The watchmaker in the 1920s who de­vised the self-winding wristwatch was on to a great idea: mechanically harvesting energy from the wearer’s moving arm and putting it to work rewinding the watch spring.

Today we are beginning to create extremely small energy harvesters that can supply electrical power to the tiny world of nano­scale devices, where things are measured in billionths of a meter. We call these power plants nano­generators. The ability to make power on a minuscule scale allows us to think of implantable biosensors that can continuously monitor a patient’s blood glucose level, or autonomous strain sensors for structures such as bridges, or environmental sensors for detecting toxins—all running without the need for replacement batteries. Energy sources are desperately needed for nano­robotics, microelectromechanical systems (MEMS), homeland security and even portable personal electronics. It is hard to imagine all the uses such infinitesimal generators may eventually find.

Researchers are pursuing several different routes toward power generation on a miniature scale. Options include exploiting random vibrations or motions (such as those near a roadway), temperature gradients (for example, ground temperature is fairly constant several meters below the surface), biochemistry, and external energy sources such as ultrasonic waves or even audible noises.

A key advantage of nano­devices and nano­systems is that they usually operate at a very low power level, in the range of nano­watts to microwatts, bringing nano­generators for powering them into the realm of the possible. Just think of the potential power sources a human body provides: mechanical energy, heat energy, vibration energy, chemical energy (in the form of glucose) and the hydraulic energy of the circulatory system. Converted into electricity, just a small fraction of this energy could be sufficient to power many types of small devices.

Power to the Tiny
Work on power generation for small devices has moved quickly since the late 1990s, when the proliferation of portable electronic gadgets attracted researchers to the problem of finding new ways to power them. Experimenters at the Massachusetts Institute of Technology’s Media Lab, for example, devised an energy-scavenging shoe using the piezoelectric effect, whereby certain crystalline materials produce a voltage when mechanically stressed. But the difficulty of producing useful amounts of power soon drove scientists to explore generators that could meet the much smaller electrical power needs of MEMS. These silicon-based devices, whose dimensions are measured in microns (millionths of a meter) to millimeters (thousandths of a meter), have found many uses, including as accelerometers for automobile air-bag systems and as ink-jet printer nozzles. Biology and chemistry also offer opportunities for producing power.

In recent years, scientists have built small vibration-based generators using both piezoelectric and electromagnetic transducers. The electro­magnetic microgenerator utilizes a moving magnet or coil for inducing an alternating electric current in a circuit. Although some microgenerators have been fabricated at the scale of MEMS, the technology tends to require structures ranging from one to 75 cubic centimeters, which work in vibration ranges from 50 hertz (cycles per second) to five kilohertz. A typical piezoelectric vibration-based generator uses a two-layered beam of lead zirconium titanate, with a mass located at its unsupported end, somewhat like a swimmer poised at the end of a diving board. When gravity causes the beam to bend downward, the upper piezoelectric layer is under tensile strain and the lower layer is under compressive strain. The result is a positive and negative voltage across the beam. As the mass oscillates back and forth, an alternating voltage is created. But because this energy generator is relatively large, gravity is important in driving its oscillating mass.

Now my research group at the Georgia Institute of Technology is working on piezoelectric power generation at the nano­scale. And at the nano­scale, things change. Gravity, which plays such a critical role in the larger world, is a very minor actor in the nano­world as compared with the forces of chemical bonding and intermolecular attraction.

Where Gravity Doesn’t Matter
The force of gravity is not available to us on a useful scale in the nano­world. If one attempted to construct a piezoelectric generator with a nano­meter-scale beam, gravity would make almost no contribution to sustaining the beam’s motion, and the device would not work. Therefore, we need another method to build a nano­-size generator for powering autonomous devices. Our team has been exploring innovative nano­­technologies for converting mechanical energy (such as body movement and muscle stretching), vibration energy (such as acoustic and ultrasonic waves) and hydraulic energy (such as the flow of blood and other bodily fluids) into electric energy to power nano­devices.

My research focused on carbon nano­tubes in the late 1990s. We invented a few techniques for measuring the mechanical, electrical and field-emission properties of individual carbon nano­tubes using in situ microscopy. But we could not control a nano­tube’s electrical properties. I immediately realized that metal oxides are a new world—and why not explore those nano­struc­tures? In 2000 I started with nano­belts, white woollike products made by baking a metal oxide such as zinc in the presence of argon gas at 900 to 1,200 degrees Celsius, and with nano­wires.

Our research has become focused on aligned zinc oxide nano­wires, each of them a perfect six-sided, columnlike crystal that is grown on a solid conductive substrate using a standard vapor-liquid-solid process in a small tube furnace. We deposit gold nano­particles, which serve as catalysts, on a sapphire substrate. An argon gas carrier flows through the furnace as a zinc oxide powder is heated. The nano­wires then grow underneath the gold particles. The typical diameter of the nano­wires is 30 to 100 nano­meters, and they measure one to three microns in length.

The idea of converting mechanical energy into electricity came to my mind around August 2005, when we were measuring the electromechanical coupled properties of the wires. Using an atomic force microscope (AFM), we observed some voltage output peaks, but we were not sure what they were. We did systematic work through November of that year and learned that the voltage was from the piezoelectric effect of the zinc oxide; our results excluded the contribution from friction, contact or other confounding arti­facts. The next step was determining what the process was for the charge output from a single nano­wire. After studying a book on semiconductor devices, I proposed the working mechanism of what would become the nano­generator.

Zinc oxide has the rare attribute of possessing both piezoelectric and semiconducting properties, which we put to use in creating and accumulating piezoelectric charges in the nano­wires. We have shown that when the conductive tip of an AFM bends a straight, vertical nano­wire, a strain field is established, with the stretched surface showing positive strain and the compressed surface showing negative strain. As the tip scans over the top of the zinc oxide nano­­wires, we observe many peaks in the corresponding voltage output image for each contact position [see box on page 84]. The piezoelectric effect creates an electric field inside the nano­wire’s volume, with the stretched and compressed sides of the wire showing positive and negative voltages.

The idea came first, but we needed experimental support. Just before Christmas 2005, I designed an experiment to visualize directly the voltage output of a large wire under optical and AFM microscopy. My student and I did the experiments, and one evening in late December, we were rewarded with several videos that directly proved my model. The next day I worked with Jinhui Song in my office to edit the movie. Then we sent the paper to Science for publication.

To be useful in practical applications, our nano­generator needs to contain an array of nano­­wires, all of them continuously generating electricity that can be collected and delivered to a device. And the energy to be converted into electricity has to come in the form of a wave or vibration from the environment so the nano­generator can operate independently and wirelessly. We have developed a novel design that addresses these requirements.

The next challenge was to increase the power of the nano­­generator. Three objectives have to be achieved: eliminate the use of the AFM, make many nano­wires generate electricity simultaneously and continuously, and excite the nano­­wires in an indirect wave, such as an ultra­sonic wave. I came out with a new design using a ridged electrode to replace the AFM tips and presented the idea to my postdoctoral assistant, Xudong Wang. It took him about four months of experiments before compiling the first group of data. The signal was rather small. From May to October 2006 we focused on the optimum packaging of the nano­­generator to enhance its output. By the end of the year we realized that the nano­­generator could at last be reported to the scientific community.

Our experimental setup provided the first demonstration of continuous direct current produced by a piezo­electric nano­­generator. It consists of an array of parallel zinc oxide nano­wires and a platinum-coated silicon electrode with a ridged surface in place of the microscope’s tip. Coating the electrode with platinum both enhances its conductivity and causes it to act like a diode that allows current to flow in only one direction, from metal to semi­conductor. The electrode is placed above the nano­­wire array at a controlled distance and can be moved laterally so that it bends the nano­­wires from side to side. Thanks to its surface ridges, the electrode acts like an array of aligned microscope tips.

Flexible Future
Since January 2007 we have been fully involved in improving our nano­generator. The ceramic or semiconductor substrates that we initially used for growing zinc oxide nano­wires are hard and brittle, for instance, making them unsuitable for applications that require a foldable or flexible power source, such as biosensors implanted in muscles or joints, or power generators built into shoes.

Here is where conductive polymers can provide a substrate that is likely to be biocompatible. In experiments we discovered that many available flexible plastic substrates are suitable for growing the zinc oxide nano­wire arrays, which ultimately could find applications in portable and flexible electronics. Because of the flexibility of the substrate, the nano­wire surface profile was wavy, causing some missed contacts. We believe that providing suitable bonding strength between the nano­wires and substrate as well as optimizing the wire spacing will be important in increasing discharge efficiency.

Although our approach has demonstrated the principle of the nano­generator, we must drastically improve its performance to make it practical. All the nano­wires must generate electricity simultaneously and continuously, and all the electricity must be effectively collected and distributed. A large-scale method for growing zinc oxide nano­wires can be cost-effective because it does not require expensive high-temperature manufacturing processes. Hurdles that lie ahead in our research include learning how to grow perfectly uniform arrays of nano­wires that all produce electricity and how to extend their working life. The lifetime of the current nano­generator is about 50 hours. The main reason for the device’s failure is likely the packaging technology for assembling the top electrode and the nano­wire arrays. If the electrode presses on the nano­wires too firmly, for example, no current will be generated. We are working hard to improve the packaging.

The process used to produce the arrays involves evaporating a thin layer of gold onto the substrate, where it acts as a catalyst for nano­wire growth. The zinc oxide crystals look something like a forest without branches. To improve the adhesion of the nano­wires with the substrate, we have added a thin layer of polymer onto the substrate after growth so that the roots of the nano­wires are partially embedded. We have achieved electrical output of about 10 milli­volts and 800 nano­amperes from a nano­generator that is about six square millimeters in size. We have also shown that nano­generators can be arranged in series to improve the output voltage and in parallel to improve the output current, as is commonly done with power sources such as batteries or fuel cells. But to produce higher voltages, we need to make nano­wires with identical height and diameter.

Nano­generators may never power our homes or even our flashlights; the amount of power available from them will be quite small. But nano­wire arrays can be ideal generators for devices that need to work only intermittently, such as sensors that collect and transmit data for one second of every minute. In the years to come, nano­­generators will be used to harvest and recycle the energy wasted in our daily life, such as that created by pressure changes in a car tire, a moving vehicle’s mechanical vibration or even the fluttering surface of a camper’s tent. Consider how many small energy resources are all around us.