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. 2021 Dec 1;8:37. doi: 10.1186/s40580-021-00289-0

Table 2.

Features and characterization of some previously developed nano-systems to harvest renewable energy from natural resources (wind, ocean and solar resources)

Energy conversion Mechanism Input Output Advantages () and disadvantages (↓)
Electromagnetic generators (EMG) Portable wind energy harvester based on S-rotor and H-rotor 5–12 m/s 108 mW, 23.2%

() powers the monitoring sensors in railway tunnels

() uses hybrid S-rotor and H-rotor

Double-Skin Façade system for harvesting wind energy 3–8 m/s 1110 W/m2

() low turbulence and uniform flow due to cavity

(↑) provides a wide range of angles for incident wind

Galloping, vortex shedding, flutter, and aerodynamic instability 2–6 m/s 1 W

(↑) based on wake galloping

(↑) a simpler mechanism for structural health monitoring system

(↑) powers wireless sensors

Piezoelectric nanogenerators (PENG) The flutter of a flexible piezoelectric membrane 9 m/s 5 mW/cm3

(↑) simple inverted flag orientation

(↑) Self-aligning capability

(↑) can operate in low-speed regimes

Vortex-induced vibration-based piezoelectric EH 1–1.4 m/s 0.6 mW

(↑) facilitates Y-shaped attachments on bluff body

(↑) provides an enhanced energy harvesting efficiency

MEH is composed of permanent magnets, rotor, piezoelectric stack, and flexure mechanism 100 rpm 0.2 mW

(↑) simple and compact design

(↑) optimal performance with a larger power output

Pyroelectric (PEG)/ Thermoelectric generators (TEG) Flexible vortex generator or turbulator 1–25 m/s 3 μ W/cm2

(↑) Flexible structure with un-interrupted energy output

(↓) possesses low pyroelectric coefficient

Harvesting solar and wind energies using thermal

oscillations through sustainable PEG

2.5–5.3 m/s 421 μ W/cm3

(↑) provides high power density

(↓) power density depends on the intensity of the solar irradiations and wind speed

Triboelectric nanogenerators (TENG) A rotary TENG based on mechanical deformation of multiple plates 15 m/s 39 W/m2

(↑) facilitates the application of polymer nanowires

(↑) can be used as a self-powered wind speed sensor

TENG-based windmill composed of nanopillar-array architectured layers 14–15 m/s 568 V, 26 μA

(↑) simple and cheap fabrication

(↑) high output and optimal performance

(↑) high stability

Pendulum-based TENG using a pendulum structure with high energy conversion efficiency 2 m/s, 2 Hz 56 V

(↑) superior durability

(↑) ultrahigh sensitivity

(↑) long-time operation

(↑) energy harvesting from wave and wind

The references of the research papers cited in this table are provided in the Additional file 1