CA3069652A1 - Electrochemical methods, devices and compositions - Google Patents
Electrochemical methods, devices and compositions Download PDFInfo
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Abstract
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] The Patent Cooperation Treaty (PCT) patent application claims priority to provisional application no. 62/361,650 titled "Electrochemical Methods, Devices and Compositions," filed on July 13, 2016, which is incorporated by reference herein.
TECHNICAL FIELD
BACKGROUND
SUMMARY
an electrode; an electrolyte in contact with the electrode and through which a first current between the source of countercharge and electrode flows; and a waveform generating device coupled with the electrode, the waveform generating device inducing an electric waveform across the electrode in the presence of the current.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 4B depicts electron distribution 450 among the electrons 420 on smooth areas 430 and rough areas 440 of the surface 111 of the first electrode 110.
depicts a process similar to FIG. 5A, where the void 500 is a high-aspect ratio feature in the first electrode 110. In FIG. 5C, a rough surface 111 of the first electrode 110 is filled. FIG. 5D is an inset of FIG. 5A
showing the formation of a new metal-metal bond 530 between a metal 540 in the electrolyte 140, and a metal edge 510 of the first edge 115 in the void 500.
8A) and at continuous acceleration (FIG. 8B), imparting a relativistic charge 112.
that is, it was a conventional electrodeposition. At FIG. 15B a second current of 1 MHz at 27 dbm (50 S2) was applied.
18B shows the same sample at x2000 magnification.
Overall, oxygen concentration was low (FIG. 37C and D), but the oxygen levels were slightly greater on the bottom region (FIG. 37B).
A vertical cross section of the sample was analyzed. FIG 38A shows the elements present. FIG.
38B was a composite of the iron, aluminum, and carbon signals, showing the codeposition of aluminum and iron at the surface of the steel substrate. FIGS. 38C-E are the two-dimensional elemental maps for iron, aluminum, and carbon, respectively.
and 39C are the two-dimensional elemental maps for aluminum and iron in the sample, respectively. FIG. 39D shows the elements present in the sample.
FIG. 40H shows an electron micrograph composite of the electron micrograph (FIG. 40A), and the two-dimensional elemental contents for iron (FIG. 40B), zinc (FIG. 40C), carbon (FIG. 40D), chlorine (FIG. 40E), and oxygen (FIG. 40F), showing the codeposition of zinc and iron to form the alloy. FIG. 40G shows the elemental distribution in the sample.
41B).
with copper following the disclosed method.
DETAILED DESCRIPTION
This compression and expansion generates a relativistic charge propagating outward from the electron's center at the speed of light. The relativistic charge then bends the field lines of the first current, directing metal from the electrolyte to form new metal-metal bonds in cracks and crevices, pits and voids, and high-aspect surface features on the workpiece.
Conventionally, problems arise at the boundaries between molded segments. The method disclosed here joins these molded segments with mechanically strong bonds.
The first electrode may be workpiece on which or to which some operation, such as depositing material, bonding, polishing, plating, or corrosion being performed, according to the techniques discussed.
The extent of metal bonding can be monitored in real-time, so the transverse current and first current can be modulated to continue metal bonding, electropolishing, or other electrochemical processes on the workpiece. This electrochemical process can also be run in reverse, where corrosion of the workpiece sends metal species into the electrolyte. From either embodiment, the present methods and devices represent a radical departure from conventional metal fusing techniques or previously known electrodeposition methods.
Gas compression is very inefficient and energy intensive, accounting for up to 10% of industrial electricity consumption. To avoid overheating, welding is limited to a single spot or multiple spots only if sufficiently spaced. Resistance welding also involves intense UV radiation, deadly voltages and currents, toxic fumes, noise, and flammability concerns.
So long as positive metal ions are abundant in solution to neutralize two adjacent negatively-charged edges, metal depositing at each edge may grow toward one another, even to electrical contact.
However, the growth of the two edges into each other does not form a bond between them. They may grow until the original surfaces abut each other, but the original gaps still exists as a weak fracture that prevents mechanical resilience.
Controls usually involve running the plating process at reduced current densities, using multiple, distributed anodes to shift the electric field density, and using organic additives.
I. Method
Referring to FIGS. 1 and 3, a workpiece 110 may be preprocessed (e.g., surface cleaning, roughening, etc.) (310), before inducing a first current (320) and inducing a second current (330), which may be an alternating or non-DC current across the workpiece. If the electrochemical process is incomplete (340), the first current and/or the second current may be modulated (350).
If the electrochemical process is complete (340), the process terminates (360). The completeness of a reaction can be assessed by any method known to one of skill in the art, including spectrometry and microscopy, as well as methods newly disclosed herein, which monitor deposition in real-time.
second current 150 is induced across the first electrode 110, the second current 150 being transverse to the first current 130, and the second current 150 inducing a relativistic charge 112 across a surface 111 of the first electrode 110. In some embodiments, the device includes a power supply 161 in electrical communication 161 with the source for a countercharge 120 and in electrical communication 162, 163 with the first electrode 110. The power supply, which may involve more than one physical power supplier, may provide and control the first current 130 and the second current 150.
A. First Electrode (e.g., Workpiece)
The first electrode is polarized with negative and positive charges when a current (for example, a first current or a transverse current) is applied, or when an electric or chemical potential is induced across the first electrode. The methods according to this disclosure manipulate electron density on the workpiece to guide metal deposition, and the like.
Due to electron distribution 450, electric field lines 135 terminate perpendicular to a tangent of the surface 111 and deviate from their original vector (137) to maintain this behavior at curves 440. The increased charge density at non-planar areas of the first electrode results in greater electrochemical activity relative to smooth areas. The distance A between electrons 420 in smooth regions 430 is greater than the distance B between electrons 420 in rugged regions 440.
Depositing metal species are redirected by the second current 150 and fill the junction 500 instead of immediately depositing on the surfaces 118, 119 of the first electrode 110 nearest to the source of a countercharge 120.
Angle 151 and arrow 611 would only modulate the electrodeposition current and do not display the disclosed effects related to treatment with a transverse current. Angle 152 and arrow 612 would promote some additional growth within the gap compared to a conventional electrodeposition, but not as much as angle 153 and arrow 613, which squarely targets growth within void 500. In practice, applying and propagating a second current is complex. The results depend on more than just the angle, but also on frequency, power, and other characteristics of the second current.
B. Electrolyte
In particular, the electrolyte may comprise a metal and one or more species selected from the group consisting of water, ammonium salts, metal chlorides, metal sulfates, ionic liquids, ionogels, and any combination thereof. When the electrolyte comprises an ammonium salt, the ammonium salt may be a tertiary ammonium salt, a quaternary ammonium salt, or combinations thereof.
1. Solvent
organic acids such as formic acid, acetic acid, and so forth; amines such as trimethylamine, or triethylamine, and the like; amides such as formamide, acetamide, and so forth; and combinations of the above.
Electrolyte having organic solvent may also display much larger electrochemical windows (2 V
to 6 V), compared to water (about 1.23 V). Organic solvents may also have greater operating temperature ranges above the 100 C limit for aqueous systems. Generally, organic solutions do not codepo sit with the metal during deposition. Organic solvents also allow deposition of more reactive metals, including pure Fe and Al. For at least these reasons, some electrolytes may comprise an organic solvent.
Generally, RTILs consist of a cation and an anion.
The cation may be 1-vinyl-3-ethyl-imidazolium ([VEIM]). The cation may be 1-allyl-3-methyl-imidazolium ([AMIM]). The cation may be 1-hexy1-3-butyl-imidazolium ([HBIM]), 1-viny1-3-methylimidazolium ([VMIM]). The cation may be 1-hydroxyundecany1-3-methylimidazolium (RCHOH)MIMD. The cation may be tetrabutylphosphonium ([P4444]). The cation may also be 1-(2,3-dihydroxypropy1)-alkyl imidazolium ([(dhp)MIM]).
For example, the anion may be triflate (OTO. The anion may be dicyanamide (DCA). The anion may be tricyanomethanide (TCM). The anion may be tetrafluoroborate (BF4). The anion may be hexafluorophosphate (PF6). The anion may be taurinate (Tau). The anion may be bis(trifluoromethane)sulfonimide (TFSI).
Exemplary RTILs are further illustrated below at Table 1.
Abbreviation Chemical Name Structure EMIC, 1-ethyl-3-methylimidazolium ,CH3 [EMIM][C1] chloride 4! \) CI
NN
L.C1-43 [EMIM][TSFI] 1-ethyl-3-methylimidazolium bis(trifluoromethane)sulfonimide Q, [VEIM][TSFI] 1-vinyl-3-ethyl-imidazolium N--\\
i; \) bis(trifluoromethane)sulfonimide O (,) 0 o 8 [HMIM][TSFI] 1-hexy1-3-methyl-imidazolium ce bis(trifluoromethane)sulfonimide (-_) 9 F3c+N-$--cF3 o 6 [AMIM][TSFI] 1-ally1-3-methyl-imidazolium bis(trifluoromethane)sulfonimide 9, 9, [HBIM][TSFI] 1-hexy1-3-butyl-imidazolium bis(trifluoromethane)sulfonimide 9 c) 9 [VMIM][TSFI] 1-viny1-3-methylimidazolium _ Nsok bis(trifluoromethane)sulfonimide O G., 0 [(CHOH)MIM[[ 1-hydroxyundecany1-3- HO-TSFI] methylimidazolium bis(trifluoromethane)sulfonimide o 0 -F3c-s-N-s-cF3 [EMIM][TCM] 1-ethy1-3-methylimidazolium HO
tricyanomethanide [P4444] [Tau] tetrabutylphosphonium taurinate /
0, ,8-' ,:S, '0 [EMIM] [DCA] 1-ethyl-3 -methylimidazolium ---\ ___ N--,\
.0%
dicyanamide 'N
I
r--) N:C N C:N
[DMIM] [Tf2N] 1-(2,3-dihydroxypropy1)-3- HO¨\
\
or methylimidazolium HO2 N
=1 [DEIM] [Tf2N] bis(trifluoromethanesulfonimide) N
I
or F3c-1-(2,3-dihydroxypropy1)-3- II II
s-N-s-cF3 ethylimidazolium bis(trifluoromethanesulfonimide) [DMIM] [BF4] 1-(2,3-dihydroxypropy1)-3- HO \
\
or methylimidazolium HO) N
[DEIM] [BF4] tetrafluoroborate N
Fl 0 I
or F-B-F
1-(2,3-dihydroxypropy1)-3- F
ethylimidazolium tetrafluoroborate [DMIM] [DCA] 1-(2,3-dihydroxypropy1)-3- HO¨
\
or methylimidazolium dicyanamide HO N
[DEIM] [DCA] or N
I
1-(2,3-dihydroxypropy1)-3-ethylimidazolium dicyanamide NEC-N-CEN
[DMIM][PF6] 1-(2,3-dihydroxypropy1)-3- HO
\
or methylimidazolium HO' N¨
' \\
[DEIM] [PF6] hexafluoropho sphate NN
F I
or F, 1, F
P, 1-(2,3-dihydroxypropy1)-3- F ,1 F
F
ethylimidazolium hexafluoropho sphate
In another example, the electrolyte may only contain a trace amount of water, such as that absorbed from the atmosphere. That is, the electrolyte may be substantially non-aqueous.
and about 50 C, between about 50 C and about 60 C, between about 60 C and about 70 C, between about 70 C and about 80 C, between about 80 C and about 90 C, between about 90 C
and about 100 C, between about 100 C and about 110 C, between about 110 C and about 120 C, between about 120 C and about 130 C, between about 130 C and about 140 C, between about 140 C
and about 150 C, between about 150 C and about 160 C, between about 160 C
and about 170 C, between about 170 C and about 180 C, between about 180 C and about 190 C, between about 190 C and about 200 C, between about 200 C and about 210 C, between about 210 C
and about 220 C, between about 220 C and about 230 C, between about 230 C
and about 240 C, between about 240 C and about 250 C, between about 250 C and about 260 C, between about 260 C and about 270 C, between about 270 C and about 280 C, between about 280 C
and about 290 C, or between about 290 C and about 300 C.
Different metals and composites typically have pH requirements to maintain a stable mixture in solution. The wetting characteristics of surfactant maintain its presence at the first electrode/electrolyte interface. Therefore, the surfactant may also buffer against the dramatic pH
gradients that occur between the interface and the electrolyte bulk due to proton consumption and metal hydroxide precipitation on the substrate.
In water, about 11%
speed of light with dielectric of about 80. RTILs have a dielectric constant of about 40, and air a constant of about 1.
2. Metal
bronze (copper-tin), tin-zinc, tin-nickel, and tin-cobalt.
Deposition of metal particles of a desired composition, crystallinity and crystal structure may provide same or substantially similar properties to the deposited material on the first electrode with less dependence upon specific deposition parameters. Each metal particle brings millions of preformed metal bonds, resulting in proportionality less energy needed from the first current to complete the bonding deposit compared to conventional electrodeposition. The particle volume also dramatically accelerates the bonding deposition rate. At least for these reasons, particle codeposition improves the time and energy efficiency of the methods disclosed herein.
Without wishing to be bound by theory, when metal particles electrically contact the first electrode, dissolved metal species also deposit on and around the metal particle in brick-and-mortar fashion until the metal particle is completely occluded. Before occlusion, however, the metal particle itself does not chemically bond to the first electrode unless its surface atoms are in a reducible state. As such, depositing molecular species push away the metal particles from the surface instead of becoming occluded. Metal particles that occlude may have trapped electrolyte between them and the surface. This porosity is detrimental to the mechanical integrity of the deposit. Conventional electrodeposition rarely occludes over 10 vol% metal particles.
Ceramic or polymer particles may be codepo sited with metal particles to obtain deposit properties outside the range or alterability of a base metal alone.
3. Additives
In particular, the electrolyte may comprise thickener to modulate the viscosity and increase the mass of particulates stably suspended in the liquid electrolyte.
Alternatively, the ionic sulfate headgroup of SDS may be replaced with sulfamate to achieve this effect without increasing alkali content.
Surfactants may also brighten by inhibiting the buildup of more oxidized species such as Fe+3, removing the need for post-treatments normally required to provide a polished surface.
and about 104 mol/L, or between about 104 mol/L and about 10-5 mol/L.
C. Source of a Countercharge
Suitable soluble electrodes include, but are not limited to, Fe, Al, Cu, or any other electrically conductive metal, including alloys and composites. Electrodes may be interchangeable to facilitate routine replacement and maintenance and reconfiguration. Although presented here in the source of a countercharge, non-corroding electrodes may also be electrodes in other capacities, including cathodes and reference electrodes.
Referring to FIG. 1B, a corroding electrode is depicted as a possible source of a countercharge.
When the first current 130 is induced between the corroding electrode 120 and the first electrode 110 through the electrolyte 140, metal 122 from the corroding electrode 120 is released as metal species (Mt) 124 into the electrolyte 140. Additional metal can be in the electrolyte when the electrode is corroding, for example from metal salts dissolved in the electrolyte. In other instances, the only metal source is from metal species released from the corroding electrode.
Dissolving the corroding electrode releases new metal into the electrolyte, maintaining its concentration through the duration of the method. The metal-carrying capacity of the electrolyte becomes less important because fresh metal can be supplied from dissolution of the corroding electrode. Metal precursors are supplied from the controlled corrosion of a formulated source of a countercharge into the electrolyte near the first electrode.
In some instances metal and/or composite powder may be mixed in a vial, added to the inside a die in a hydraulic press, pressed together, and removed as a metal pellet for use an as a corroding anode.
During deposition, corrosion of the source of a countercharge may occur primarily along the grain boundaries of the pressed particles when higher current densities are used, causing their release into solution with their approximately original dimensions. Particles dissolved in this way are surface activated and exhibit a higher solubility in the electrolyte than particles simply mixed into solution. Particles with a surrounding layer of metal-species which is electroactive for deposition, such as Al4C17 in 1-ethyl-3-methylimidazolium chloride (EMIC), are more readily codeposited.
Metal particle size may be small enough to remain suspended in the electrolyte and avoid the effects of gravity or control the impact of grain size on the properties of the deposit. Larger grains result in a harder metal from a slower process. Smaller grains yield softer metal with more ductility from a faster deposition. The larger the discrepancy at the grain boundary defines points of failure.
Spherical particles with uniform surface energy may codepo sit such that the overall finish of the deposit is more predictable and easy to control. Elongated particles may align themselves with the electric or magnetic fields of second current and encourage directional growth, bridging a gap between two first electrodes more rapidly.
D. First Current (Electric Field)
The first current polarizes the workpiece so that it possesses a net negative charge. This negative charge effects a charge transfer reaction with dissolved and suspended metal ions and particles from the electrolyte to effect new metal-metal bonds with metals on the surface of the workpiece.
Shorter pulses of polarization allows these metal species to equilibrate during the electrochemical process.
and about 1.5 V, or between about -1.5 V and about 0.7 V. These pulses may be generated from an electroplating power supply, which may be power supply 160, or a reverse pulse rectifier used to generate a DC current for electrochemical processes.
E. Second (Transverse)Current (Induced Potential)
The difference between a point of deposition under the induced potential and a point of deposition without the induced potential is a shift of the field lines toward crevices and rough areas of the surface not normally filled.
grain properties, such as crystallinity and morphology; induced nucleation on energetically difficult surfaces; reduced porosity in the metal; adhesion onto the substrate; and controlled linear crystalline growth. Therefore, the properties of the deposited metal can be changed without heat, pressure, or modifying the system's components or normal deposition parameters.
The second current 150 effects a relativistic change 112, causing electrons 420 to move across the surface 111 in the directions 700A, 700B of the imposed electric field. When the second current (VTc ) is positive, electrons 420 accelerate toward the right (700A), and when VTC is negative, electrons accelerate toward the left 700B). This shuffling of the positions of electrons 420 at the surface 111 changes the electron distribution, and therefore, the localized charge density. When the waveform of VT
approaches 0, electrons may be bunched together or pushed apart farther than normal. In the former, a smooth point 430 on the surface 111 may experience the charge density normally seen at points with greater curvature 440. Similarly, the charge density at curved points 440 may be reduced from their normal values.
As shown in FIG. 8A, electrons 420 moving at constant velocity maintain uniform spacing and constant electric field vectors. A DC offset second current 150 applied to the first electrode 110 causes a net flow of electrons at a constant velocity in the bulk and surface of the first electrode 110 inducing a magnetic field at all depths. The bulk fields cancel, while surface fields propagate outside the conductor. Consequently, a DC offset second current only weakly impacts the electric field lines 150 from cathodic polarization of the first electrode 110 under the first circuit 130.
Y =2 (Equation 1) ,11-2 where y is the contraction constant, v is the velocity of the electron, and c is the speed of light (3 x 108 m/s). Here, the electron velocity is non-relativistic, so the degree of this effect is small.
offset can be much greater without damaging the electrolyte, because the current can complete a circuit without depending entirely upon charge pass through the electrolyte. The electrical contact need not be within the area targeted for deposition, and the DC offsets can be much more than +/- 6 V, including up to +/- 200 V. Gap geometry may also affect the limits of the DC
offset.
offset leads to transverse growth inside the void, and also to the formation of metal-metal bonds within the gap. When the overpotential of deposition is greater, adhesion is often improved. In general, ETC can be much greater than EED, if the workpieces being joined already have some point of electrical contact. ETC is the electric field of transverse current from the transverse current signal source. EED is the electric field of the electrodeposition signal source. Greater overpotential can also increase grain size of the deposition metal, which can harm adhesion, depending on the system.
The double layer barrier between the metal particle and the surface of the first electrode is reduced. The electric field also imparts an electrokinetic velocity tangential to the surface, which causes parallel wobbling as the particle approaches the surface perpendicularly. Both mechanisms reduce the porosity of deposits created with particle occlusion following the methods described herein.
F. Waveform
Several waveforms may also be combined to define the second current. Different waveforms have different effects on the surface, even when superimposed as a multi-waveform.
"Relative power" describes how different waveforms of identical peak voltage deliver power across the electrode surface. In electrochemical processes, voltage may be treated as a constraint instead of a power, because potential is thermodynamically significant to the reaction, while power relates to time and surface area.
(See Example 8).
Non-symmetric reflections result in signal differences, allowing one to use roughness like a fingerprint to uniquely identify a sample. The waveform flows through the gap, as an electric field or as a magnetic field. The pattern can become complex. Because of the offset, the compound difference between the waveforms of the points of contact can amplify the current experienced in the gap beyond the energy. As the roughness changes, the distribution of energy also changes.
If the roughness becomes smooth, the distribution of energy across the surface becomes more uniform. This change is topography can be measured with a reflection or transmission-type impedance.
The magnitude of the electric current fluctuates logarithmically. See FIGS. 7 and 8. The dissolved metal atoms follow the electric field. The magnitude and polarity result from the differences in the offset. The current density (V/m) increases as the gap closes.
Here, strong vectors are felt at the surface. Some first current vectors move parallel to the surface, allowing corrosion during deposition. Microscopic analysis of deposited material showed globular pockets of amorphous rather than crystalline deposition.
See Example 8 and FIG. 22. When the deposited material was rough, the energy was not presented to the surface in a way that would promote smooth deposition. Thus, the waveform of the second current was too simple, and needed to be modulated so that the deposited material is smooth instead of rough. In various embodiments, the second current (or induced potential) may have a period similar to a diffusion rate of a component in the electrolyte.
This material-dependent speed, called "drift velocity," vp, is between about mm/s and about m/s:
vE, = ¨n*A*Q (Equation 2) where I is current (amperes), n is the volumetric charge carrier density in the medium (e7m3), A
is the area of flux (m2), and Q is the charge of the carrier (1.6 x 10-19 C/e-). An electron at a constant velocity has its electric field contracted tangential to the surface of the first electrode, and has its field expanded perpendicular to the surface, per the Lienard generalization. The distortion is negligible if v<<c, as for vp.
vp = 7, (Equation 3) where k is the dielectric constant of the material in the electrolyte. Since charges move on the surface of the first electrode and not within its bulk, the signal propagation produced by second current moves along the first electrode-electrolyte interface. The dielectric constant of the electrolyte also affects the velocity of propagation. For example, water has a dielectric constant of 80.4; Vp is still 3.35 x 107 m/s, dramatically faster than mass transport through the electrolyte.
1,0,(22, a2 re - (Equation 4) 6*Ir*c where 110 is the permeability of free space (47c x 10-7 N/A2) and a is the charge acceleration, a reasonable approximation when drift speed is much slower than the speed of light.
Er = ____________ (Equation 5A) and E0 = q * a * sin(0) (Equation 5B) 4*Ir*80*r2 4*r*8er*c2 where Er is the electric field radial in all directions to the point charge, E0 is the electric field which is perpendicular to Er, and co is the permittivity of free space (8.85 x 10-12 C2/Nm2). E0 is unique to charges under acceleration and is responsible for the effects of second current on the electrodeposition. E0 is negligible for charged particles at non-relativistic velocity and no acceleration.
PTC = -2* npeak *I'peakl = Prad Pohm (Equation 6) where Rpeak and 'peak are the peak resistance and current of the waveform, respectively. P.m can be divided into radiated power rad, (P land power dissipated due to ohmic losses (Pohm).
\--
SD = _\17:1*Ii*0- (Equation 7) where f is the frequency, 11 is the permeability of the electrode, and a is its conductivity. SD
describes the approximate depth from the surface of the first electrode, at which PD = Ppc/e. The AC second current, especially at higher frequencies above 1 GHz, more efficiently uses the second current power.
YRMS = y * (1 + (-2) * tan-1 1.4* (RRMS)2- (Equation 8) where YRms is the modified attenuation constant of the electrode due to roughness, Y is the original attenuation constant of the material, and RRms is the RMS roughness.
This relationship under Hammerstad model demonstrates increased attenuation from roughness by unity for the smoothest surfaces and by double for the roughest surfaces. Power dissipation results from micro-field formation between roughness features, and can be absorbed by interfacial electrochemical processes. See also Example 9. With the appropriate waveform, fields from the second current affect the first, secondary, and tertiary electric fields at curvature. The secondary and tertiary electric field cause convective charge transfers. The frequency of the second current may be determined based upon the skin depth of the applied power. Generally, the transverse current causes a more uniform micro-current and macro-current distribution.
RNF 0.62 * ¨ (Equation 9) ATC
where D is the maximum dimension of the electrochemically active first electrode or the distance between the electrodes applying second current, and X,Tc is the wavelength of the second current.
This region is the reactive near field and within it, E0 and Er are in-phase with the magnetic field of the EMR. As energy interchanges between E4 and I-14 every quarter period, the electric fields exhibit capacitive behavior, while the magnetic field exhibits inductive behavior. Within the near field region, electrochemical polarization field lines and any ionic species in the electrolyte reacting with them are subject to these frequency-dependent capacitive and inductive fields.
At high frequencies even sinusoidal features may appear asymptotic.
The second current power is stronger at rough and/or asymmetrical areas due to less cancellation, having a localized effect on simultaneously occurring electrodeposition. Once deposited material has filled in the abrasion and restored symmetry to the first electrode, the second current power self-cancels. If cancellation increases substantially before surface imperfections have been removed, a larger phase offset may be applied. A benefit of using superimposed signal cancellation reduces the far-field radiating power from the first electrode, compared to a single second current with large power and a complex waveform.
Likewise, slower AC
frequency does not affect processes which occur over drastically faster periods. Second current frequencies of about Hz and about kHz can affect ionic displacement reactions, such as ionic reactants in the electrolyte. Faster frequencies may alter the cathodic polarization field lines at about the vp, but the reactants move too slowly to respond to those changes simultaneously and will instead respond with some probability, similar to aliasing within telecommunications and computing. Frequencies between about kHz and about MHz are timed to the rotational moment of polar molecules. Above about 100 MHz, many aqueous electrolytes cease to conduct and instead behave capacitively. Arbitrary waveforms, such as superimposing a high frequency waveform over a lower one, balance these effects. Such waveforms can be defined by variables modified during an electrochemical process in response to changes in the system (feedback loop). For example, an adequately enabled oscilloscope may monitor the second current to observe phenomena or gradual changes during an electrochemical process to troubleshoot, refine signals, or give sensory feedback (phase shift, attenuation, etc.).
G. Applications of the Method
1. Corrosion Processes
While ICCP
reduces corrosion, its effectiveness is limited by the placement of nearby anodes. The overall effectiveness of ICCP could be enhanced by a method that better distributed charge across a vulnerable surface. Alternatively, in situations when anodes cannot be placed appropriately, a transverse current can be more effective.
2. Electropolishing
Advantageously, rough areas corrode faster than smooth. Because conventional electroplating produces unwanted roughness, electropolishing is often used after conventional electroplating to remove accumulated roughness and provide a smooth finish. Electropolishing current densities are usually low and/or pulsed. This maintains a smooth finish at the expense of overall process time. When higher current density is applied, corrosion occurs more rapidly along grain boundaries of the metal, causing chunks of metal to detach from the bulk of the surface and increasing surface roughness.
component using the methods disclosed herein. The goal is to maintain oscillation in the y-direction while controlling or minimizing fluctuations in the z-direction by swinging and changing the magnitude of the vectors. In this way, a flattening of surface features is promoted without vertically building features, as seen in conventional processes. The deposition current is modulated relative to the transverse current to ensure the overall electric field strength relative to the workpiece surface is constant, while the parallel field strength may wander. The first and second currents may be coordinated together so weak and strong field complement. The deposition and transverse currents may pass through the same electrical junction. The total electrode signal may look like pulse plating, but that does not account for the different signals put into the workpiece to generate the disclosed effect. See Example 9.
Higher current densities may be run while avoiding the surface corrosion in chunks and along grain boundaries. Electropolishing yields a nearly smooth surface by corroding away the edges and rough features without the spalling seen in prior art methods. A DC field may be applied in the opposite direction of the electric field needed to promote electrodeposition In other words, if the DC field that promotes deposition is negatively polarized relative to the workpiece, then reversing the polarity of that DC field promotes corrosion, thus electropolishing the workpiece.
With the methods disclosed herein, electropolishing may be accelerated.
offset. A set of deposition electrodes may be arranged on the backside of the workpiece. In a conventional electrodeposition, most of the metal is laid down on the edges facing the void space of the gap.
The thinnest amount of material is deposited in the center of the gap, resulting is a poor junction Using the disclosed process, the opposite effect prevails, wherecorrosion is preferred at the edges but deposition is preferred in the gap. Metal fills in the entire void space.
3. Batteries
Further, as the electrodes become thinner, a larger ohmic drop occurs across the surface leading to less uniform charge density during charge/discharge cycles.
Problems arise if the Li + ions try to deposit atop more Li + and 3D deposits of Li form. Li aggregation creates an explosion hazard and causes roughness. Specifically, if the Li reaches the opposite electrode, the battery may short and the dendrites formed during the Li deposition may damage the membrane dividing the two half-cells of the battery.
Lithium-metal batteries (Li-foil anode) and lithium-ion batteries (Li-ions intercalated into a graphite/foil anode, where the foil is frequently copper) both suffer from the growth of lithium dendrites during the battery's charging cycles. While Li-ion anodes can be stable for hundreds of cycles, dendrites develop immediately in Li-metal. Once formed, the dendrites lower the columbic efficiency of the battery, damage the ion membrane, and short the battery if the dendrites contact the anode. Commonly dendrites form which puncture or irreversibly damage the electrolyte membrane. If dendritic growth reaches the opposing electrode, then the battery is permanently shorted and cannot be recovered.
Transverse current can enforce a uniform current distribution across the entire surface, more evenly distribute Li concentrations throughout the solid electrolyte interphase, and maintain an anode/electrolyte interface with uniform electrical behavior.
And the rate of recharge could be increased without compromising the lifetime of the battery as with conventional batteries.
II. Device
1020 contains a power supply 160 and a power modulator 165, which induce a first current 130 between the source of a countercharge 120 and the first electrode 110 through the electrolyte 140. The MCU
1020 also supplies power to induce a second current 150 through a surface 111 of the workpiece 110. The electrode applicator unit 1010 contains at least one source of a countercharge 120 and a plurality of channels 145 for flowing an electrolyte 140 through the electrode applicator unit 1010. The electrode applicator unit 1010 is connected to the main control unit 1020 through a current collector cable 161 connected to the main control unit 1020 and a power control unit 1030 connected to the main control unit 1020. The power control unit 1030 applies a first current 130 between a first electrode 110 and the at least one source of a countercharge 120 through the electrolyte 140. The power control unit 1030 may also induce a second current 150 across the first electrode 110. As described elsewhere herein, the second current 150 is transverse to the first current 130, and may be controlled to induce a relativistic charge across the first electrode 110.
The electrolyte 140 may act as a linear resistor. The father the source of countercharge 120 is held from the surface 111 of the workpiece 110, the more resistance passing charge through the electrolyte 140, and the less current density at the workpiece 110. In other instances, the process may be run through a controlled current mode at the power control unit 1030, in which the bonding system 1000 increases the voltage to maintain the selected current density at the surface 111 of the workpiece 100 when the applicator 1010 is moved.
The applicator 1010 may have an integrated heating 146 and/or cooling unit 147, or more generally a temperature control unit, which control the temperature of the electrolyte 140 within. The applicator 1010 and the MCU 1020 may be connected by wiring 161 for power and sensors, and tubing 169 that allows fluid to flow from one to the other.
pump 168, depending the configuration, may be positioned to drive or otherwise pump electrolyte 140 from the tank 167 through the tubing 169 to circulate electrolyte 140 for distribution on the workpiece where desired. In such a configuration, the electrolyte 140 may be dispensed through the applicator 1010.
A. Main Control Unit
Computer control may be used for the broadest range of materials, sensory feedback, data recording, and complex deposition conditions.
Current-controlled power may achieve a current density (A/cm2), and so a desired mass flux from metal of the electrolyte onto the surface of the first electrode.
Potential-controlled power may achieve a redox state of substrate atoms at the first electrode/electrolyte interface. For example, a slightly negative potential could be applied to the first electrode to ensure a metallic state of the surface atoms and to prepare the surface for adhesion. Potential control of positive polarity at the first electrode may corrode the surface of the first electrode. For example, the MCU 1020 could effect a potential equal to or greater than 0.8 V but below 1.6 V vs. a standard hydrogen electrode (SHE) to corrode a steel surface without corrosively pitting. This would be useful for increasing the penetration depth of deposited layers on the surface of the first electrode without causing significant roughening. Potential control may also control the stoichiometry of deposited alloys or composites via potentials of the first current of based on the metal from the electrolyte.
vs. Fe/Fe + for 2 s.
The first potential surpasses the activation energy for Fe to deposit, but is insufficient to drive Mn deposition. The second potential exceeds the activation energy of Mn formation and so both species electrodeposit simultaneously. The overpotential (that is, the potential applied in excess of the activation energy) impacts the relative deposition rate of each species. Other alloys may be used by changing the metal species and selecting the appropriate voltage, as taught herein. See the FeZn alloy at Example 13.
AC can be applied by the MCU 1020 to obtain resistance/impedance measurements.
For example, the MCU 1020 can rapidly apply an AC of 1-100 mV and a frequency less than or about 100 kHz to measure the linear impedance response and obtain feedback about the bulk conductivity of the first circuit. If a reference electrode 148 is present in the applicator 1020, additional lower frequencies can monitor the first electrode/electrolyte interface.
potential of the preceding pulse of the first current 130 to measure system impedance. The measurement time would depend on the frequency and the number of wave periods recorded and the processing time for the computer to analyze the recorded signal against the applied waveform (-10-50 [I s total). If impedance has increased relative to the last data point collected, the computer 164 may determine whether this increase correlates with an expected gradual loss in ionic conductivity of the electrolyte with use and time. If so, the current/potential magnitude of later pulses may be increased to overcome the additional ionic resistance of the electrolyte 140.
The entire sequence may be repeated using updated parameters. If not, then the measures impedance/capacitance at one or two lower frequencies to probe the condition of the surface. And immediately after the user turns on the power, and again immediately after power is turned off, the MCU 1020 may measure the OCP of the system to estimate the redox state of the first electrode surface 111.
B. Applicator
Electrode 1130 may be a parallel source of a countercharge to modify or stabilize the total first current without changing the potential through the source of a countercharge 1120. In this way co-deposition may be controlled independently of the overall deposition process.
Electrode 1130 may be a single surface, or multiple surfaces with directional control. Electrolyte may be circulated through the system via one or multiple, opposing channels 1140, 1145. The applicator 1100 may contain one or more channels 1150, 1155 for fresh and depleted electrolyte.
Secondarily, the area and geometry of the tip 1160 may exploit surface tension of the electrolyte to influence fluid from draining from the aperture when the tip volume is full. The tip 1660 or applicator 1100 body may contain an agitator for the electrolyte, including higher frequency ultrasonic transducers, low frequency vibrators, or any related mechanism. The tip may be designed for directional use. A scoop-like tip may use sheering force of the first electrode surface to push electrolyte back into the applicator as the tip is guided across the surface of the first electrode.
The dielectric mesh may be a metal mesh, a metal mesh in a polymer, or a dielectric polymer mesh. When present, a metal inner later provides a conductive surface for capacitive coupling of the radio frequency originating from the workpiece. The metal inner layer is also an effective ground plane, while the polymer outer layer protects the metal inner layer from depositing or corroding.
With these reference electrodes, fast potential measurements may be recorded while the surface state of the RE is relatively stable. Polarization of the RE over longer time domains would allow the measured feedback potential to drift as the RE1 surface conditions become more transient. To obtain feedback over longer periods, an RE2 should maintain a steady-state potential while continuously polarized in solution. An example RE2 would be Ag/AgCl.
In various embodiments, this back layer may be a corroding or non-corroding electrode, which provides a source of a countercharge 120. The remaining volume of the inset may be filled with electrolyte 140. The electrolyte 140 may be of high viscosity, such as a gel, or be of low viscosity within a sponge or porous membrane. Any electrolyte described herein may be used.
The perimeter of active area 1220 may have a contiguous seal made of silicone, latex, or similar material. This seal, when present, may isolate the electrolyte 140 from auxiliary contact pads 1230, 1235, which provide electrical contact with the first electrode 110.
Each circuit may be powered by wires 1340, 1342, 1343 leading to a junction or gap 1350, which is connected to a wire 1360 leading to a power supply/control unit, or an onboard battery/control system. The user can articulate the first electrode holder 1320 to control the area of deposition while changing the relative positions of the sources of countercharge 1330, 1335 to control the vector of second current. Other digits or multiple gloves may be used.
III. Software
These connections may load sensor data logs to a computer readable medium. The connections may facilitate computer control during operation of the method, live remote monitoring, and communication between multiple MCUs. The connections may receive software updates, including operating parameters and models for different substrate materials and electrolytes. For example, party A may create a electrolyte with special operating parameters and create a computer model that can be loaded onto the MCUs for other users.
IV. Metal deposits
Rather, the atoms slide around until they hit new layers, promoting layer-by-layer growth. The methods described herein are not just top-down deposition of new material but promote self-leveling atoms.
Carbon-fiber is minimally conductive, but can be directly metallized with the methods described herein. Other fabrics, such as KevlarTM, may be treated before metallization by impregnating with metal ions.
Any woven material is suitable. For example, a cotton cloth may be impregnated with NiC12 overnight. Fabrics may be straight, stiff, and/or distribute stress forces.
Generally, metallization replaces conventional epoxy treatment.
Conventional body armor requires instead of the conventional 7 to 9 layers of Kevlar to meet ballistics requirements. Even while accounting for the added weight of the metallization, the new body armor is thinner and lighter, allowing longer durations of comfortable wear.
To armor vehicles, the Kevlar may be shaped into panels and metalized to form the body of the vehicle. Again, like body armor, the vehicle paneling is thinner and lighter while providing equivalent protection from projectiles and other weapons.
EXAMPLES
0 Average diffusion layer thickness of reactive species in electrolyte A Area of flux (m2) AC Alternating current c Speed of light (3 x 108 m/s) CA Corroding Source of a countercharge D Longest EMR-active dimension of an electrode (m) DC Direct current E 4 Electric field vector Electric field induced by an electrodeposition between a source of a countercharge EED
and a first electrode (V/m) EMIC 1-Ethyl-3-methylimidazolium chloride EMR Electromagnetic radiation Er Electric field radial to a point charge ETC Electric field induced by second current (V/m) E0 Electric field perpendicular to Er co Permittivity of free space (8.85 x 10-12 c2/Nm2) f Frequency FDP Dielectrophoretic force FEP Electrophoretic force IV Magnetic field vector Hsine Amplitude of a sinusoidal profile use to approximate surface roughness I Current (amperes) i(x) Current at point x on the electrode surface iave Average current density along a rough surface ix Current density at the highest features of roughness iL Current density at the lowest features of roughness 'peak Peak current IPP Peak to peak current of a waveform IRms RMS Current k Dielectric constant of a material k 27clk MCU Main Control Unit n Volumetric charge carrier density (e-/m3) OCP Open circuit potential PCU Power Control Unit PD Power at a depth, D, from the electrode surface Pe- Radiative power of a non-relativistic, accelerating electron Pain, Power dissipated by ohmic losses Prad Radiated power PTC Applied power of second current Q Charge of an electron (1.6 10-19 C/e-) RCT Charge transfer resistance of an electrochemical reaction RE Reference Electrode RNF Distance of the reactive near field from an electrode surface Rpeak Peak resistance RRms RMS roughness of an electrode surface Rs Solution (electrolyte) resistance RTIL Room Temperature ionic liquid SD Skin depth SHE Standard Hydrogen Electrode TC Second current v Velocity of charged particle V Voltage VD Drift velocity of a charged particle vp Velocity of propagation Vpeak Maximum voltage of a waveform Vpp Peak to peak voltage of a waveform VRMS RMS Voltage VTC Voltage of second current Y Material attenuation constant of second current YRMS Attenuation constant of second current due to surface roughness a Charge acceleration 7 Lienard electric field contraction constant Wavelength kTC Wavelength of second current Permeability of electrode [to Permeability of free space (47c x 10-7 N/A2) Example 1 - Smoothness and Uniformity Through Controlled Charge Distribution
second lead attachment 1415 was on a second side 1421 of the slots 1450 Slots 1450 functioned as voids in the workpiece, so that current flow was blocked with a potential drop on either side of the slot 1450.
14A, but this time with the second current applied across the workpiece, with the attributes of the current as introduced immediately above.
resulted from kinetic roughening and occurred when the nucleation rate was high relative to the actual growth rate. At longer deposition periods, these edges propagated faster than the voids were filled, leading to more dendritic morphology.
Applying a second current instead provided a simple means to reduce reliance on or avoid these conventional practices. The uniform distribution of charge afforded by second current reduced the disproportionate growth normally observed at edges and points.
Consequently, the uniformity of growth became less dependent upon the relative position of an anode.
16. During Period A, the pulses alternated between neutral and corrosion-inducing potentials.
Corrosion at >100 mA/cm2 encouraged the release of bulk pieces of the substrate via corrosion along grain boundaries. The pulses had a defined pulse length of uniform or non-uniform duty cycle and a DC offset indicated by the dashed line. Once the surface was roughened during Period A, the DC offset was transitioned to more a reducing potential over Period B, so the ratio of reducing to oxidizing current slowly increased. During Period C, the pulses were entirely neutral or reducing. The final magnitude of the reducing pulse equaled that at which deposition current was maintained thereafter.
Conventional pulse deposition or reverse-pulse deposition methods are not sufficient to remove the passivation layers on more reaction metals like Fe, Al and Ti. For example, on a passivated nickel surface, the passivation layer comprised a mixture of nickel oxide and nickel hydroxide atop the outer metallic boundary. Charges must transverse this layer through each oxidation state before reducing completely. In contrast, deposition onto non-passivating surfaces such as Au went by comparatively simple adsorption and charge transfer steps.
Example 2¨ Surface Repair
17J) are apparent from pliers used to straighten the workpiece after shearing The first electrode, in this case the sheared copper sample, is viewed from the perspective of the source for a countercharge through the electrolyte (one-half saturation CuSO4(aq) at ambient temperature).
To roughen the surface for demonstration of crack filling, the copper workpiece (first electrode) was exposed to a 100 mA first current for several minutes (FIG. 17B). At this high current density, the metal from the first electrode primarily corroded in small chunks, starting at the outer edges of the first electrode. After several minutes, the surface of the first electrode was substantially rough (FIG. 17C). This roughening was much more than needed to remove surface oxides and promote adhesion of deposited metal, but the extreme roughness provided a useful visual of the effects of the second current.
Two-dimensional growth dominated despite a perpendicular positioning of the source of a countercharge to the surface of the workpiece as shown in the sequence of images from FIG.
17D to 171. Normal charge density at edges of roughness was avoided. Instead, the horizontal imprints 1520 were filled in, which is also shown in the sequence until they disappear after having been filled as shown in FIGS. 17K and 17L. As processing progressed, the original smooth surface was restored resulting a relatively smooth workpiece with the shear filled as well as the imprints (FIGS. 17J-17 L). As most of the surface of the first electrode 1700 was restored, remaining valleys had a planar bottom and growth proceeded vertically until the valley was filled in with new metal-metal bonds formed between metal from the electrolyte and the metal of the walls of the valleys.
This example was performed with simple sinusoidal waves at a fixed voltage, frequency, and phase offset. Had parameter settings been dynamic and able to adapt to the changing surface over time, as with sensory feedback, the surface features of the first electrode may be filled and smoothened simultaneously. Other factors that may effect the deposition and bonding are the position of the leads inducing the current across the workpiece, as well as the position of the source of countercharge relative to the workpiece, among other factors.
Example 3 - Second Current Controlled Adhesion
and 18B are electron micrographs of a workpiece showing corrosion-based surface roughening caused by the transverse current. In particular, a relatively high voltage of 7 kV at 34 kHz, limited to 30 mA, induced significant surface roughening in less than 5 seconds. The surface had the passivation layer removed along with some metal from the workpiece. The process may be influenced toward finer removal of material, or the process may increase corrosion using a first current between the workpiece and a source for a countercharge, or by modulating the second current to higher frequencies or higher powers. Conventional surface pretreatments were unnecessary when applying the second current, particularly when the most highly oxidized metal species remained reducible in the electrolyte.
Here, the transverse current was modulated to roughen the surface or reduce porosity while allowing the relief of strain during deposition.
Example 4¨ Pressed Powder Corroding Electrode
Example 5 - Bonding Using Computerized System
Alternatively, the user 2050 may use both, with the leads 2030, 2035 proving broad second current while the counterelectrodes of the applicator 1100 localize the second current across the area of the tip.
The electrolyte also contains dissolved A1C13 at a molar ratio of about 1:1 with EMIC. See Example 12 for more details on deposition chemistry.
Therefore, the operator may set the interior temperature of the applicator to 60 C to promote deposition. The MCU's 2010 software may account for temperature and may modulate the applied power automatically.
Example 6 - Repairing Chemical Tank
remotely. The MCU is programmed to first apply a corrosion-roughening step through the electrochemical circuit. The roughened surface is primed for new metal deposition. Next, the MCU proceeds with slow deposition with second current of 10 dbm at 4 GHz and DC offset of 0.5 V.
The second current frequency is chosen because it is sufficiently fast while not stimulating dangerous chemicals stored in the tank. Power is lost from dissipation across the crack.
Power is set to 10 dbm compensate for this dissipation.
Example 7 ¨ Anti-corrosion method
switches from the monitoring mode using the periodic transverse current to a repair mode using a continuous transverse current at 0.2 dbm and 30 MHz. The higher power of the repair mode compensates for the signal attenuation. The higher frequency of the continuous transverse current outpaces the rate of the corrosion reaction, so that the progression of corrosion is halted and the defect is repaired. The wavelength of the transverse current is selected to be less than the length of the tubing. The polar symmetry of the sinusoidal waveform disrupts the flow of electrons and ions near the defect, which would normally facilitate corrosion.
A net change is not induced in transverse current, because the mean potential at the defect remains at zero.
The CSS switches from the repair mode back to the monitoring mode using a pulsed transverse current.
Example 8 ¨ Two-dimensional Computer Simulation of the Bonding Method
and a cathodic workpiece in two segments (2110A, 2110B) having a gap 2150 between the segments 2110A, 2110B. The workpiece 2110A, 2110B was in electrical communication with the anodes 2110A, 2110B through an electrolyte 2140. In the simulation, the electrolyte 2140 was saltwater, the "conductivity(2)" parameter was 5, the time was 9.75 [Ls, the slice was the electric field norm (V/m), and the relative angle between the electrodeposition and transverse current (phi) was 0 . The arrows 2133 are the electric field lines.
Example 9¨ Bonding Method Using Copper Metal Bonding Method
In one experiment, two 5" x 1" pieces of 0.08" thick copper sheet were joined along their longest dimensions. In a related experiment, two pieces of steel were joined using an electrodeposition current of -300 mA. Samples prepared using conventional electrodeposition methods and the bonding method disclosed herein were compared to each other.
Specifically, the anode experienced only the pulsing of the uncombined electrodeposition current.
and ChB used the equivalent impedance. The exact potential varied with hardware, temperature, concentration, and pH of the electrolyte.
Example 10 ¨ Incident-Reflection Method
Electrodeposition occurred at -1 V, using two copper anodes on either side of the circuit board.
The transverse current was applied through two channels via an electrical contact on each side of the circuit board. Both channels applied a transverse current at 100 kHz and 1.5 Vpp with a 180 phase offset. The two sides of the circuit board had no direct electrical contact.
The iTC signal changed as it travelled across the surface of the circuit board, because the electrodeposition and the electrolyte absorbed energy from the iTC. The remaining, unabsorbed energy in the iTC continued to travel across the surface until it encountered the right side of the circuit board. The iTC reflected back, generating the reflected transverse current (rTC). When iTC encountered rTC, their energies superimposed, like ripples in a pond. When the superimposition provided more energy at a point, the electrodeposition increased at the point as a function of the rate of the electrochemical reaction. The frequency and power of the iTC could be swept nonlinearly to promote a uniform electric field across the surface of the workpiece.
Alternatively, the frequency and power of the iTC can target particular features or topographies on the surface of the workpiece.
showed uniform copper distribution across the two regions. Overall, oxygen concentration was low (FIG. 37C and D), but the oxygen levels were slightly greater on the bottom region (FIG.
37B). This concentration difference is not because the lower area deposited more oxygen into the bulk, but instead because the surface area was greater due to increased roughness. Therefore, more surface area and more oxygen were exposed to the detector at the bottom region.
Example 11 ¨ Al-Fe Deposit
are the two-dimensional elemental maps for each iron (FIG. 38C), aluminum (FIG. 38D), and carbon (FIG.
38E).
Example 12¨ Deposition from an Aluminum Corroding Anode
and 39C are the two-dimensional elemental maps for aluminum and iron in the sample, respectively, showing an approximately 1:1 aluminum-iron alloy deposited from the ionic liquid onto the copper workpiece. FIG 39D is an elemental analysis confirming that the sample contained iron, aluminum, copper, carbon, oxygen, and chlorine.
Example 13 ¨ Fe-Zn alloy deposit This example demonstrated Zn-Fe alloy deposition from an ionic liquid using a pressed powder electrode. An ionic liquid was prepared from a 1:2 molar ratio of choline chloride and urea. The zinc and iron sources for the deposit came from the anode and dissolved salts.
The anodes tested were an iron anode, a zinc anode, or a Zn-Fe anode made of pressed powder or other preparation.
A solution of 0.2 M ZnCl2prepared in the ionic liquid. Up to 0.3 M FeCl3 was also added to the solution. The workpiece was mild steel (3/4" x 3/4"). The solution temperature was 85 C. The electrodeposition current was -1.8 V.
FIG. 40H shows an electron micrograph composite of the electron micrograph (FIG. 40A), and the two-dimensional elemental contents for iron (FIG. 40B, yellow), zinc (FIG.
40C, light blue), carbon (FIG. 40D, cyan), chlorine (FIG. 40E, green), and oxygen (FIG. 40F, dark blue), showing the codeposition of zinc and iron to form the alloy. FIG. 40G shows the elemental distribution in the sample, showing that the sample contained iron, zinc, carbon, oxygen, and chlorine Example 14¨ Plating Copper onto a Woven Workpiece
Deposition near the junction 4151, 4152 was rough. Deposition on the copper workpiece 4110 was smoother and more nearly matched the <110> crystal phase of the copper workpiece 4110.
Because Kevlar is not conductive like copper or semi-conductive like carbon, the woven workpiece is first impregnated with a metal salt, such as NiC12(aq), before further processing.
Any non-conductive woven workpiece, such as cotton cloth or polyester cloth, may be pretreated in this way. The treated woven workpiece is processed using a method described to deposit aluminum, titanium, or another metal or alloy. Kevlar or other non-conductive workpiece may be shaped into panels or shaped to a mold before deposition, so that the metallization locks the fabric into place.
Example 15 ¨ Further Examples of Joining Separate Workpieces A. Joining Copper to Nickel
(about 2.5"
x 1" x 0.062") using copper. The electrolyte was saturated CuSO4(aq). The anodes were also Cu <110>. The electrodeposition current density was 0.6 mA/mm2. The transverse current was applied through two channels, with one channel configured to the copper workpiece and the other channel configured to the nickel workpiece. The transverse current was applied with a 180 phase offset at 5 Vpp and 100 kHz in saw tooth waveform. These were the same parameters for the transverse current conditions as the copper-carbon cloth at Example 14.
This reduction would also lessen the size of spikes in current density at the edge of the nickel workpiece. The frequency could be increased into the MHz region to suppress faster growth at edges, especially at the nickel edge which is already thicker.
B. Joining Brass to Aluminum
As such, the joint between the two workpieces 4310, 4315 was mechanically strong. Moreover, the areas 4351 and 4352 adjacent to the junction 4350 also had thick deposits of new copper.
The deposition across both the workpieces 4310, 4315 was smooth, although the junction 4350 received the most new material. FIG. 43B magnifies the junction 4350. The regions 4351, 4352 adjacent to the juncture 4350 show ripples from convection in the electrolyte during deposition.
This combination of electrodeposition and transverse currents increased the roughness of the deposit at the junction 4350 and in the regions 4351, 4352 near the junction.
C. Joining Copper Sheets
Perpendicular shearing &
Bending along both axis of the junction.
D. Joining Steel to Steel via Fe-Sn Alloy
Example 16¨ Joining Aluminum Workpieces with Nickel Gel Electrolyte
offset less than or equal to the Vpp of the transverse current, the Vpp remains unchanged.
When the Vpp of the transverse current is greater than the voltage of the DC
offset, more deposition or corrosion occurs at nodes 4613, 4615 than at the anti-nodes 4612, 4614, 4616.
45) and the energy distribution of 1.6-GHz transverse current is too uneven (FIG. 48). Above 1-GHz, the periodic transverse current artificially changes the rate of deposition points along the junction, increasing the parallel electric field strength and preventing high current density areas. At frequencies of 1, 1.33 or 1.6 GHz, the transverse current origin corresponds to an anti-node 100% of the time.
There, the transverse current signal may be turned so the workpiece surface at the origin is does not experience an anti-node. The higher frequency transverse current may cause stronger bonds between the two workpieces because energy is better distributed, while the lower frequencies could cause a redistribute metal.
Differences in the phase on the electrodes arise from these asymmetries. These differences change as new metal is deposited. Cycling the transverse current helps avoid forming artificial rough spots.
smooth finish is achieved on a deposit, particularly for high frequencies and without electrodeposition signal modulation.
Example 17¨ Battery Healing
The anode comprises Li-foil and the electrolyte is a 1:1 mixture of ethylene carbonate and dimethyl carbonate with dissolved LiPF6 at a concentration between 0.2 M and 1.0 M. The coin cells are loaded into a charge-discharge cell to deliver impedance-regulated AC energy from a battery control unit to the coin cell. During both charge and discharge cycles (deposition and dissolution), the transverse current signal is applied over the standard charge/discharge potentials. Both processes involve Li diffusion through the solid electrolyte interphase.
Electrical contact is made between the charge-discharge cell and the coin cell.
facilitates uniform propagation of AC signal.
Areas of destructive interference do not exceed this boundary, so deposition or dissolution lessens. As the transverse current signal changes, the locations of these constructive and destructive points change at a controlled rate similar to the ionic mobility of lithium ions.
So the above description should not be taken as limiting the document.
These claims should cover all generic and specific features described, and all statements of the present method and system, which, as a matter of language, might be said to fall therebetween.
EXEMPLARY EMBODIMENTS
The following is a listing of exemplary embodiments for methods and apparatuses disclosed herein:
1. A method comprising:
inducing a first current between a source of a countercharge and a first electrode, the first current being through an electrolyte;
inducing a second current across the first electrode, the second current being transverse to the first current, and the second current inducing a relativistic charge across the first electrode.
2. The method of claim 1, wherein the first electrode is a working electrode.
3. The method of claims 1-2, the electrolyte comprising a metal, the first electrode having a void with a metal edge, the relativistic charge causing a metal-metal bond to form between metal from the electrolyte and the metal edge to thereby fill the void.
4. The method of claim 3, wherein the void is a crack, crevice, or fracture in the first electrode.
5. The method of claim 3, the void forming a gap between a first portion of the first electrode, the first portion having a first edge of the metal edge, and a second portion of the first electrode, the second portion with a second edge of the metal edge proximate the first edge, the relativistic charge causing the metal-metal bond to form between metal from the first edge and metal from the electrolyte and between metal from the second edge and metal from the electrolyte, the bonded metals thereby bridging the gap to form a unified electrode of the first portion and the second portion.
6. The method of claims 1-5, wherein the source of a countercharge is an electrode counter to the first electrode.
7. The method of claims 1-6, wherein the electrolyte comprises a metal and one or more species selected from the group consisting of water, ammonium salts, metal chlorides, metal sulfates, ionic liquids, ionogels, and any combination thereof.
8. The method of claim 7, wherein the electrolyte comprises an ionic liquid, and the ionic liquid is a room temperature ionic liquid.
9. The method of claim 8, wherein the room-temperature ionic liquid is 1-ethy1-3-methylimidazolium chloride.
10. The method of claims 1-9, wherein the electrolyte comprises metal particles.
11. The method of claims 1-10, wherein the second current is chosen from an alternating current (AC) second current, or a combination of an AC second current and a direct current (DC) second current.
12. The method of claim 11, wherein the second current is the combination of the AC second current and the DC second current, the DC second current offsetting the AC
second current by an amount less than an electrochemical breakdown of the electrolyte.
13. The method of claims 1-12, the second current having a waveform comprising a plurality of waveforms based on harmonics of one or more frequencies at which the electrolyte or the first electrode exhibits absorption of the one or more frequencies.
14. The method of claim 13, the second current having a phase offset of about 90 between an onset frequency voltage and an output amperage.
15. The method of claims 1-14, further comprising applying a signal cancellation to reduce a far-field radiation from the first electrode.
16. The method of claims 1-15, the second current having a period similar to a diffusion rate of a component in the electrolyte.
17. A method comprising:
inducing an electric field between a source of a countercharge and a first electrode, the electric field having field lines through an electrolyte;
inducing a potential across a surface of the first electrode, the induced potential bending the field lines proximate the surface such that metal from the electrolyte follows a path of the bent field lines to deposit the metal onto the surface.
18. The method of claim 17, wherein the first electrode is a working electrode.
19. The method of claims 17-19, the first electrode having a void with a metal edge, the induced potential causing a metal-metal bond to form between metal from the electrolyte and the metal edge to thereby fill the void.
20. The method of claim 19, wherein the void is a crack, crevice, or fracture in the first electrode.
21. The method of claim 19, the void forming a gap between a first portion of the first electrode, the first portion having a first edge of the metal edge, and a second portion of the first electrode, the second portion with a second edge of the metal edge proximate to the first edge, the relativistic charge causing the metal-metal bond between metal from the first edge and metal from the electrolyte and between metal from the second edge and metal from the electrolyte, the bonded metals to thereby bridging the gap to form a unified electrode of the first portion and the second portion.
22. The method of claims 17-21, wherein the source of a countercharge is an electrode counter to the first electrode.
23. The method of claims 17-22, wherein the electrolyte comprising one or more species selected from the group consisting of water, quaternary ammonium salts, metal chlorides, ionic liquids, ionogels, and any combination thereof.
24. The method of claim 23, wherein the electrolyte comprises an ionic liquid, and the ionic liquid is a room temperature ionic liquid.
25. The method of claim 24, wherein the room-temperature ionic liquid is 1-ethy1-3-methylimidazolium chloride.
26. The method of claims 17-25, wherein the electrolyte comprises metal particles.
27. The method of claims 17-26, wherein the second current is chosen from an alternating current (AC) second current, or a combination of an AC second current and a direct current (DC) second current.
28. The method of claims 17-27, the induced potential having a waveform comprising a plurality of waveforms based on harmonics of one or more frequencies at which the electrolyte or the first electrode exhibits absorption at the one or more frequencies.
29. The method of claim 28, the induced potential having a phase offset of about 900 between an onset frequency and an output amperage.
30. The method of claims 17-29, further comprising applying a signal cancellation to reduce a far-field radiation from the first electrode.
31. The method of claims 17-30, the induced potential having a period similar to a diffusion rate of a component in the electrolyte.
32. A method comprising: inducing a potential across a surface of an electrode in the presence of a chemical potential between an electrolyte and the surface of the electrode, the induced potential relativistically charging the surface of the electrode.
33. The method of claim 32, the relativistic charge causing a metal-metal bond to form between metal from the electrolyte and metal on the surface.
34. The method of claim 33, the electrode having a void with a metal edge, the relativistic charge causing the metal-metal bond between metal from the electrolyte and the metal edge to thereby fill the void.
35. The method of claim 34, the void forming a gap between a first portion of the electrode, the first portion having a first edge of the metal edge, and a second portion of the electrode, the second portion with a second edge of the metal edge proximate to the first edge, the relativistic charge causing the metal-metal bond to form between metal from the first edge and metal from the electrolyte and between metal from the second edge and metal from the electrolyte, the bonded metals to thereby bridging the gap to form a unified electrode of the first portion and the second portion.
36. The method of claims 32-35, wherein the electrolyte comprises metal and one or more species selected from the group consisting of water, quaternary ammonium salts, metal chlorides, ionic liquids, ionogels, and any combination thereof.
37. The method of claims 32-36, wherein the electrolyte comprises metal particles.
38. The method of claims 32-37, wherein the induced potential is chosen from an alternating current (AC) induced potential, or a combination of an AC induced potential and a direct current (DC) induced potential.
39. The method of claim 38, wherein the induced potential is the combination of the AC
induced potential and the DC induced potential, the DC induced potential offsetting the AC
induced potential by an amount less than an electrochemical breakdown of the electrolyte.
40. The method of claims 32-39, the induced potential having a waveform comprising a plurality of waveforms based on harmonics of one or more frequencies at which the electrolyte or the electrode exhibits absorption at the one or more frequencies.
41. The method of claim 40, wherein the induced potential comprises a phase offset of about 900 between an onset frequency and an output amperage.
42. The method of claims 32-41, further comprising applying a signal cancellation to reduce a far-field radiation from the electrode.
43. The method of claims 32-42, the induced potential having a period similar to a diffusion rate of a component in the electrolyte.
44. The method of claims 1-43, wherein the first electrode comprises at least two galvanically reactive metals meeting a junction, the second current reducing corrosion at the junction.
45. The method of claim 44, wherein the second current distributes charge away from grain boundaries on the surface of the first electrode and avoids corrosive pitting at the surface of the first electrode.
46. The method of claims 1-43, wherein the first current has a positive potential sufficient to corrode away a rough feature at the surface of the first electrode.
47. The method of claim 46, wherein the first current is applied with a low current density, a pulsed current density, or a combination of a low, pulsed current density.
48. The method of claims 1-31, wherein metal from the electrolyte bonds to a vacant site on the surface of the first electrode or the source for a countercharge and not to a previously bonded metal.
49. The method of claim 48, wherein a membrane is disposed between the source for a countercharge and the first electrode, the source for a countercharge comprising Lin,Oy, the first electrode comprising carbon or Li , the metal from the electrolyte comprising Li+, and the previously-bonded metal comprising Li .
50. A corroding electrode comprising one or more metal species selected from the group consisting of metal particles, metal ions, and combinations thereof;
wherein the corroding electrode dissolves when a first current is applied between the corroding electrode and a first electrode through an electrolyte, thereby suspending the one or more metal species into the electrolyte.
51. The corroding electrode of claim 50, further comprising one or more ceramic particles or dielectric polymers.
52. The corroding electrode of claims 50-51, wherein the corroding source of a countercharge is formed by being pressed together into a solid body.
53. The corroding electrode of claims 50-52, wherein the metal particles have grain sizes selected to grain sizes of the first electrode.
54. The corroding electrode of claims 50-53, comprising metal particles having rough or non-symmetric dimensions.
55. The corroding electrode of claims 50-54, comprising metal particles having spherical dimensions and a uniform surface energy.
56. The corroding electrode of claims 50-55, comprising metal particles having an elongated dimension, which aligns with a second current induced across the first electrode, the second current being transverse to the first current, and the second current inducing a relativistic charge across the first electrode.
57. The method of claims 1-31, wherein the source of a countercharge is a corroding electrode of claims 50-56.
58. A device comprising:
a source of a countercharge, and a first electrode in electrical communication through an electrolyte with the source of a countercharge;
wherein a first current is induced through the electrolyte between the source of a countercharge and the first electrode; and wherein a second current is induced across the first electrode, the second current being transverse to the first current, and the second current inducing a relativistic charge across the first electrode.
59. The device of claim 58, wherein the first electrode is a working electrode.
60. The device of claims 58-59, the electrolyte comprising a metal, the first electrode having a void with a metal edge, the relativistic charge causing a metal-metal bond to form between metal from the electrolyte and the metal edge to thereby fill the void.
61. The device of claim 60, wherein the void is a crack, crevice, or fracture in the first electrode.
62. The device of claim 60, the void forming a gap between a first portion of the first electrode, the first portion having a first edge of the metal edge, and a second portion of the first electrode, the second portion with a second edge of the metal edge proximate the first edge, the relativistic charge causing the metal-metal bond to form between metal from the first edge and metal from the electrolyte and between metal from the second edge and metal from the electrolyte, the bonded metals thereby bridging the gap to form a unified electrode of the first portion and the second portion.
63. The device of claims 58-62, wherein the source of a countercharge is an electrode counter to the first electrode.
64. The device of claims 58-63, wherein the electrolyte comprises a metal and one or more species selected from the group consisting of water, quaternary ammonium salts, metal chlorides, ionic liquids, ionogels, and any combination thereof.
65. The device of claim 64, wherein the electrolyte comprises an ionic liquid, and the ionic liquid is a room temperature ionic liquid.
66. The device of claim 65, wherein the room-temperature ionic liquid is 1-ethy1-3-methylimidazolium chloride.
67. The device of claims 58-66, wherein the electrolyte comprises metal particles.
68. The device of claims 58-67, wherein the second current is chosen from an alternating current (AC) second current, or a combination of an AC second current and a direct current (DC) second current.
69. The device of claim 68, wherein the second current is the combination of the AC second current and the DC second current, the DC second current offsetting the AC
second current by an amount less than an electrochemical breakdown of the electrolyte.
70. The device of claims 58-69, further comprising a waveform generator to provide the second current with a waveform comprising a plurality of waveforms based on harmonics of one or more frequencies at which the electrolyte or the first electrode exhibits absorption of the one or more frequencies.
71. The device of claims 58-70, further comprising a signal canceler to reduce a far-field radiation from the first electrode.
72. The device of claims 58-71, the second current having a period similar to a diffusion rate of a component in the electrolyte.
73. A device comprising:
a source of a countercharge, and a first electrode in electrical communication through an electrolyte with the source of a countercharge;
wherein an electric field is induced between the source of a countercharge and the first electrode, the electric field having field lines through the electrolyte; and wherein a potential is induced across a surface of the first electrode, the induced potential bending the field lines proximate the surface such that metal from the electrolyte follows a path of the bent field lines to deposit the metal onto the surface.
74. The device of claim 73, wherein the first electrode is a working electrode.
75. The device of claims 73-75, the first electrode having a void with a metal edge, the induced potential causing a metal-metal bond to form between metal from the electrolyte and the metal edge to thereby fill the void.
76. The device of claim 75, wherein the void is a crack, crevice, or fracture in the first electrode.
77. The device of claim 75, the void forming a gap between a first portion of the first electrode, the first portion having a first edge of the metal edge, and a second portion of the first electrode, the second portion with a second edge of the metal edge proximate to the first edge, the relativistic charge causing the metal-metal bond between metal from the first edge and metal from the electrolyte and between metal from the second edge and metal from the electrolyte, the bonded metals to thereby bridging the gap to form a unified electrode of the first portion and the second portion.
78. The device of claims 73-77, wherein the source of a countercharge is an electrode counter to the first electrode.
79. The device of claims 73-78, wherein the electrolyte comprises one or more species selected from the group consisting of water, quaternary ammonium salts, metal chlorides, ionic liquids, ionogels, and any combination thereof.
80. The device of claim 79, wherein the electrolyte comprises an ionic liquid, and the ionic liquid is a room temperature ionic liquid.
81. The device of claim 80, wherein the room-temperature ionic liquid is 1-ethy1-3-methylimidazolium chloride.
82. The device of claims 73-81, wherein the electrolyte comprises metal particles.
83. The device of claims 73-82, wherein the second current is chosen from an alternating current (AC) second current, or a combination of an AC second current and a direct current (DC) second current.
84. The device of claims 73-83, further comprising a waveform generator to provide the induced potential with a waveform comprising a plurality of waveforms based on harmonics of one or more frequencies at which the electrolyte or the first electrode exhibits absorption at the one or more frequencies.
85. The device of claims 73-84, further comprising a signal canceler to reduce a far-field radiation from the first electrode.
86. The device of claims 73-85, the induced potential having a period similar to a diffusion rate of a component in the electrolyte.
87. A first electrode, wherein a potential is induced across a surface of the first electrode in the presence of a chemical potential between an electrolyte and the surface of the first electrode, the induced potential relativistically charging the surface of the first electrode.
88. The first electrode of claim 87, the relativistic charge causing a metal-metal bond to form between metal from the electrolyte and metal on the surface.
89. The first electrode of claim 88, the first electrode having a void with a metal edge, the relativistic charge causing the metal-metal bond between metal from the first electrolyte and the metal edge to thereby fill the void.
90. The first electrode of claim 89, the void forming a gap between a first portion of the first electrode, the first portion having a first edge of the metal edge, and a second portion of the first electrode, the second portion with a second edge of the metal edge proximate to the first edge, the relativistic charge causing the metal-metal bond to form between metal from the first edge and metal from the electrolyte and between metal from the second edge and metal from the electrolyte, the bonded metals to thereby bridging the gap to form a unified electrode of the first portion and the second portion.
91. The first electrode of claims 87-90, wherein the electrolyte comprises metal and one or more species selected from the group consisting of water, quaternary ammonium salts, metal chlorides, ionic liquids, ionogels, and any combination thereof.
92. The first electrode of claims 87-91, wherein the electrolyte comprises metal particles.
93. The first electrode of claims 87-92, wherein the induced potential is chosen from an alternating current (AC) induced potential, or a combination of an AC induced potential and a direct current (DC) induced potential.
94. The first electrode of claim 93, wherein the induced potential is the combination of the AC
induced potential and the DC induced potential, the DC induced potential offsetting the AC
induced potential by an amount less than an electrochemical breakdown of the electrolyte.
95. The first electrode of claims 87-94, the induced potential having a waveform comprising a plurality of waveforms based on harmonics of one or more frequencies at which the electrolyte or the electrode exhibits absorption at the one or more frequencies.
96. The first electrode of claims 87-95, the induced potential having a period similar to a diffusion rate of a component in the electrolyte.
97. A device comprising:
a main control unit comprising a power supply and a power modulator;
an electrode applicator unit, comprising at least one source of a countercharge and a plurality of channels for flowing an electrolyte through the electrode applicator unit, the electrode applicator unit being connected to the main control unit;
a current collector cable connected to the main control unit; and a power control unit connected to the main control unit, which power control unit applies a first current between a first electrode and the at least one source of a countercharge through the electrolyte, the power control unit inducing a second current across the first electrode, the second current being transverse to the first current, and the second current inducing a relativistic charge across the first electrode.
98. The device of claim 97, wherein the main control unit further comprises a computer for executing instructions stored on a computer readable medium.
99. The device of claim 98, wherein the power modulator and the power control unit are controlled by the computer.
100. The device of claims 97-99, wherein the main control unit further comprises an electrolyte storage tank, at least one pump, and tubing connected to the electrolyte storage tank, the at least one pump, and the electrode applicator unit; thereby flowing the electrolyte from the electrolyte storage tank through the tubing into the plurality of channels of the electrode applicator unit.
101. The device of claims 97-100, wherein the electrode applicator unit further comprises a heating unit or a cooling unit for modulating a temperature of the electrolyte within the channels of the electrode applicator unit.
102. The device of claims 97-101, wherein the current collector cable further comprises leads for attaching to the first electrode.
103. The device of claims 56-86 or 97-102, wherein the at least one source of a countercharge comprises a corroding electrode of claims 50-56.
104. The device of claims 56-86 or 97-102, wherein the device performs a method of claims 1-49.
Claims (32)
a source of countercharge;
an electrode;
an electrolyte in contact with the electrode and through which a first current between the source of countercharge and electrode flows; and a waveform generating device coupled with the electrode, the waveform generating device inducing an electric waveform across the electrode in the presence of the current.
applying a first current between a source of countercharge and an electrode;
and applying an electric waveform across the electrode, the electric waveform having an energy density greater than 0 mA/cm2 and less than 300 mA/cm2 and a frequency between 35 kHz and 10 GHz.
Applications Claiming Priority (3)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
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| EP3485068B1 (en) | 2016-07-13 | 2026-04-08 | Iontra Inc | Electrochemical methods, devices and compositions |
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Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN111826691A (en) * | 2020-08-21 | 2020-10-27 | 东北大学 | A kind of method for preparing zinc-tantalum alloy by solvated ionic liquid |
| CN111826691B (en) * | 2020-08-21 | 2021-09-21 | 东北大学 | Method for preparing zinc-tantalum alloy by using solvated ionic liquid |
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| TWI658506B (en) | 2019-05-01 |
| JP7358238B2 (en) | 2023-10-10 |
| WO2018013874A1 (en) | 2018-01-18 |
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| JP2023112036A (en) | 2023-08-10 |
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| US12286720B2 (en) | 2025-04-29 |
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| US11280018B2 (en) | 2022-03-22 |
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