium pentoxide (V2O5) powder into the beaker, slowly stirring the V2O5 powder at a room temperature until the V2O5 powder is completely dissolved, adding a proper amount of deionized water, further stirring the solution until stable reddish brown sol is formed, and diluting to a precise volume to obtain the V2O5 sol with the concentration being 0.008 mol/dm<3>; (2) pretreatment of an indium tin oxide (ITO) base, namely ultrasonically washing a to-be-treated ITO conductive glass sheet with a little of ethanol and deionized water sequentially for 15-30 minutes, and naturally drying the ITO conductive glass sheet for later use; and (3) preparation of a V2O5.nH2O thin-film electrode, namely taking 25[mu]l of V2O5 sol with a pipettor, spreading the V2O5 sol on the conductive surface of the pretreated ITO conductive glass sheet, naturally drying the V2O5 sol at the room temperature, sintering the ITO conductive glass sheet in a vacuum chamber at 150 DEG C for two hours, and naturally cooling the ITO conductive glass sheet to the room temperature, so as to obtain the V2O5.nH2O thin-film electrode. The prepared V2O5.nH2O thin-film has a special porous mesh morphology; the specific capacity of the lithium ion battery can be improved; the cycle performance of the lithium ion battery can be improved; the preparation process flow is simple; the production cost is low; and the high-capacity V2O5.nH2O thin-film electrode material has great application value.

Description

A kind of lithium ion battery high power capacity V 2o 5nH 2o thin-film electrode material

Technical field

The invention belongs to electrode material field, particularly a kind of high power capacity V for lithium ion battery ₂o ₅nH ₂o thin-film electrode material.

Background technology

Lithium ion battery is the novel storage battery grown up on lithium battery basis last century, specific energy is high, power density is high because having for lithium ion battery, have extended cycle life, self discharge is little, cost performance advantages of higher, has become the main alternative that can fill formula power supply again of current portable type electronic product.As power supply renewal product, be likely applied to high-power electric appliance field in the future.Can lithium ion battery realize commercialization will depend primarily on performance and price, in the evolution of lithium ion battery, positive electrode may become the bottleneck of its large-scale promotion application of restriction, thus develops superior performance, low-cost positive electrode is key factor in lithium ion commercialization process.

The many positive electrode of current research mainly contains the LiMO of layer structure ₂(wherein: M=Ni, Co, Mn etc.), but the problems such as the low and cyclicity of its specific capacity need to solve.Spinel-type LiMn ₂o ₄having the advantages such as security performance is good, easy synthesis, is also the anode material for lithium-ion batteries that research is more at present.But the John-Teller effect existed in charge and discharge process, can cause structure to distort, the symmetry of spinel structure is reduced, charge-discharge performance is deteriorated.There is the LiMPO of olivine crystal structure ₄(wherein: M=Fe, Mn, Ni, Co etc.) Heat stability is good, security performance are high, and have exceeded the transition metal oxide electrode material of layer structure in the stability of charged state, make it be specially adapted to electrokinetic cell.The irreversible capacity but caused because conductivity is low reduces the coulombic efficiency of battery.

V ₂o ₅nH ₂o xerogel is by V ₂o ₅the single vaporization of colloidal sol and obtaining.V ₂o ₅nH ₂o is fibrous by what be mutually wound around, and these fibers are made up of the band risen and fallen again, and the band of fluctuating presents two-dimensional structure, is similar to crystalline state V ₂o ₅structure.With it unlike, V ₂o ₅nH ₂in O, interlayer V-O key is relatively weak, Li ⁺embed wherein, lattice variations is less, is applicable to Li ⁺embed and deviate from, being conducive to the application in lithium ion battery.But still have that ion transportation is low, conductivity is low, charge-discharge performance is poor in actual applications, specific capacity and the problem such as energy density is low, limit its application in field of lithium ion battery.

Summary of the invention

The object of the present invention is to provide a kind of energy consumption low, time consume low, technique is simple, the lithium ion battery high power capacity V of with low cost, function admirable ₂o ₅nH ₂o thin-film electrode material.

Lithium ion battery V involved in the present invention ₂o ₅nH ₂o thin-film electrode material is prepared by the following method:

(1) V is prepared ₂o ₅colloidal sol: get the hydrogen peroxide (H of appropriate 30% ₂o ₂) solution is placed in small beaker, then takes a certain amount of vanadic oxide (V ₂o ₅) powder puts into beaker, at room temperature slowly stir and make V ₂o ₅powder dissolves completely, and then add appropriate amount of deionized water and continue to be stirred to the stable rufous colloidal sol of formation, constant volume, obtaining concentration is 0.008mol/dm ³v ₂o ₅colloidal sol;

(2) preliminary treatment ITO substrate: pending ITO electro-conductive glass sheet is carried out supersound washing 15-30 minute with a small amount of ethanol, deionized water successively, and natural air drying is stand-by;

(3) V is prepared ₂o ₅nH ₂o membrane electrode: measure 25 μ LV with pipettor ₂o ₅colloidal sol, spreads on the conducting surface of pretreated ITO electro-conductive glass sheet, and under room temperature after natural air drying, the vacuum tank being placed in 150 DEG C sinters 2 hours, naturally cools to room temperature, namely obtains V ₂o ₅nH ₂o membrane electrode.

By V prepared by this method ₂o ₅nH ₂o film presents the special appearance of holey.To V prepared by the present invention ₂o ₅nH ₂o thin-film electrode material, adopts three-electrode system, with 1mol/dm ³liClO ₄/ PC is electrolyte, V ₂o ₅membrane electrode is work electrode, and Pt sheet is auxiliary electrode, and Ag/AgCl is reference electrode, carries out cyclic voltammetric and constant current charge-discharge test.Test result shows: its cyclic voltammetry curve has two to the redox peak be obviously separated, and charging and discharging curve has obvious discharge platform, shows high embedding lithium capacity and good cycle performance.When charging and discharging currents density is 150mA/g, its initial discharge specific capacity can reach 408.75mAh/g, and the lithium ion battery V of current existing bibliographical information ₂o ₅nH ₂o electrode material, when current density is only 80mA/g, specific discharge capacity is only 390mAh/g.Under high current density (550mA/g), carry out long-time charge-discharge test, its initial discharge specific capacity is 232.83mAh/g, and after 104 cycle discharge and recharges, specific discharge capacity still can keep 198.61mAh/g.With the lithium ion battery V of existing bibliographical information ₂o ₅nH ₂o positive electrode is compared, V provided by the invention ₂o ₅nH ₂o film positive electrode, effectively overcomes the problems such as lithium ion battery specific capacity is low, charge-discharge performance is poor, significantly improves V ₂o ₅nH ₂o is as the using value of anode material for lithium-ion batteries.

Electrode fabrication process is by V ₂o ₅colloidal sol directly spreads over ito glass substrate previous step and completes, and technique is simple, and easy and simple to handle, process easily controls.And in process, do not relate to the use of conductive agent, bonding agent, the impact on environment can be reduced.In addition, the sintering temperature of electrode material is only 150 DEG C, and energy consumption is low, greatly can reduce the cost of manufacture of electrode.

Accompanying drawing explanation

Fig. 1 is V ₂o ₅nH ₂the SEM figure of O film;

Fig. 2 is V ₂o ₅nH ₂the cyclic voltammetry curve of O membrane electrode;

Fig. 3 is V ₂o ₅nH ₂the first charge-discharge curve (current density is 150mA/g) of O membrane electrode;

Fig. 4 is V under different current density ₂o ₅nH ₂the discharge capacity attenuation curve of O membrane electrode;

Fig. 5 is V ₂o ₅nH ₂the capacity attenuation curve (current density is 550mAh/g) of O membrane electrode;

Fig. 6 is V ₂o ₅nH ₂the cyclic voltammetric line of O membrane electrode before and after discharge and recharge;

Embodiment

Below in conjunction with drawings and Examples, the present invention is further described as follows:

Embodiment 1

A kind of high power capacity V for lithium ion battery ₂o ₅nH ₂the preparation method of O membrane electrode is as follows:

(1) V is prepared ₂o ₅colloidal sol: get the hydrogen peroxide (H of appropriate 30% ₂o ₂) solution is placed in small beaker, then takes a certain amount of vanadic oxide (V ₂o ₅) powder puts into beaker, at room temperature slowly stir and make V ₂o ₅powder dissolves completely, and then add appropriate amount of deionized water and continue to be stirred to the stable rufous colloidal sol of formation, constant volume, obtaining concentration is 0.008mol/dm ³v ₂o ₅colloidal sol;

(2) preliminary treatment ITO substrate: pending ITO electro-conductive glass sheet is carried out supersound washing 15-30 minute with a small amount of ethanol, deionized water successively, and natural air drying is stand-by;

(3) V is prepared ₂o ₅nH ₂o membrane electrode: measure 25 μ LV with pipettor ₂o ₅colloidal sol, spreads on the conducting surface of pretreated ITO electro-conductive glass sheet, and under room temperature after natural air drying, the vacuum tank being placed in 150 DEG C sinters 2 hours, naturally cools to room temperature, namely obtains V ₂o ₅nH ₂o membrane electrode.

As the V that Fig. 1 is prepared ₂o ₅nH ₂the electron-microscope scanning figure (SEM) of O film.As can be seen from the figure, V ₂o ₅nH ₂o film is made up of the netted fluff structure that aperture is larger, and hole disperses and comparatively evenly, this pattern makes film have larger specific area, is conducive to increasing the contact area between film and electrolyte, shortens lithium ion at V ₂o ₅nH ₂deintercalation path in O, accelerates the Charger transfer speed on electrode, just contributes to improving V ₂o ₅nH ₂the charging and discharging capacity of O membrane electrode and cyclical stability, thus improve its electro-chemical activity.

Embodiment 2

A kind of high power capacity V for lithium ion battery ₂o ₅nH ₂the preparation method of O membrane electrode is as follows:

(1) V is prepared ₂o ₅colloidal sol: get the hydrogen peroxide (H of appropriate 30% ₂o ₂) solution is placed in small beaker, then takes a certain amount of vanadic oxide (V ₂o ₅) powder puts into beaker, at room temperature slowly stir and make V ₂o ₅powder dissolves completely, and then add appropriate amount of deionized water and continue to be stirred to the stable rufous colloidal sol of formation, constant volume, obtaining concentration is 0.008mol/dm ³v ₂o ₅colloidal sol;

(2) preliminary treatment ITO substrate: pending ITO electro-conductive glass sheet is carried out supersound washing 15-30 minute with a small amount of ethanol, deionized water successively, and natural air drying is stand-by;

(3) V is prepared ₂o ₅nH ₂o membrane electrode: measure 25 μ LV with pipettor ₂o ₅colloidal sol, spreads on the conducting surface of pretreated ITO electro-conductive glass sheet, and under room temperature after natural air drying, the vacuum tank being placed in 150 DEG C sinters 2 hours, naturally cools to room temperature, namely obtains V ₂o ₅nH ₂o membrane electrode.

Employing three-electrode system is tested, V ₂o ₅nH ₂o membrane electrode is work electrode, and Ag/AgCl is as reference electrode, and Pt sheet, as to electrode, carries out cyclic voltammetric and constant current charge-discharge test.As the V that Fig. 2 is prepared ₂o ₅nH ₂the cyclic voltammetry curve of O membrane electrode, scanning voltage scope is-1.2 ~ 0.9Vvs.Ag/AgCl, sweeps speed for 0.01V/s.As can be seen from the figure, at V ₂o ₅nH ₂the cyclic voltammetry curve of O membrane electrode only has two to obvious redox peak, Li is described ⁺ion is at V ₂o ₅nH ₂embedding de-process on O membrane electrode is carried out in two steps, and do not exist can not anti-phase, is conducive to the performance improving lithium ion battery.V ₂o ₅nH ₂o membrane electrode is-0.25V and 0.16V place each appearance oxidation peak at voltage, correspond to Li ⁺ion is at V ₂o ₅nH ₂o membrane electrode deviates from process; Locate each appearance reduction peak at-0.46V and-0.15V, correspond to Li ⁺ion is at V ₂o ₅nH ₂telescopiny on O membrane electrode, and the potential difference at first pair of oxidation/reduction peak difference 0.21V, the potential difference difference 0.3V at second pair of oxidation/reduction peak, illustrates V ₂o ₅nH ₂o thin-film electrode material has good invertibity.

As the V that Fig. 3 is prepared ₂o ₅nH ₂the constant current charge-discharge curve of O membrane electrode.Charging and discharging currents density is 550mA/g, and voltage range is-1.2 ~ 0.9Vvs.Ag/AgCl.Upper as can be seen from figure, on discharge curve, there is obvious discharge voltage plateau.Its initial charge capacity, discharge capacity, irreversible capacity are respectively 219.39mAh/g, 232.83mAh/g, 13.44mAh/g.The specific discharge capacity of electrode is comparatively large, and irreversible capacity is lower, and this V is described ₂o ₅nH ₂o membrane electrode has good chemical property.

As the V that Fig. 4 is prepared ₂o ₅nH ₂the charging and discharging curve of O membrane electrode under different current density.As can be seen from the figure, when current density is 150mA/g, discharge capacity can reach 408.75mAh/g first.Along with the increase of charging and discharging currents density, V ₂o ₅nH ₂the discharge capacity of O membrane electrode declines to some extent.When current density increases to 550mA/g (increasing 2.2 times) by 250mA/g, but discharge capacity only reduces by 16.2% (reducing to 232.83mAh/g from 277.78) first, and namely discharge capacity slowly reduces with the increase of current density first, and this V is described ₂o ₅nH ₂o membrane electrode has good high rate performance.

Although along with the increase of discharge current density, V ₂o ₅nH ₂the discharge capacity first of O membrane electrode reduces to some extent, but after 5 circulations, attenuation rate obviously reduces, and each curve attenuation rate is followed successively by 8.56%, 4.09%, 2.90%, 2.20%, 0.70%, and this trend is different from other lithium ion anode material.This V is described ₂o ₅nH ₂o membrane electrode goes for the larger condition of work of current density.

Embodiment 3

A kind of high power capacity V for lithium ion battery ₂o ₅nH ₂the preparation method of O membrane electrode is as follows:

(1) V is prepared ₂o ₅colloidal sol: get the hydrogen peroxide (H of appropriate 30% ₂o ₂) solution is placed in small beaker, then takes a certain amount of vanadic oxide (V ₂o ₅) powder puts into beaker, at room temperature slowly stir and make V ₂o ₅powder dissolves completely, and then add appropriate amount of deionized water and continue to be stirred to the stable rufous colloidal sol of formation, constant volume, obtaining concentration is 0.008mol/dm ³v ₂o ₅colloidal sol;

(2) preliminary treatment ITO substrate: pending ITO electro-conductive glass sheet is carried out supersound washing 15-30 minute with a small amount of ethanol, deionized water successively, and natural air drying is stand-by;

(3) V is prepared ₂o ₅nH ₂o membrane electrode: measure 25 μ LV with pipettor ₂o ₅colloidal sol, spreads on the conducting surface of pretreated ITO electro-conductive glass sheet, and under room temperature after natural air drying, the vacuum tank being placed in 150 DEG C sinters 2 hours, naturally cools to room temperature, namely obtains V ₂o ₅nH ₂o membrane electrode.

Employing three-electrode system is tested, V ₂o ₅nH ₂o membrane electrode is work electrode, and Ag/AgCl is as reference electrode, and Pt sheet, as to electrode, carries out cyclic voltammetric and constant current charge-discharge test.

As the V that Fig. 5 is prepared ₂o ₅nH ₂o membrane electrode carries out repeatedly the capacity attenuation curve of charge and discharge cycles under the current density of 550mA/g.As can be seen from the figure, V ₂o ₅nH ₂the initial discharge specific capacity of O membrane electrode can reach 232.83mAh/g.Within front 40 cycles, the attenuation curve change of discharge capacity is very steady, and with in 71 ~ 104 weeks in 40 ~ 70 weeks, all there is the fluctuation that part is small in curve, but its discharge capacity is stabilized between 213.89 ~ 229.17mAh/g and 198.61 ~ 213.89mAh/g respectively.V ₂o ₅nH ₂the discharge capacity attenuation rate of the average each cycle of O membrane electrode is only 0.14%.In whole charge and discharge process, its irreversible capacity all remains on lower level, is about 15mAh/g.In a word, the V prepared by the present invention ₂o ₅nH ₂o membrane electrode, under high current density condition, also has higher specific discharge capacity and the cyclical stability of excellence.

As the V that Fig. 6 is prepared ₂o ₅nH ₂the cyclic voltammetry curve of O membrane electrode before and after constant current charge-discharge.Wherein, solid line represents electrode under the current density of 550mA/g, the cyclic voltammetry curve after the charge and discharge cycles in 104 cycles.From figure, V ₂o ₅nH ₂the cyclic voltammetry curve of O membrane electrode exists two to the obvious redox peak of separation, and peak area is larger.But after charge and discharge cycles, first oxidation peak on volt-ampere curve dies down, and second oxidation peak moves slightly to negative potential; And two reduction peak reduce except current value, do not observe other change.In a word, the change of two cyclic voltammetry curves is not remarkable, and this is consistent with the result that constant current charge-discharge is tested, and shows V prepared by the present invention ₂o ₅nH ₂o membrane electrode has excellent stable circulation performance.

Claims (1)

1. lithium ion battery V involved in the present invention ₂o ₅nH ₂o thin-film electrode material is prepared by the following method: (1) prepares V ₂o ₅colloidal sol: get the hydrogen peroxide (H of appropriate 30% ₂o ₂) solution is placed in small beaker, then takes a certain amount of vanadic oxide (V ₂o ₅) powder puts into beaker, at room temperature slowly stir and make V ₂o ₅powder dissolves completely, and then add appropriate amount of deionized water and continue to be stirred to the stable rufous colloidal sol of formation, constant volume, obtaining concentration is 0.008mol/dm ³v ₂o ₅colloidal sol; (2) preliminary treatment ITO substrate: pending ITO electro-conductive glass sheet is carried out supersound washing 15-30 minute with a small amount of ethanol, deionized water successively, and natural air drying is stand-by; (3) V is prepared ₂o ₅nH ₂o membrane electrode: measure 25 μ LV with pipettor ₂o ₅colloidal sol, spreads on the conducting surface of pretreated ITO electro-conductive glass sheet, and under room temperature after natural air drying, the vacuum tank being placed in 150 DEG C sinters 2 hours, naturally cools to room temperature, namely obtains V ₂o ₅nH ₂o membrane electrode.