Chemistry: electrical current producing apparatus – product – and – Current producing cell – elements – subcombinations and... – Electrode
Reexamination Certificate
1998-09-01
2001-03-13
Kalafut, Stephen (Department: 1745)
Chemistry: electrical current producing apparatus, product, and
Current producing cell, elements, subcombinations and...
Electrode
C429S227000, C429S221000, C429S231500, C429S231950
Reexamination Certificate
active
06200704
ABSTRACT:
BACKGROUND OF THE INVENTION
This invention relates generally to positive electrodes characterized by active-sulfur and a second material having a higher discharge rate than active-sulfur. The electrodes are preferably rechargeable, and in some preferred embodiments as a thin-film format. Various negative electrodes, such as, alkali metal, alkaline earth metal, transition metal, and carbon insertion electrodes, among others, can be coupled with the positive electrode to provide battery cells, preferably having high specific energy (Wh/kg) and energy density (Wh/l), while providing high rate pulse capability. All references cited in this application are incorporated by reference for all purposes.
The rapid proliferation of portable electronic devices in the international marketplace has led to a corresponding increase in the demand for advanced secondary batteries. The miniaturization of such devices as, for example, cellular phones, laptop computers, etc., has naturally fueled the desire for rechargeable batteries having high specific energies (light weight). At the same time, mounting concerns regarding the environmental impact of throwaway technologies, has caused a discernible shift away from primary batteries and toward rechargeable systems.
In addition, heightened awareness concerning toxic waste has motivated, in part, efforts to replace toxic cadmium electrodes in nickel/cadmium batteries with the more benign hydrogen storage electrodes in nickel/metal hydride cells. For the above reasons, there is a strong market potential for environmentally benign secondary battery technologies.
Secondary batteries are in widespread use in modern society, particularly in applications where large amounts of energy are not required. However, it is desirable to use batteries in applications requiring considerable power, and much effort has been expended in developing batteries suitable for high specific energy, medium power applications, such as, for electric vehicles and load leveling. Of course, such batteries are also suitable for use in lower power applications such as cameras or portable recording devices.
At this time, the most common secondary batteries are probably the lead-acid batteries used in automobiles. Those batteries have the advantage of being capable of operating for many charge cycles without significant loss of performance. However, such batteries have a low energy to weight ratio. Similar limitations are found in most other systems, such as Ni—Cd and nickel metal hydride systems.
Among the factors leading to the successful development of high specific energy batteries, is the fundamental need for high cell voltage and low equivalent weight electrode materials. Electrode materials must also fulfill the basic electrochemical requirements of sufficient electronic and ionic conductivity, high reversibility of the oxidation/reduction reaction, as well as excellent thermal and chemical stability within the temperature range for a particular application. Importantly, the electrode materials must be reasonably inexpensive, widely available, non-toxic, and easy to process.
Thus, a smaller, lighter, cheaper, non-toxic battery has been sought for the next generation of batteries. The low equivalent weight of lithium renders it attractive as a battery electrode component for improving weight ratios. Lithium provides also greater energy per volume than do the traditional battery standards, nickel and cadmium.
The low equivalent weight and low cost of sulfur and its nontoxicity renders it also an attractive candidate battery component. Successful lithium/organosulfur battery cells are known. (See, De Jonghe et al., U.S. Pat. Nos. 4,833,048 and 4,917,974; and Visco et al., U.S. Pat. No. 5,162,175.)
Recent developments in ambient-temperature sulfur electrode technology may provide commercially viable rechargeable lithium-sulfur batteries. Chu and colleagues are largely responsible for these developments which are described in U.S. Pat. Nos. 5,582,623 and 5,523,179 (issued to Chu). The patents disclose an sulfur-based positive electrode for a battery cell that has low equivalent weight and high cell voltage and consequently a high specific energy (greater than about 120 Wh/kg). The disclosed positive electrode addresses deficiencies in the prior art to provide a high capacity sulfur-based positive composite electrode suitable for use with metal (such as lithium) negative electrodes in secondary battery cells. These developments allow electrochemical utilization of elemental sulfur at levels of 50% and higher over multiple cycles. Because sulfur has a theoretical maximum capacity of 1675 mAh/g (assuming all sulfur atoms in an electrode are fully reduced during discharge), the utilization of sulfur in lithium-sulfur cells as described in the above Chu patents typically exceeds 800 milliamp-hours per gram (mAh/g) of sulfur.
The sulfur-based positive electrodes described in the above Chu patents provide increased capacity over previously available electrodes. Of course, further increases in electrode (and hence battery) capacity would be desirable. In addition, another desirable characteristic of a battery cell for some applications is fast kinetics, that is, the ability to adequately respond to high power requirements with a high discharge rate. Some portable electronic devices, for example, have a variety of different power requirements. For example, a camera battery must be able to respond to relatively low power requirements associated with such general operations as shutter activation, auto focus, zoom lens adjustment, and film advancement and rewind. In addition, the camera battery must be able to respond to such relatively infrequent and short-lived high power requirements as flash operation. For such devices, a battery which combines the features of increased capacity and high discharge rate pulse capability may be optimal.
Accordingly, cathodes and battery cells having both high capacity and high discharge rate pulse characteristics would be desirable. A rechargeable (secondary) electrode/battery having such features would be further desirable.
SUMMARY OF THE INVENTION
The present invention provides a positive electrode for a battery cell that has low equivalent weight and high cell voltage and consequently a high specific energy, and has high discharge rate pulse capability. The batteries of this invention are preferably rechargeable and operate at high sulfur utilization over many cycles. Positive electrodes according to the present invention are composed of at least two electrochemically active materials: an “active-sulfur” material, and a second electrochemically active material having a higher discharge rate than the active-sulfur component. The active-sulfur component is also oxidizing with respect to the higher discharge rate material. In operation, the active-sulfur component of the positive electrode discharges to satisfy power demands below its maximum discharge rate. The high discharge rate (but relatively low capacity) material is discharged to satisfy power demands that exceed the active-sulfur's discharge rate. The high discharge rate material in the positive electrode may be effectively recharged (or “regenerated”) chemically by oxidation by the active-sulfur material during a “resting” phase, that is, when the power demands on a battery cell in which the cathode is incorporated are low enough that they may be met without exceeding the maximum discharge rate of the active-sulfur component of the positive electrode. This effective recharge occurs according to a well known electrochemical mechanism due to the contact between the two electrochemically active materials in the positive electrode, and the fact that the active-sulfur material is oxidizing with respect to the higher discharge rate material.
Thus the high capacity of the active-sulfur component of the positive electrode may be leveraged to chemically regenerate the lower capacity but higher discharge rate material so that both materials are available for discharge until the active-sulfur component is
Chu May-Ying
De Jonghe Lutgard C.
Katz Bruce D.
Visco Steven J.
Beyer Weaver & Thomas LLP
Kalafut Stephen
Martin Angela J.
PolyPlus Battery Company, Inc.
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