Energy harvester for electrostatic energy

What is claimed is: 1. An energy harvester comprising: a lower electrode; a ferroelectric material layer which is disposed on the lower electrode and formed of a negatively poled ferroelectric material or a positively poled ferroelectric material; and a friction-charged body which is adapted to be repeatedly contacted and separated from the ferroelectric material layer, has an electric susceptibility different from an electric susceptibility of the ferroelectric material layer, and functions as an upper electrode to exchange electrons with the lower electrode, wherein the ferroelectric material layer is formed of the negatively poled ferroelectric material and has a negative charging property in relation to the friction-charged body, or wherein the ferroelectric material layer is formed of the positively poled ferroelectric material and has a positive charging property in relation to the friction-charged body. 2. The energy harvester of claim 1 , wherein the friction-charged body and the ferroelectric material layer have opposite charging characteristics. 3. The energy harvester of claim 1 , wherein the friction-charged body generates triboelectricity when the friction-charged body is separated from the ferroelectric material layer and the friction-charged body is in contact with the ferroelectric material layer. 4. The energy harvester of claim 1 , wherein the ferroelectric material layer comprises at least one of polyvinylidene difluoride (PVDF), lead zirconate titanate (PZT), platinum oxide (PTO), Barium tin oxide (BTO), bismuth ferric oxide (BFO), KNbO3, NaNbO3, and GeTe. 5. The energy harvester of claim 1 , wherein the friction-charged body comprises metal. 6. The energy harvester of claim 1 , wherein the ferroelectric material layer comprises polyvinylidene difluoride (PVDF), and the friction-charged body comprises aluminum (Al). 7. The energy harvester of claim 6 , wherein the ferroelectric material layer comprising PVDF is negative-poled. 8. The energy harvester of claim 1 , wherein a type of poling applied to the ferroelectric material layer corresponds to charging characteristics of the ferroelectric material layer with respect to the friction-charged body. 9. The energy harvester of claim 1 , further comprising: outgoing lines connected to the lower electrode and the friction-charged body, respectively; and a storage battery connected to the outgoing lines. 10. The energy harvester of claim 9 , further comprising: a first rectifying diode connected between one of the outgoing lines and the storage battery; and a second rectifying node connected between another one of the outgoing lines and the storage battery. 11. An electronic device comprising an energy harvester, wherein the energy harvester comprises a lower electrode; a ferroelectric material layer which is disposed on the lower electrode and formed of a negatively poled ferroelectric material or a positively poled ferroelectric material; and a friction-charged body which is adapted to be repeatedly contacted and separated from the ferroelectric material layer, has an electric susceptibility different from an electric susceptibility of the ferroelectric material layer, and functions as an upper electrode to exchange electrons with the lower electrode, wherein the ferroelectric material layer is formed of the negatively poled ferroelectric material and has a negative charging property in relation to the friction-charged body, or wherein the ferroelectric material layer is formed of the positively poled ferroelectric material and has a positive charging property in relation to the friction-charged body. 12. A method of controlling a ferroelectric material layer and a friction-charged body of an energy harvester, the method comprising: applying a type of poling to the ferroelectric material layer based on charging characteristics of the ferroelectric material layer with respect to the friction-charged body; making contact between the ferroelectric material layer and the friction-charged body to flow electrons directly from the friction-charged body to the ferroelectric material layer; and separating the ferroelectric material layer from the friction-charged body to flow electrons out of a lower electrode through a wire connected to the friction-charged body, wherein the ferroelectric material layer is formed of a negatively poled ferroelectric material and has a negative charging property in relation to the friction-charged body, or wherein the ferroelectric material layer is formed of a positively poled ferroelectric material and has a positive charging property in relation to the friction-charged body.