Scientists discover method to boost energy generation from microalgae


Date:
October 18, 2021
Source:
Nanyang Technological University
Summary:
The variety of humble algae that cover the surface of ponds and
seas could hold the key to boosting the efficiency of artificial
photosynthesis, allowing scientists to produce more energy
and lower waste in the process. A study showed how encasing
algae protein in liquid droplets can dramatically enhance the
algae's light-harvesting and energy-conversion properties by up
to three times. This energy is produced as the algae undergoes
photosynthesis, which is the process used by plants, algae and
certain bacteria to harness energy from sunlight and turn it into
chemical energy. When light hits the droplet, light waves travel
around the curved edges of the droplet. Light is effectively
trapped within the droplet for a longer period of time, giving
more opportunity for photosynthesis to take place, hence generating
more energy.



FULL STORY ==========================================================================
The variety of humble algae that cover the surface of ponds and seas could
hold the key to boosting the efficiency of artificial photosynthesis,
allowing scientists to produce more energy and lower waste in the process.


==========================================================================
A study by Nanyang Technological University, Singapore (NTU Singapore) scientists showed how encasing algae protein in liquid droplets can dramatically enhance the algae's light-harvesting and energy-conversion properties by up to three times. This energy is produced as the algae
undergoes photosynthesis, which is the process used by plants, algae
and certain bacteria to harness energy from sunlight and turn it into
chemical energy.

By mimicking how plants convert sunlight into energy, artificial
photosynthesis may be a sustainable way of generating electricity that
does not rely on fossil fuels or natural gas, which are non-renewable. As
the natural energy conversion rate from sunlight to electricity is
low, boosting the overall electricity produced could make artificial photosynthesis commercially viable.

The study, led by Assistant Professor Chen Yu-Cheng from the School of Electrical and Electronic Engineering, looked at a particular type of
protein found in red algae. These proteins, called phycobiliproteins,
are responsible for absorbing light within algae cells to kick-start photosynthesis.

Phycobiliproteins harvest light energy from across the spectral range
of light wavelengths, including those which chlorophylls absorb poorly,
and convert it to electricity.

Asst Prof Chen said: "Due to their unique light-emitting and
photosynthetic properties, phycobiliproteins have promising potential applications in biotechnology and solid-state devices. Boosting the
energy from the light- harvesting apparatus has been at the centre of development efforts for organic devices that use light as a power source."
The team's research may lead towards a new, sustainable way of generating electricity from sunlight that does not rely on fossil fuels or natural
gas, which are non-renewable. New bio-inspired technology based on phycobiliproteins could be used to make more efficient solar cells and
paves the way for greater efficiency within artificial photosynthesis.



========================================================================== Using algae as a source of biological energy is a popular topic
of interest in sustainability and renewable energy, as algae usage
potentially reduces the amount of toxic by-products created in the manufacturing of solar panels.

The study supports NTU's commitment to sustainability as part of its
2025 strategic plan, which seeks to understand, articulate, and address humanity's impact on the environment.

The findings were published and selected as the cover of scientific
journal ACS Applied Materials Interfaces.

Tripling artificial photosynthesis efficiency Microalgae absorb sunlight
and convert it into energy. In order to amplify the amount of energy
that algae can generate, the research team developed a method to encase
red algae within small liquid crystal micro-droplets that are 20 to 40
microns in size and exposed them to light.



==========================================================================
When light hits the droplet, an effect known as the "whispering-gallery
mode" occurs, in which light waves travel around the curved edges of
the droplet.

Light is effectively trapped within the droplet for a longer period of
time, providing more opportunities for photosynthesis to take place and
hence generating more energy.

The energy generated during photosynthesis in the form of free electrons
can then be captured through electrodes as an electrical current.

"The droplet behaves like a resonator that confines a lot of light," said
Asst Prof Chen. "This gives the algae more exposure to light, increasing
the rate of photosynthesis. A similar result can be obtained by coating
the outside of the droplet with the algae protein too." "By exploiting microdroplets as a carrier for light-harvesting biomaterials, the strong
local electric field enhancement and photon confinement inside the
droplet resulted in significantly higher electricity generation," he said.

The droplets can be easily produced in bulk at low cost, making the
research team's method widely applicable.

According to Asst Prof Chen, most algae-based solar cells produce an
electrical power of 20-30 microwatts per square centimetre (myW/cm2). The
NTU algae- droplet combination boosted this level of energy generation
by at least two to three times, compared to the energy generation rate
of the algae protein alone.

Converting "bio-trash" to bio-energy Artificial photosynthesis aims to replicate the natural biological process by which plants convert sunlight
into chemical energy. The goal is to establish a way of making energy renewable, reliable, and storable without impacting the environment in
a negative way.

One of the challenges of artificial photosynthesis is generating energy
as efficiently as other solar-powered energy sources, such as solar
panels. On average, solar panels have an efficiency rating of 15 to 20
per cent while artificial photosynthesis is currently estimated to be
4.5 per cent efficient.

Asst Prof Chen said: "Artificial photosynthesis is not as efficient as
solar cells in generating electricity. However, it is more renewable
and sustainable.

Due to increasing interest in environmentally-friendly and renewable technologies, extracting energy from light-harvesting proteins in
algae has attracted substantial interest in the field of bio-energy."
Asst Prof Chen envisions one potential use case of "algae farms," where densely-growing algae in bodies of water could eventually be combined
with larger liquid crystal droplets to create floating power generators.

"The micro-droplets used in our experiments has the potential to be
scaled up to larger droplets which can then be applied to algae outside
of a laboratory environment to create energy. While some might consider
algae growth to be unsightly, they play a very important role in the environment. Our findings show that there is a way to convert what some
might view as 'bio-trash' into bio-power," said Asst Prof Chen.

========================================================================== Story Source: Materials provided by
Nanyang_Technological_University. Note: Content may be edited for style
and length.


========================================================================== Journal Reference:
1. Zhiyi Yuan, Xin Cheng, Tsungyu Li, Yunke Zhou, Yifan Zhang,
Xuerui Gong,
Guo-En Chang, Muhammad D. Birowosuto, Cuong Dang, Yu-Cheng
Chen. Light- Harvesting in Biophotonic Optofluidic Microcavities
via Whispering- Gallery Modes. ACS Applied Materials & Interfaces,
2021; 13 (31): 36909 DOI: 10.1021/acsami.1c09845 ==========================================================================

Link to news story: https://www.sciencedaily.com/releases/2021/10/211018105926.htm

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