Nanoball batteries are an experimental type of battery with either the cathode or anode made of nanosized balls that can be composed of various materials such as carbon and lithium iron phosphate. Batteries which use nanotechnology are more capable than regular batteries because of the vastly improved surface area which allows for greater electrical performance, such as fast charging and discharging.[ citation needed ]
In 2009, researchers from MIT were able to charge a simple lithium iron phosphate nanoball battery in 10 seconds using this technology. In theory, this would allow for rapid charging of small electronic devices while larger batteries would still be limited by mains electricity. [1] [2]
Before the carbon nanoballs can be made, a carbon rod must be formed. The carbon rod is prepared in the presence of acetylene with coke powder (type of fuel source with few impurities and a high carbon content) and formed using arc discharge technique. Arc discharge technique uses two high-purity graphite electrodes as an anode and a cathode which are vaporized by the passage of a DC (direct current) current. [3] [ self-published source? ] After arc discharging for a period of time, a carbon rod is built up at the cathode. The carbon rod is then put in a DC arc discharge reactor. The carbon rod acts as the anode while a high purity graphite rod acts as the cathode. A current adjusted to 70-90 amps was passed through the two rods in an acetylene medium at a pressure of 0.05 to 0.06 MPa (megapascals). Carbon nanoballs formed on the carbon rod during the arc evaporation process. The carbon nanoballs were then examined using a FE-SEM (Field emission scanning electron microscope) and a STEM (scanning transmission electron microscope) which was equipped with energy dispersive x-rays operated at 200 kV (kilo-volts), x-ray diffraction, and Raman Spectroscopy. Most of the carbon nanoballs that was formed were sintered (solid mass of material formed by heat and/or pressure). Trace amounts of nanoballs that existed as individuals rather than a group was also detected as well as a few cotton-like nano-materials. [1]
Tests done by the Anhui University of Technology have shown that the carbon nanoballs inside a cell electrode have a high reversible capacity and a capacity retention rate of almost 74%. This means that the battery can discharge very quickly and that the battery has almost three-quarters of its total energy available under the right conditions. Tests done by the Institute of Materials and Technology, Dalian Maritime University have also shown that carbon nanoballs can be used to further increase the energy output of other materials like silicon. [2] Changing the molecular structure of silicon-carbon nanoballs can also result in higher charge and discharge capacities, longer cycling stability (amount of time before needing to replace the battery),and a good rate performance. [4]
Like carbon, lithium is also a good energy conductor. It is also already in use in commercial lithium-ion batteries. Lithium makes a good energy conductor because it allows ions to transfer faster than other elements and is also able to hold on to that energy longer. Research has shown that coating a phosphate particle with a layer of LiFePO4 (lithium iron phosphate) allows for an even faster rate of ion transferral. Lithium iron phosphate was made by solid-state reaction using Li2CO3 (lithium carbonate), FeC2O4 (iron(II) oxalate), and NH4H2PO4 (ammonium dihydrogen phosphate). The compounds were then placed in acetone and ball-milled (grinding materials together in a special cylindrical device) before being heated at 350 °C for 10 hours and then being allowed to cool to room temperature The mixture was then pelletized under 10,000 pounds of pressure before being heated again at 600 °C for 10 hours under argon. Each nanoball created measured around 50 nm(nanometers) in diameter. Under normal circumstances, electrochemical systems (e.g., batteries) can only achieve high power rates with supercapacitors. Supercapacitors achieve a high power rate by storing energy through surface adsorption reactions of charged species on an electrode. However, this results in low energy density. Instead of just storing charge on the surface of a material, Lithium iron phosphate can achieve a high power rate and high energy density by storing charge in the bulk of itself (the interior of the carbon nanoballs). This is possible because lithium iron phosphate has high lithium bulk mobility. Creating a fast ion-conducting surface phase through controlled off-stoichiometry (controlling the mole to mole ratio of the reactants and products in the molecular equation) enabled an ultrafast discharge rate. [5]
Discharge rate tests were conducted on electrodes with 30% active material, 65% carbon, and 5% binder. The lithium iron phosphate nanoballs were assembled in an argon-filled glove box and tested using a Maccor 2200 (type of battery test system). The Maccor 2000 was set to galvanostatic mode(measures electrochemical performance) and used lithium metal as an anode and a non-aqueous electrolyte and Celgard 2600 or 2500 as a separator. [5] The final discharge rate was fast enough to charge a battery in about 10–20 seconds, about a 100x faster than a normal battery.
Since this is an experimental procedure done in a lab environment, there haven't been any commercial products that have implemented this type of technology yet. Tesla Motors has thought about implementing nanoball batteries into its vehicles but the amount of energy needed and the cable needed to transfer that much energy would make it highly inefficient. As of right now, nanoball batteries are still in the experimental stage. Besides being used in cars and phones, nanoball batteries could also be used for relief in third-world countries and disaster-stricken areas as their small size and high discharge rates would allow for energy to be quickly and efficiently spread around.[ citation needed ]
Nanoball batteries show a lot of potential but improvements have to be made before they become a viable option to replace current batteries. Future research would include trying to integrate the nanoballs into the cathode of a lithium cell or merging nanoballs with other materials like silicon in batteries. Research done at the School of Material Science and Engineering at East China University of Science and Technology has shown that coating silicon nanoballs with a graphene/carbon coating keeps the silicon nanoball from degrading too quickly and improving the overall electromechanical performance of the battery. [6] For commercial use in cars and other electrical vehicles, the nanoball battery would need to be able to charge the vehicle using less energy. Even though the battery can discharge very quickly, too much energy is needed to go into the battery. Another issue that needs correcting is that even though the battery can discharge very quickly, it has difficulty holding on to that much energy for very long. Increasing the limit of how much energy the battery could hold would make the battery much more efficient. The technology may also allow for smaller batteries as the cathode material degrades at a slower rate than in current production batteries.[ citation needed ]
An electrode is an electrical conductor used to make contact with a nonmetallic part of a circuit. Electrodes are essential parts of batteries that can consist of a variety of materials depending on the type of battery.
A lithium-ion battery or Li-ion battery is a type of rechargeable battery composed of cells in which lithium ions move from the negative electrode through an electrolyte to the positive electrode during discharge and back when charging. Li-ion cells use an intercalated lithium compound as the material at the positive electrode and typically graphite at the negative electrode. Li-ion batteries have a high energy density, no memory effect and low self-discharge. Cells can be manufactured to prioritize either energy or power density. They can however, be a safety hazard since they contain flammable electrolytes and, if damaged or incorrectly charged, can lead to explosions and fires.
The lithium iron phosphate battery or LFP battery is a type of lithium-ion battery using lithium iron phosphate as the cathode material, and a graphitic carbon electrode with a metallic backing as the anode. The energy density of an LFP battery is lower than that of other common lithium ion battery types such as nickel manganese cobalt (NMC) and nickel cobalt aluminum (NCA), and also has a lower operating voltage; CATL's LFP batteries are currently at 125 watt hours (Wh) per kg, up to possibly 160 Wh/kg with improved packing technology, while BYD's LFP batteries are at 150 Wh/kg, compared to over 300 Wh/kg for the highest NMC batteries. Notably, the energy density of Panasonic’s “2170” NCA batteries used in 2020 in Tesla’s Model 3 is around 260 Wh/kg, which is 70% of its "pure chemicals" value.
A polymer-based battery uses organic materials instead of bulk metals to form a battery. Currently accepted metal-based batteries pose many challenges due to limited resources, negative environmental impact, and the approaching limit of progress. Redox active polymers are attractive options for electrodes in batteries due to their synthetic availability, high-capacity, flexibility, light weight, low cost, and low toxicity. Recent studies have explored how to increase efficiency and reduce challenges to push polymeric active materials further towards practicality in batteries. Many types of polymers are being explored, including conductive, non-conductive, and radical polymers. Batteries with a combination of electrodes are easier to test and compare to current metal-based batteries, however batteries with both a polymer cathode and anode are also a current research focus. Polymer-based batteries, including metal/polymer electrode combinations, should be distinguished from metal-polymer batteries, such as a lithium polymer battery, which most often involve a polymeric electrolyte, as opposed to polymeric active materials.
Nanobatteries are fabricated batteries employing technology at the nanoscale, particles that measure less than 100 nanometers or 10−7 meters. These batteries may be nano in size or may use nanotechnology in a macro scale battery. Nanoscale batteries can be combined to function as a macrobattery such as within a nanopore battery.
Nanodot can refer to several technologies which use nanometer-scale localized structures. Nanodots generally exploit properties of quantum dots to localize magnetic or electrical fields at very small scales. Applications for nanodots could include high-density information storage, energy storage, and light-emitting devices.
Lithium iron phosphate or lithium ferro-phosphate (LFP) is an inorganic compound with the formula LiFePO
4. It is a gray, red-grey, brown or black solid that is insoluble in water. The material has attracted attention as a component of lithium iron phosphate batteries, a type of Li-ion battery. This battery chemistry is targeted for use in power tools, electric vehicles, solar energy installations and more recently large grid-scale energy storage.
A nanowire battery uses nanowires to increase the surface area of one or both of its electrodes. Some designs, variations of the lithium-ion battery have been announced, although none are commercially available. All of the concepts replace the traditional graphite anode and could improve battery performance.
A lithium-ion capacitor (LIC) is a hybrid type of capacitor classified as a type of supercapacitor. It is called a hybrid because the anode is the same as those used in lithium-ion batteries and the cathode is the same as those used in supercapacitors. Activated carbon is typically used as the cathode. The anode of the LIC consists of carbon material which is often pre-doped with lithium ions. This pre-doping process lowers the potential of the anode and allows a relatively high output voltage compared to other supercapacitors.
Nanoarchitectures for lithium-ion batteries are attempts to employ nanotechnology to improve the design of lithium-ion batteries. Research in lithium-ion batteries focuses on improving energy density, power density, safety, durability and cost.
The lithium–air battery (Li–air) is a metal–air electrochemical cell or battery chemistry that uses oxidation of lithium at the anode and reduction of oxygen at the cathode to induce a current flow.
A potassium-ion battery or K-ion battery is a type of battery and analogue to lithium-ion batteries, using potassium ions for charge transfer instead of lithium ions. It was invented by the Iranian/American chemist Ali Eftekhari in 2004.
The sodium-ion battery (NIB or SIB) is a type of rechargeable battery analogous to the lithium-ion battery but using sodium ions (Na+) as the charge carriers. Its working principle and cell construction are almost identical with those of commercially widespread lithium-ion battery types, but sodium compounds are used instead of lithium compounds.
Aluminium-ion batteries are a class of rechargeable battery in which aluminium ions serve as charge carriers. Aluminium can exchange three electrons per ion. This means that insertion of one Al3+ is equivalent to three Li+ ions. Thus, since the ionic radii of Al3+ (0.54 Å) and Li+ (0.76 Å) are similar, significantly higher numbers of electrons and Al3+ ions can be accepted by cathodes with little damage. Al has 50 times (23.5 megawatt-hours m-3) the energy density of Li and is even higher than coal.
Research in lithium-ion batteries has produced many proposed refinements of lithium-ion batteries. Areas of research interest have focused on improving energy density, safety, rate capability, cycle durability, flexibility, and cost.
Lithium hybrid organic batteries are an energy storage device that combines lithium with an organic polymer. For example, polyaniline vanadium (V) oxide (PAni/V2O5) can be incorporated into the nitroxide-polymer lithium iron phosphate battery, PTMA/LiFePO4. Together, they improve the lithium ion intercalation capacity, cycle life, electrochemical performances, and conductivity of batteries.
The glass battery is a type of solid-state battery. It uses a glass electrolyte and lithium or sodium metal electrodes. The battery was invented by John B. Goodenough, inventor of the lithium cobalt oxide and lithium iron phosphate electrode materials used in the lithium-ion battery (Li-ion), and Maria H. Braga, an associate professor at the University of Porto and a senior research fellow at Cockrell School of Engineering at The University of Texas.
Structural batteries are multifunctional materials or structures, capable of acting as an electrochemical energy storage system while possessing mechanical integrity.
A solid state silicon battery or silicon anode all solid state battery is a type of rechargeable lithium ion battery consisting of a solid electrolyte, solid cathode, and silicon-based solid anode.
This is a history of the lithium-ion battery.