Materials Science: Revolutionizing Batteries, Biomaterials and Advanced Polymers
eBook
Published: November 6, 2024
Credit: Technology Networks
Advances in materials science are transforming fields ranging from energy storage to healthcare. However, designing materials that meet the increasing demands of modern applications comes with challenges, such as improving efficiency, sustainability and adaptability. Overcoming these obstacles will be critical to unlocking next-gen solutions.
This eBook explores groundbreaking research shaping the future of batteries, biomaterials and polymers, offering valuable insights into their real-world applications.
Download this eBook to explore:
- The latest innovations in battery design for renewable energy storage
- How biomaterials are accelerating tissue regeneration and medical breakthroughs
- Analytical techniques used in polymer science to enhance performance across industries
Credit: iStock
SHAPE-SHIFTING
BIOMATERIALS FOR
TISSUE REGENERATION
SUPERCHARGING
BATTERIES WITH IMPROVED
MATERIAL DESIGN
EXPLORING THE
TECHNIQUES USED IN
POLYMER ANALYSIS
MATERIALS
SCIENCE
Revolutionizing Batteries, Biomaterials
and Advanced Polymers
CONTENTS
04
Exploring the World of
Medical Biomaterials
07
Could Hydrogel Help Mend
a Broken Heart?
09
Shape-Shifting Biomaterials
for Tissue Regeneration
12
Analytical Techniques in the
Battery Lifecycle
16
Common Techniques in Battery
Material Analysis
17
Innovative Hydrogel Dressing To
Accelerate Diabetic Wound Healing
20
Supercharging Batteries With
Improved Material Design
22
Exploring the Techniques Used in
Polymer Analysis
MATERIALS SCIENCE: REVOLUTIONIZING BATTERIES, BIOMATERIALS AND ADVANCED POLYMERS 3
TECHNOLOGYNETWORKS.COM
FOREWORD
The field of material science is experiencing a remarkable transformation. From enhancing
battery storage for renewable energy to developing biomaterials that interact seamlessly
with human tissue, the possibilities seem limitless.
This eBook explores key developments in materials science, shedding light on the
innovative approaches that are shaping the future. Whether it’s the creation of stronger,
more flexible polymers for medical use or breakthroughs in battery technology
that promise cleaner energy solutions, the chapters ahead delve into the materials
revolutionizing industries and improving lives.
By weaving together insights from cutting-edge research and practical applications,
this eBook offers readers a glimpse into the future of material science and its impact on
technology and sustainability.
The Technology Networks editorial team
The rapid development of new biomaterials is changing the
healthcare landscape. Biomaterials are materials designed to
safely interact with biological systems to support, improve or
replace natural processes. In 2022, the biomaterials market
reached $155 billion and is predicted to grow by 15.5% over
the next two decades.1
This investment is helping to unlock
new treatment strategies, from advanced prostheses and
implantable devices to cutting-edge drug delivery systems
and tissue regeneration techniques.
This listicle will explore the different types of
biomaterials, highlight their diverse properties and
discuss how they are being applied to accelerate
advanced medical treatments.
What are biomaterials?
A comprehensive definition of a “biomaterial” is difficult to
achieve; it has evolved over the years as the field has grown
and developed. The most widely accepted description
defines a biomaterial as a substance that has been
intentionally designed to interact with biological systems,
whether for the treatment, augmentation or replacement of
a biological function.
Significant research into biomaterials began in the late 1960s,
with an initial interest in materials that were “inert”. Early
applications focused on dental and surgical treatments, such
as the use of titanium for orthopedic and dental implants.2
Since then, the number of available biomaterials has grown
rapidly. Broadly, biomaterials can be grouped based on their
primary material and the properties of that material.
Types of biomaterials
Metals
Metals have played a role in medical implants for over
a century, ever since metal plates were first used to fix
bone fractures.3
MATERIAL SCIENCE
Exploring the World of
Medical Biomaterials
Steven Gibney, PhD
4
Credit: iStock
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MATERIALS SCIENCE: REVOLUTIONIZING BATTERIES, BIOMATERIALS AND ADVANCED POLYMERS 5
However, early attempts at metal implants often
suffered from corrosion issues. This is exemplified by
Sherman vanadium steel which, despite its relatively
high hardness, displayed poor corrosion resistance
when implanted in a biological environment.4 Since
then, more advanced metallic materials have been
developed, including titanium alloys, stainless steel
alloys and cobalt–chromium alloys.5
These metals
are biocompatible and corrosion resistant, ensuring
any implants made from them will maintain structural
integrity. This also makes them safer than their historical
counterparts.
The properties of metallic biomaterials make them
ideal for load-bearing applications that require
sufficient strength to withstand constant daily activity.
This includes good physical strength, durability and
a high elastic modulus. One of the most common
applications for metallic biomaterials is artificial
joints and orthopedic implants, such as hip and knee
replacements.6
On a smaller scale, zinc- and magnesiumbased alloys have been used to create cardiovascular
stents, small mesh tubes that are used to expand
narrowed or blocked coronary arteries.7
Ceramics
Ceramic biomaterials share many properties and
applications with their metallic counterparts. This
includes their high physical and mechanical strength,
resistance to wear and generally good biocompatibility.
However, bioceramics have several advantages when
compared directly to metallic biomaterials, such as a
higher melting temperature, extreme corrosion resistance,
improved mechanical properties and a biocompatibility
exceeding that of most metals.8
This combination of properties makes ceramic
biomaterials well-suited for applications where
durability and biocompatibility are crucial. Ceramics
such as zirconia, also known as zirconium dioxide,
are used extensively in dental implants, where their
biocompatibility and resemblance to natural tooth
structure make them successful replacements in
dental procedures.9
Ceramics such as alumina and
hydroxyapatite are employed in bone grafts and joint
replacements and can also be used as coatings to reduce
the wear and inflammatory response to larger implants.8
Polymers (natural and synthetic)
Polymers represent one of the widest categories of
biomaterials, encompassing both synthetic polymers,
like polyethylene, and natural polymers, such as
collagen. Polymeric biomaterials are valued for their
versatility; the wide range of unique polymers available
makes it possible to tailor their design to meet specific
medical needs.
Natural polymers have already been the subject of
much study. For example, collagen – a natural protein
present in skin and other connective tissues – has been
widely used in the preparation of biological scaffolds
and implants for tissue engineering and regeneration.8
Other natural polymers like fibrin, keratin, fibronectin
and laminin have also been investigated as biomaterials
for tissue engineering applications.10 Fibrin derived from
blood can function as a natural sealant during surgeries,
while decellularized matrices created by removing
cellular components from tissues provide a framework
for tissue regeneration.10,11 The integration of naturally
occurring polymers as a biomaterial ensures a seamless
interaction with the body, making them extremely
biocompatible solutions for tissue repair, regeneration
and transplantation.
Synthetic polymers, such as nylon, polyethylene and
polyester, can be heavily modified and engineered
to suit a specific need. Synthetic polymers are also
useful substitutes for patients with an allergy to certain
natural polymers, as they are less immunogenic. The
ability to modify synthetic polymers by adjusting their
monomer structure makes it easy to adjust material
properties to suit a specific need. This can include
tweaking the physical or chemical properties to
improve biodegradability, making them more suitable
for tissue engineering applications.12 This also makes
synthetic polymers valuable for the development of
implantable devices, where polymers such as polylacticco-glycolic acid (PLGA), polyvinyl alcohol (PVA) and
polyvinylpyrrolidone (PVP) can be manufactured into
3D scaffolds using different methods, such as 3D printing,
freeze-drying or electrospinning.13,14
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MATERIALS SCIENCE: REVOLUTIONIZING BATTERIES, BIOMATERIALS AND ADVANCED POLYMERS 6
There is similar interest in the use of synthetic polymers
for drug delivery applications, where polymers can be
used to improve the efficacy of therapeutics, extend
the release of compounds or target specific biological
systems.15
Composite/hybrid materials
Composite or hybrid biomaterials are created by
combining different materials to create a product that
possesses the optimal properties of their individual
components. This ability to create custom combinations
of biomaterials unlocks new avenues of interest when
designing medical solutions. For instance, a combination
of natural collagen and synthetic PLGA can be
used to manufacture structures that display unique
combinations of physicochemical properties including
elasticity and strength, making them suitable for
bone and soft tissue regeneration.16 Likewise, ceramic
and metal biomaterials can be directly combined or
mixed with polymers to create more effective joint
replacements or for tissue reconstruction.16,17 The sheer
number of possible combinations of biomaterials means
that hybrid design is expected to become increasingly
popular, allowing researchers to tune the properties of
their material to their desired solution.
The future of biomaterials
Biomaterials have already brought about transformative
innovations that have reshaped patient care and disease
management. Ongoing research is laying the foundation
for groundbreaking developments in biomaterials, from
new types of materials to novel applications. This progress
will also benefit from wider advances in technology, such
as the use of 3D printing for personalized implants and
the development of smart biomaterials that dynamically
respond to physiological cues.
Likewise, the integration of data-driven design and
artificial intelligence (AI) solutions will accelerate
the design and optimization of key biomaterials.
The convergence of multidisciplinary approaches
and emerging technologies will no doubt unlock
new frontiers in the development and application of
biomaterials, contributing to more personalized and
effective medical treatments. •
REFERENCES
1. Grand View Research. Biomaterials Market Size, Share &
Trends Analysis Report By Product (Natural, Metallic, Polymer),
By Application (Cardiovascular, Orthopedics, Plastic Surgery),
By Region, And Segment Forecasts, 2023 – 2030. https://www.
grandviewresearch.com/industry-analysis/biomaterialsindustry. Accessed January 2, 2024.
2. Vallet-Regí, M. Evolution of biomaterials. Front Mater.
2022;9:864016. doi:10.3389/fmats.2022.864016
3. Uhthoff HK, Poitras P, Backman DS. Internal plate fixation of
fractures: short history and recent developments. J Orthop Sci.
2006;11(2):118-126. doi:10.1007/s00776-005-0984-7
4. Szczęsny G, Kopec M, Politis DJ, Kowalewski ZL, Łazarski A,
Szolc T. A review on biomaterials for orthopaedic surgery
and traumatology: From past to present. Materials (Basel).
2022;15(10):3622. doi:10.3390/ma15103622
5. Prasad K, Bazaka O, Chua M, et al. Metallic biomaterials:
current challenges and opportunities. Materials.
2017;10(8):884. doi:10.3390/ma10080884
6. Davis R, Singh A, Jackson MJ, et al. A comprehensive review
on metallic implant biomaterials and their subtractive
manufacturing. Int J Adv Manuf Technol. 2022;120(3-4):1473-
1530. doi:10.1007/s00170-022-08770-8
7. Fu J, Su Y, Qin YX, Zheng Y, Wang Y, Zhu D. Evolution of
metallic cardiovascular stent materials: A comparative study
among stainless steel, magnesium and zinc. Biomaterials.
2020;230:119641. doi:10.1016/j.biomaterials.2019.119641
8. Vaiani L, Boccaccio A, Uva AE, et al. Ceramic materials for
biomedical applications: an overview on properties and
fabrication processes. J Funct Biomater. 2023;14(3):146.
doi:10.3390/jfb14030146
9. Mussano F, Genova T, Munaron L, Faga MG, Carossa S.
Ceramic biomaterials for dental implants: current use and
future perspectives. In: Dental Implantology and Biomaterial.
IntechOpen; 2016. doi:10.5772/62701
10. Kalirajan C, Dukle A, Nathanael AJ, Oh TH, Manivasagam
G. A critical review on polymeric biomaterials for biomedical
applications. Polymers. 2021;13(17):3015. doi:10.3390/
polym13173015
11. Canonico S. The use of human fibrin glue in the surgical
operations. Acta Biomed. 2003;74 Suppl 2:21-25.
PMID:15055028
12. Maitz, MF. Applications of synthetic polymers in clinical
medicine. Biosurface and Biotribology. 2015;1(3):161-176.
doi:10.1016/j.bsbt.2015.08.002
13. Xia D, Chen J, Zhang Z, Dong M. Emerging polymeric
biomaterials and manufacturing techniques in regenerative
medicine. Aggregate. 2022;3(5):e176. doi:10.1002/agt2.176
14. Teo AJT, Mishra A, Park I, Kim YJ, Park WT, Yoon YJ.
Polymeric biomaterials for medical implants and devices.
ACS Biomater Sci Eng. 2016;2(4):454-472. doi:10.1021/
acsbiomaterials.5b00429
15. Fenton OS, Olafson KN, Pillai PS, Mitchell MJ, Langer R.
Advances in biomaterials for drug delivery. Adv Mater.
doi:10.1002/adma.201705328
16. Lei B, Guo B, Rambhia KJ, Ma PX. Hybrid polymer biomaterials
for bone tissue regeneration. Front Med. 2019;13(2):189-201.
doi:10.1007/s11684-018-0664-6
17. Affatato S, Spinelli M, Squarzoni S, Traina F, Toni A. Mixing
and matching in ceramic-on-metal hip arthroplasty: an invitro hip simulator study. J Biomech. 2009;42(15):2439-2446.
doi:10.1016/j.jbiomech.2009.07.031
7 MATERIALS SCIENCECredit: iStock
How do you un-break a heart? Well, if that broken heart
belongs to Toni Braxton, you just need to say you’ll love her
again. But for anybody else, a different approach is in order.
Chemical engineers are one step closer to being able
to repair damaged hearts, with researchers from the
University of Waterloo, the University of Toronto and
Duke University creating a new synthetic material that can
replicate the biomechanical properties of human tissues.
The material has been described in a new paper
published in the journal PNAS.
Biomimetic hydrogels
Great strides have been made in the field of tissue
engineering in recent years. However, current
advancement has been somewhat limited by a lack
of materials that can properly mimic the native
nanofibrillar structures found in biological tissue.
Another unique aspect of these fibrous networks
formed by collagen or fibrin inside biological tissues is
that they undergo a very strong stiffening response to
shear and elongational strain forces, but soften when
compressed. This mechanical behavior is rarely found in
the synthetic materials developed for tissue engineering.
Now, a team of researchers has designed a new hydrogel
that can overcome these hurdles.
Their hydrogel is made from gelatin and wood pulpderived cellulose nanocrystals. Scanning electron
microscope images showed that the material has a
fibrous nanostructure with large pores that can deal
Could Hydrogel Help Mend
a Broken Heart?
Alex Beadle
Credit: iStock
TECHNOLOGYNETWORKS.COM
MATERIALS SCIENCE: REVOLUTIONIZING BATTERIES, BIOMATERIALS AND ADVANCED POLYMERS 8
with nutrient and waste transport, similar to biological
tissue.
What is a hydrogel?
A hydrogel is a three-dimensional network of
crosslinked, hydrophilic polymers that can swell to
hold large volumes of water. They are a popular material
choice as a scaffold in tissue engineering, with their high
water content providing a good environment for cell
survival.
The team also carried out experimental strain stiffening
tests, to see if their material also exhibited the unusual
stiffening and softening responses that biological fibrous
networks do. These tests confirmed that the hydrogel
had comparable mechanical properties to biological
networks, with it performing very similarly to samples of
fibrin gel.
Hydrogels for cancer treatment,
heart attack recovery
The researchers have successfully used their tissuemimetic hydrogels to promote the growth of small-scale
tumor replicas known as organoids. These are derived
from donated tumor tissue, as described in a previous
study.
“Hydrogels that mimic the structure and properties of
human tissues can recreate that environment for cells
in a controlled setting,” explained first author Prof.
Elisabeth Prince, director of the Prince Polymer
Materials Lab, speaking to Technology Networks.
“Growing tumor organoids in a biomimetic environment
allows them to maintain their in vivo phenotype better,
making them a better in vitro model of tumors. Also,
it has tissue-mimetic hydrogels that can potentially
support the healing of damaged tissues.”
Prince and her team are currently aiming to test the
effectiveness of cancer treatments on these organoids,
with the idea of one day administering these treatments
to patients in personalized cancer therapies. Another
aim of her work is to develop injectable versions of this
fibrous hydrogel material that can help to regrow heart
tissue that has been damaged by a heart attack.
“[These hydrogels] can be used as an in vitro platform
for developing personalized cancer therapies and can
serve as a scaffold for regeneration of damaged tissues,”
Prince said. The tissue-like structure of the hydrogel,
with its nanofibers, makes it well-suited to being a
scaffold material.
Next, Prince and her team are hoping to exploit the
composite nature of these hydrogels by experimenting
with different nanoparticles to try to add more
functionality to the material. “We are trying to develop
conductive versions of these biomimetic hydrogels to
support electrical signaling in damaged cardiac and
skeletal muscle tissue,” Prince said. •
Prof. Elisabeth Prince was speaking to Alexander Beadle,
Science Writer for Technology Networks.
ABOUT THE INTERVIEWEE:
Prof. Elisabeth Prince is an assistant professor in the Department
of Chemical Engineering at the University of Waterloo. Her
research interests lie at the interface of soft matter design,
polymer chemistry, biomimetic materials and sustainability.
REFERENCE:
1. Prince E, Morozova S, Chen Z, et al. Nanocolloidal
hydrogel mimics the structure and nonlinear mechanical
properties of biological fibrous networks. PNAS.
2023;120(51):e2220755120. doi: 10.1073/pnas.2220755120
9 MATERIALS SCIENCE
Consider the humble pinecone. Found scattered on
forest floors and covered in woody scales, the pinecone
is a perfect example of nature’s clever shape-shifting
engineering. When it is wet and humid, the scales stay
closed, protecting the seeds. But when it is dry – ideal
conditions for the seeds to disperse – the scales open
and they are released.
This naturally occurring shape-shifting structure
inspired Skylar Tibbits, associate professor of design
research at the Massachusetts Institute of Technology,
in 2013 to design similarly "smart" materials for
architecture and engineering. Think climate-adaptive
building facades that can expand, contract or rotate in
response to the outdoor temperature and sunlight, or
flatpack furniture that self-assembles when you take it
home. Enter the 4D printing revolution. This approach
transcends the limitations of the static structures
produced by 3D printing by adding a fourth dimension:
time. Similar to the pinecone that closes its scales when
wet, 4D materials are designed to autonomously change
shape in response to a stimulus in their environment,
such as humidity, temperature, light, pressure or
magnetism.
These shape-shifting materials are not just for
architectural design. In recent years, 4D printing has
become a transformative technology in the biomedical
field, offering the potential to create smart biomaterials
that change shape in response to specific physiological
stimuli. In contrast to the passive materials that are
traditionally used for tissue engineering, 4D printed
materials are dynamic and can adapt to the constantly
changing needs of the living body.
So, how are these materials used in healthcare? 4D
materials are first fabricated using 3D printing, then
triggered by a stimulus to change their shape. This shape
shift can be leveraged for deployable medical devices
such as stents or orthopedic implants.
Shape-Shifting Biomaterials for
Tissue Regeneration
Kaja Ritzau-Reid, PhD
Credit: iStock
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MATERIALS SCIENCE: REVOLUTIONIZING BATTERIES, BIOMATERIALS AND ADVANCED POLYMERS 10
Rather than undergoing invasive surgery during
implantation, materials can take on a temporary
compact structure during surgery and then be deployed
to their final full-size shape once they have reached the
target location in the body.
Some materials also benefit from being printed in a flat
2D configuration first. As Amir Zadpoor, a professor
of biomaterials and tissue biomechanics at Delft
University of Technology explains: “When the initial
configuration of these materials is flat, it creates many
opportunities for adding surface-related functionalities,
including complex nanopatterns and electronic devices.”
This can be particularly useful for creating complex
surface nanopatterns that stimulate certain cells, or even
kill bacteria, preventing infections upon implantation in
the body.
Shape-shifting mechanisms
To create smart biomaterials there are several key
requirements. Materials need to be compatible with
modern 3D printing techniques (e.g., extrusion-based,
light-based, bioprinting), be biocompatible and have
the capability to undergo shape change in response to a
specific stimulus.
Taking inspiration from the pinecone, hydration is a
popular stimulus in 4D printing approaches. Hydrogels
are highly absorbent polymer networks that can swell or
shrink in response to humidity.1
Researchers have found
that by creating scaffolds with several layers, each with a
different swelling mechanism, the material can bend in a
controlled way when it is immersed in a liquid, creating
tubular or curved structures. Zadpoor’s group recently
showed that by using two different hydrogel-based
materials with high- and low-swelling formulations, the
scaffold could self-bend after liquid immersion, creating
a curved structure that mimicked the natural structure
of cartilage.2
They used this structure to grow bone
cells, which were positioned in the hydrogel layers,
creating a proof of concept for 4D printing multicellular
cartilage tissue.
Transforming geometries in the
body
A key benefit of using shape-shifting materials in
biomedical applications is the level of adaptability
and customization that is possible. For stents and
prosthetics, this means that the implanted construct can
adapt to the changing needs of the body. For example, a
4D printed intestinal stent was designed to be triggered
by near-body temperature, allowing the stent to adjust
its shape in direct response to the patient’s internal
temperature.3 Similarly, vascular stents have been
designed to change shape in response to blood flow or
vessel diameter.4 These self-adaptive stents are highly
customized, responding directly to their environment,
which could reduce the need for surgical intervention in
the future.
4D printing has also been used to create patches to
help repair organ damage in the body. Heart attacks
can cause severe damage to the heart tissue, and 4D
scaffolds have been developed with a self-adaptive
structure to mimic the curved surface and adapt to
the contractions of the beating heart.5 To improve
scaffold integration to the heart tissue, cells were
added to fibrous scaffolds and aligned along the fibers
to mimic the cellular architecture of heart tissue.
Improving scaffold integration by incorporating cells
into 4D scaffolds is a rapidly evolving field of study,
with particular focus on which stage of the shape
transformation process works best to add cells.6
Minimal, targeted delivery
Shape-shifting materials are also advantageous
for drug delivery strategies, as 4D-printed devices
can be designed to release drugs in response to a
specific stimulus at the target location, such as pH or
temperature.7
In a recent proof-of-concept study, 4D
printing technology converged with micro-robotics in a
scene perhaps more reminiscent of a sci-fi space movie.
The researchers created bioinspired puffball capsules
– complete with ‘spores’ containing the drugs and an
inbuilt propulsion system – that can be steered to their
target site using a rotating magnetic field for on-demand
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MATERIALS SCIENCE: REVOLUTIONIZING BATTERIES, BIOMATERIALS AND ADVANCED POLYMERS 11
drug release.8
This futuristic meld of technologies gives
a glimpse into a promising future for drug delivery in
healthcare: highly customizable, minimally invasive,
targeted care.
Machine learning approaches
Researchers are also starting to use AI and machine
learning to fully leverage the adaptability that 4D
printing offers. Using modeling and simulation, it is
possible to predict the shape transformation of these
materials, as well as the physiological responses. This
will help to guide the selection of smart materials, as
well as the ideal shape-shifting geometry during the
design process. This can also inform multi-material
printing, where multiple smart materials with different
stimuli are used in the same scaffold or construct.
Furthermore, the incorporation of sensors could offer
real-time monitoring of the constructs, unlocking even
more functionality.
In the clinic
All this sounds exciting and transformative for
healthcare, but 4D-printed technologies for tissue
engineering have yet to reach the clinic, largely due to
some key challenges that still need to be addressed.
For example, the 3D fabrication procedures used
will need to be optimized to facilitate the large-scale
production of these materials, as well as rigorous testing
and approval processes that must be implemented
before these materials reach the clinic. Each specific
application will also have its own unique challenges, as
requirements will differ enormously between different
tissue engineering projects.
Despite these challenges, it is clear why 4D printing
has become a major research focus in the biomedical
field. As Zadpoor explains, using shape-shifting
materials can lead to a mixture of functionalities and
microarchitecture that is not possible to create in
any other way. It ultimately creates materials that are
much more responsive and customizable to the human
body. While several major hurdles will still need to be
overcome before we see these technologies in the clinic,
this bioinspired shape-shifting revolution will take us
towards a new, 4D future in healthcare. •
REFERENCES
1. Ramezani M, Mohd Ripin Z. 4D printing in biomedical
engineering: advancements, challenges, and future
directions. J Funct Biomater. 2023;14(7):347. doi: 10.3390/
jfb14070347
2. Díaz-Payno PJ, Kalogeropoulou M, Muntz I, et al. Swellingdependent shape-based transformation of a human
mesenchymal stromal cells-laden 4D bioprinted construct
for cartilage tissue engineering. Adv Healthc Mater.
2023;12(2):2201891. doi: 10.1002/ADHM.202201891
3. Lin C, Huang Z, Wang Q, et al. Mass-producible nearbody temperature-triggered 4D printed shape memory
biocomposites and their application in biomimetic
intestinal stents. Compos Part B Eng. 2023;256:110623. doi:
10.1016/J.COMPOSITESB.2023.110623
4. Zhou Y, Zhou D, Cao P, et al. 4D printing of shape memory
vascular stent based on βCD-g-polycaprolactone.
Macromol Rapid Commun. 2021;42(14):2100176. doi:
10.1002/MARC.202100176
5. Wang Y, Cui H, Wang Y, et al. 4D printed cardiac
construct with aligned myofibers and adjustable
curvature for myocardial regeneration. ACS Appl
Mater Interfaces. 2021;13(11):12746-12758. doi: 10.1021/
acsami.0c17610
6. Kalogeropoulou M, Díaz-Payno PJ, Mirzaali MJ, van Osch
GJVM, Fratila-Apachitei LE, Zadpoor AA. 4D printed
shape-shifting biomaterials for tissue engineering and
regenerative medicine applications. Biofabrication.
2024;16(2):022002. doi: 10.1088/1758-5090/ad1e6f
7. Zu S, Wang Z, Zhang S, et al. A bioinspired 4D printed
hydrogel capsule for smart controlled drug release.
Mater Today Chem. 2022;24:100789. doi: 10.1016/J.
MTCHEM.2022.100789
8. Song X, Sun R, Wang R, et al. Puffball-inspired
microrobotic systems with robust payload, strong
protection, and targeted locomotion for on-demand drug
delivery. Adv Mater. 2022;34(43):2204791. doi: 10.1002/
ADMA.202204791
ABOUT THE INTERVIEWEE:
Amir Zadpoor is the Antoni van Leeuwenhoek professor in
biomaterials and tissue biomechanics at Delft University of
Technology, and professor of orthopedics at Leiden University
medical center. His research focuses on biomechanics,
biomaterials and biofabrication, including 4D printing and selffolding materials.
12 MATERIALS SCIENCE
As the world shifts towards net zero, batteries will play
an increasingly important part in our energy supply.
Batteries are already commonplace in portable devices
such as phones and laptops, and demand is rising for
lithium-ion batteries that can power electric cars – over
14 million of which were sold globally in 2023.1
The
ability to store and redistribute electricity generated by
renewables will also be a crucial step in meeting national
power needs, without recourse to fossil fuel sources.
But every battery application requires slightly different
properties, whether those are performance factors such
as power output and lifetime, or practical considerations
such as cost, weight and size. The precise balance of
these characteristics is determined by the internal
chemistry of the battery and manufacturers must
carefully control these complex interactions to tailor the
device performance to each specific application.
Naturally, this requires a deep understanding of the
composition of each piece of the battery unit and
analytical techniques are therefore essential at every
stage in the production line.
1. Analysis of raw materials
Lithium-ion batteries are the most widely used battery
type, being particularly suited for small portable devices
and electric vehicles thanks to their high energy density
and excellent operating efficiency. Deposits of this critical
mineral are found globally as part of mixed metal ores.
But, with no single ore or geological formation acting as
a commercial source, processing requirements for this
raw material will vary across different mining sites. Each
individual mixed deposit must be analyzed to determine
the exact quantity and proportion of every constituent
element to ensure each is separated efficiently.
Analytical Techniques in the
Battery Lifecycle
Victoria Atkinson, PhD
Credit: iStock
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MATERIALS SCIENCE: REVOLUTIONIZING BATTERIES, BIOMATERIALS AND ADVANCED POLYMERS 13
This type of quantitative elemental identification is
principally achieved through inductively coupled
plasma optical emission spectroscopy (ICP-OES).
Fundamentally, this technique reads the “energy
fingerprint” of each element in the sample to provide a
quantitative breakdown of the elemental composition.
In ICP-OES, the apparatus first generates a hightemperature plasma by passing a flow of inert gas
(usually argon) through an induction coil running a
high-frequency alternating current. Collisions of these
gas atoms with electrons accelerated by a magnetic field
around the coil ionize the carrier gas, which becomes
a plasma at temperatures above 6000 Kelvin. In the
next stage, the sample is sprayed into the plasma stream
as a mist. As the particles collide and interact with the
plasma, individual atoms are ionized or excited, resulting
in a series of fixed electronic energy transitions for
each element. Each transition releases a single specific
wavelength of light which is detected by a spectrometer,
creating a characteristic emissions spectrum. The
resulting experimental spectrum can then be compared
against known standards to determine the identity and
quantity of each element in the sample.
2. Analysis of battery components
Each component in a battery, from the electrodes to the
additives in the electrolyte, has been carefully tailored
to optimize the battery for a particular application.
Verifying the quality and composition of each battery
element separately is therefore crucial to ensure the
completed unit performs as expected and manufacturers
use a raft of techniques to analyze each part before
assembly.
In a lithium-ion battery, the anodes (or negative
electrodes) are typically made of graphite. They hold
and release lithium ions from within their structure
throughout a charge cycle. This means the material
must be both porous and conductive to lithium ions
while remaining fully compatible with the electrolyte
and other chemical elements of the battery. Inductively
coupled plasma mass spectrometry (ICP-MS)2
– a
technique similar to ICP-OES but which records the
atoms’ mass rather than an emission spectrum – is the
most common technique to assess the purity of anode
materials. Thermogravimetric mass spectrometry
(TG-MS) is also used to evaluate whether any small
molecules may have adsorbed onto the electrode
surface during manufacture. This technique combines
thermogravimetric analysis (TGA)3
– which measures
mass changes as the temperature is increased to provide
information about physical properties such as phase
transition temperatures and adsorption processes –
with mass spectrometry (MS) to identify small molecule
contaminants from the molecular masses of their ions.
The cathodes (or positive electrodes) are the major
lithium component in a battery, being made from mixed
lithium oxides. Like the anodes, cathode purity and
quality is also easily determined by ICP-OES.
The electrolyte solution, which transports lithium
ions between the two electrodes, is a complex
chemical mixture. It typically contains lithium salts
(e.g., LiPF6
), an organic solvent and a mixture of other
additives to optimize battery function. The ratio of
these different solution components determines the
ultimate battery properties, thus monitoring and
controlling their proportions is a necessary quality
control step. Chromatographic techniques such as gas
chromatography mass spectrometry (GC-MS) are used
to evaluate the solvent composition: gas chromatography
separates mixtures of gaseous compounds by their
affinity to a stationary phase in a coiled column. The mass
spectrometer then measures the mass of each chemical
component in the mixture separately. Further techniques
such as Fourier transform infrared spectroscopy (FTIR)4
and differential scanning calorimetry (DSC)5
are also
used to analyze other electrolyte components such as
binders, separators and coatings.
3. Analysis of the assembled
battery
Before sale, a finished battery will undergo a series
of product tests to check that its performance and
safety meet required performance and regulatory
specifications. Where these checks identify a problem,
TECHNOLOGYNETWORKS.COM
MATERIALS SCIENCE: REVOLUTIONIZING BATTERIES, BIOMATERIALS AND ADVANCED POLYMERS 14
the manufacturers must be able to understand the
root cause – whether it is due to a structural issue,
damaged component or chemical incompatibility.
Battery failure analysis is therefore an important step in
the production pipeline. This process employs a wide
range of techniques to probe every aspect of the battery
structure, chemistry and performance.
Techniques such as scanning electron microscopy
(SEM)6
and energy dispersive X-ray spectroscopy
(EDS)7
analyze the surface of electrodes and coatings to
identify potential contaminants or imperfections which
might impede the battery’s performance. SEM uses a
focused beam of electrons to scan and image the surface
of electrodes and coatings, while EDS uses scattered
X-rays to identify contaminants by their characteristic
electromagnetic emission spectra.
The degradation of components is another major cause
of battery failure. As such, studies into the aging and
side reactions of various battery parts are a typical
part of battery analysis.6,8
Impurities can react with
the electrolyte, additives or separator in the battery
during its function, leading to the formation of complex
degradation products which reduce the efficiency of key
electrochemical processes.
Identifying these unwanted compounds helps to limit
or prevent such side reactions. This is most commonly
achieved using FTIR.9
Like ICP-OES, this technique
relies on the fixed energy transitions within each
compound (this time between vibrational energy levels)
and produces a characteristic spectrum of IR absorption
values for each compound.
Thermal analyses of electrolyte constituents are also
important, especially due to the potential for significant
temperature changes during a battery charge cycle. Since
electrolyte solvents are often volatile or flammable,
characterizing the electrolyte’s thermal stability is
paramount to the safe operation of the battery. Relevant
metrics, such as decomposition temperature and phase
transition temperatures, in addition to possible side
reactions, can all be measured by TGA.
The separator, a permeable membrane within the
electrolyte which separates the anode and cathode
to prevent short-circuiting, is also subject to
temperature fluctuations during use. Differential
scanning calorimetry (DSC) measures the amount
of heat required to increase the temperature of the
separator and is used to determine properties such
as its decomposition temperature and glass transition
temperature, both fundamental to the operational safety
of the battery.3,10
4. Battery recycling and analysis of
black mass
In recent years, there has been a huge surge in demand
for lithium and other critical minerals used for batteries.11
But our finite global supplies are beginning to feel the
pressure of our modern need for battery technology.12,13
It is also important to recognize that while batteries
reduce our reliance on fossil fuels, extensive mining for
the necessary minerals creates an environmental and
ethical dilemma. Some mining operations have been
criticized for contaminating water supplies, mistreating
workers and leaving lasting scars on the landscape.14
Fortunately, there are now several methods to recover
these valuable materials from spent batteries, which can
be reused in future cells.
Used batteries can be collected, dismantled and
shredded to create a material known as black mass.
Black mass contains high concentrations of key metals
such as lithium, manganese, cobalt and nickel.
Identifying the components of black mass is crucial
in determining how best to recover these individual
metals. Elemental analysis methods such as ICP-OES,
ICP-MS and EDS are used to determine the constituent
elements and their proportions in the black mass,
while chromatographic methods combined with mass
spectrometry (e.g. GC-MS or ion chromatography) can
separate the mixture and identify the components in the
black mass.
This knowledge then informs the metal recovery
process, enabling the maximum amount of material to
be recycled into new batteries while simultaneously
reducing the quantity of spent waste sent to landfill.
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MATERIALS SCIENCE: REVOLUTIONIZING BATTERIES, BIOMATERIALS AND ADVANCED POLYMERS 15
Batteries rely on a careful balance of different
chemistries to deliver optimum performance. It
is therefore vital that manufacturers are able to
monitor the composition of each part throughout the
production process. Separating raw materials depends
on knowing their constituent elements, producing
quality components requires precision data about their
structure and performance, while effective product
testing relies on having techniques that are able to
detect even the smallest deviations from the original
design. Combining elemental analysis, spectroscopy,
chromatography and mass spectrometry methods
enables manufacturers to address each of these needs
as they arise, streamlining the production process and
ultimately extending the battery lifecycle. •
REFERENCES:
5. International Energy Agency. Global EV Outlook 2023.
https://www.iea.org/reports/global-ev-outlook-2023.
Published April 2023. Accessed May 30, 2024.
6. Van Acker T, Theiner S, Bolea-Fernandez E, Vanhaecke
F, Koellensperger G. Inductively coupled plasma mass
spectrometry. Nat Rev Methods Primers. 2023;3(1):52. doi:
10.1038/s43586-023-00235-w
7. Pirsaheb M, Seifi H, Gholami T, et al. Thermal analysis
techniques for evaluating the thermal stability of battery
materials: A comprehensive review. J Anal Appl Pyrolysis.
2023;174:106136. doi: 10.1016/j.jaap.2023.106136
8. Amaral MM, Real CG, Yukuhiro VY, et al. In situ and
operando infrared spectroscopy of battery systems:
Progress and opportunities. J Energy Chem. 2023;81:472-
491. doi: 10.1016/j.jechem.2023.02.036
9. Xu X, Gan L, Chen R, et al. Effects of electrolyte/
cathode ratio on investigation of their thermal behaviors
using differential scanning calorimetry. Appl Phys Lett.
2024;124(4):043901. doi: 10.1063/5.0177345
10. Tsuda T, Hosoya K, Sano T, Kuwabata S. In-situ scanning
electron microscope observation of electrode
reactions related to battery material. Electrochim Acta.
2019;319:158-163. doi: 10.1016/j.electacta.2019.06.165
11. Marschilok AC, Bruck AM, Abraham A, et al. Energy
dispersive X-ray diffraction (EDXRD) for operando
materials characterization within batteries. Phys Chem
Chem Phys. 2020;22(37):20972-20989. doi: 10.1039/
D0CP00778A
12. Kuppan S, Duncan H, Chen G. Controlling side reactions
and self-discharge in high-voltage spinel cathodes:
the critical role of surface crystallographic facets. Phys
Chem Chem Phys. 2015;17(39):26471-26481. doi: 10.1039/
C5CP04899K
13. Dopilka A, Gu Y, Larson JM, Zorba V, Kostecki R. NanoFTIR spectroscopy of the solid electrolyte Interphase
Layer on a Thin-Film Silicon Li-Ion Anode. ACS Appl
Mater Interfaces. 2023;15(5):6755-6767. doi: 10.1021/
acsami.2c19484
14. Sun YY, Hsieh TY, Duh YS, Kao CS. Thermal behaviors
of electrolytes in lithium-ion batteries determined by
differential scanning calorimeter. J Therm Anal Calorim.
2014;116(3):1175-1179. doi: 10.1007/s10973-014-3683-9
15. Lithium Statistics and Information. United States
Geological Survey. https://www.usgs.gov/centers/
national-minerals-information-center/lithium-statisticsand-information. Accessed May 30, 2024.
16. Maisel F, Neef C, Marscheider-Weidemann F, Nissen NF.
A forecast on future raw material demand and recycling
potential of lithium-ion batteries in electric vehicles.
Resour Conserv Recycl. 2023;192:106920. doi: 10.1016/j.
resconrec.2023.106920
17. Backhaus R. Battery raw materials - where from and
where to? ATZ Worldw. 2021;123(9):8-13. doi: 10.1007/
s38311-021-0715-5
18. Haider SA. The ethical dilemma of green economy:
Examining the human and environmental costs of cobalt
mining in DRC. Global Journal of Human-Social Science.
2023;23(B2):31-37. https://socialscienceresearch.org/
index.php/GJHSS/article/view/103694.
COMMON TECHNIQUES
IN BATTERY MATERIAL ANALYSIS
CLICK HERE TO DOWNLOAD THE FULL INFOGRAPHIC
X-RAY TECHNIQUES
Degradation of the cell constituents during usage and storage, known as aging, is a major challenge.
Chromatography-based methods, including liquid chromatography (LC), gas chromatography (GC) and ion
chromatography (IC), are particularly useful for analyzing the battery electrolytes and electrode composition.
Hyphenation of chromatographic techniques can allow further analytical questions to be answered.
For example, gas chromatography-mass spectrometry (GC-MS), a destructive technique, is suited to compositional
testing. In battery analysis, it has found utility in analyzing the gases generated by Li–ion batteries, giving insights
on component degradation during repeated charging and discharging. Information impacting safety and optimal
performance can also be gained from the analysis of cyclic carbonates.
X-ray photoelectron spectroscopy (XPS) is a surface analysis technique that
provides chemical state and elemental information about the top layer of a material
(~ top 10 nm). The surface is exposed to an X-ray beam and the photoelectrons
emitted from the surface are measured. This technique is particularly useful for
analyzing the battery interfaces and changes in composition during use.
X-ray fluorescence (XRF) spectroscopy identifies and quantifies the elemental
composition of materials according to the X-rays emitted from sample atoms
when they are energized. This non-destructive technique is able to identify
inhomogeneities, inclusions, degradation products and defects.
X-ray diffraction (XRD) can provide rapid, real-time structural information, helping to
identify and quantify compounds and mineral compositions. It also assists in the analysis
of material stability under stress and high temperatures.
CHROMATOGRAPHY
DATA ANALYSIS
CARRIER GAS GC OVEN MASS SPECTROMETER
Trap Injection
Port
Capillary
Column
Ionization
Source
Focusing
Lens
Detector
Mass Analyzer
RAMAN MICROSCOPY
Raman microscopy combines imaging with pinpointed chemical analyses to
provide molecular and structural information. This enables chemical mapping
across a sample and has proven useful in mapping carbon-based materials,
yielding information on defects and structural disorder and graphene stack
size. It has also proven useful in developing alternative cathode materials and
measuring the impact of additives on electrolytes.
17 MATERIALS SCIENCE
The World Health Organization estimates that over
420 million people are living with diabetes worldwide.
A common complication of diabetes is diabetic foot
ulcer, and globally, there is a lower extremity amputation
every 20 seconds.1
Diabetic wounds have multiple
pathological features, including compromised vessel
networks and persistent inflammation, which prevent
the transport of oxygen, nutrients and waste to and from
wound sites, disrupting wound healing.
The global diabetic foot ulcer treatment market was
valued at USD 8.2 billion in 2022 and is expected
to reach USD 14.4 billion by 2032. The majority of
diabetic wound care products are passive dressings,
which merely provide a protective barrier against the
external environment and do not actively promote
wound healing. Here, we will describe three recent
hydrogel technologies with novel concepts to promote
diabetic wound healing.
Innovative Hydrogel Dressing
To Accelerate Diabetic Wound
Healing
Andy Tay, PhD
Credit: iStock
What is a hydrogel?
Hydrogels are three-dimensional networks of
crosslinked polymers that can absorb a large
amount of water and swell while maintaining
their structure. Hydrogels have uses in a
variety of biomedical applications thanks
to their superabsorbancy, biodegradability,
biocompatibility, hydrophilicity and
viscoelasticity.
TECHNOLOGYNETWORKS.COM
MATERIALS SCIENCE: REVOLUTIONIZING BATTERIES, BIOMATERIALS AND ADVANCED POLYMERS 18
Hydrogel with antibiofilm and antioxidant properties
In a recent study, Pranantyo et al. described a synthetic
hydrogel, named PPN, fabricated from crosslinked
polyethylene glycol (PEG) hydrogel tethered with an
antibacterial cationic polymer, polyimidazolium (PIM),
and the antioxidant N-acetylcysteine (NAC).2
PIM
was found to be a potent growth inhibitor for a wide
spectrum of Gram-positive and Gram-negative bacteria
implicated in diabetic wound infections. The authors
found that their hydrogels were able to swell up to 10
times their initial water volume, and the swollen form
was stable and exhibited constant mass after incubation
for seven days in bacterial extracts and infected wound
fluids. This suggests that PPN can soak up wound
exudates and resist degradation by infected wound
fluids, enabling the hydrogel to be ultralow-leachable
and leave minimal residue at wound sites after dressing
removal. This is crucial to prevent material-related
inflammation.
Using a 3D de-epidermised dermis human skin
equivalent (DED-HSE) model, a living ex vivo tissue
construct in which decellularized dermal scaffolds from
human donors are repopulated with allogeneic donor
keratinocytes, the authors showed that by day seven,
their hydrogel was able to heal 40–50% of the initial
wound size and promote proliferation of keratinocytes.
Next, using an infected diabetic mice model, the team
found that wounds treated with their hydrogel had
more than 99.9% reduction in the colonization of
all bacterial strains, including methicillin-resistant
Staphylococcus aureus (MRSA), surpassing commercial
silver-based antimicrobial dressings. This advantage
also allowed their hydrogel-treated wound to be
resolved of inflammation as indicated by a lower
number of inflammatory monocytes in the wound
tissues. Impressively, the antioxidants in the hydrogel
also led to an increase in the concentrations of growth
factors including vascular endothelial growth factors
(VEGF) that promoted blood vessel formation and
thicker granulation tissue associated with improved
proliferation of fibroblasts and keratinocytes.
Hydrogel loaded with exosomes
Adipose-derived stem cell (ADSC)-derived exosomes
are therapeutic agents in tissue regeneration as they
contain bioactive proteins, nucleic acids and lipids.
These molecules can contribute to wound healing by
promoting anti-inflammation, inhibiting apoptosis
and facilitating cell migration and proliferation. In a
study published in Nature Communications, Han and
colleagues describe the development of a hydrogel
loaded with ADSC-derived exosomes and bovine serum
albumin (BSA)-based oxygen nanobubbles to form a
multifunctional wound dressing to boost oxygen levels
in wound tissues and promote tissue regeneration.3
The
use of BSA was also able to scavenge free radicals.
Using human dermal fibroblasts in vitro, the authors
showed that the oxygen nanobubbles relieved cells
of hypoxia. Previous studies have found that hypoxic
conditions lead to lower exosome delivery efficiency.4
The authors found that oxygen nanobubbles, which
mitigated the hypoxic wound environment, significantly
improved the delivery of therapeutic cargo from the
exosomes. The multifunctional hydrogel also promoted
better proliferation and migration of fibroblasts, along
with angiogenesis in vitro.
Finally, using a rat model of full-thickness wounds,
hydrogel-treated animals showed flatter wound
surfaces with continuous epidermis, demonstrating
minimal keloid formation and scarless wound healing.
Furthermore, the treated animals had a higher density
of newly formed blood vessels and less inflammation.
There were also lower numbers of pro-inflammatory
M1-like macrophages and higher numbers of antiinflammatory M2-like macrophages. While this
hydrogel was not used in a diabetic wound setting in
the paper, the authors concluded that the technology
has the potential to be applied to diabetic wounds,
particularly because of its oxygen-supplying advantage.
Mechanotherapy with hydrogel
One medical device that is used for diabetic wound
treatment is topical negative-pressure wound treatment
(NPWT), which provides mechanical suction to
TECHNOLOGYNETWORKS.COM
MATERIALS SCIENCE: REVOLUTIONIZING BATTERIES, BIOMATERIALS AND ADVANCED POLYMERS 19
remove wound fluids and is correlated with improved
wound closure.5,6
Meta-analyses found that dynamic
mechanical loading during NPWT induced fibroblast
cell division and migration, the secretion of growth
factors and the formation of new blood vessels.7
Shou et al. developed a magnetic hydrogel using
poly(ethylene glycol) diacrylate (PEGDA) containing
magnetic particles. In the presence of a dynamic
magnetic field, fibroblasts and keratinocytes
encapsulated within the hydrogel were mechanically
stimulated.8
This led to an improvement in cell
proliferation, collagen deposition and VEGF production.
The best effects were seen with three days of
stimulation, an hour a day, while continual stimulation
beyond day three led to a reduction in cell proliferation.
Interestingly, the team found that fibroblasts were
mechanically responsive while keratinocytes were not.
Mechanical stimulation primarily activated fibroblasts
to produce more extracellular matrix proteins and
secretome, which activated keratinocytes, causing them
to secrete more VEGF via the Ras/MEK/ERK pathway.
Wanting to maximize the therapeutic impact of
mechanical stimulation, the team also analyzed public
databases of single-cell RNA sequencing and identified
an exceptionally mechano-sensitive subpopulation
of fibroblasts. They further verified this by showing
that this subtype of fibroblasts proliferated faster and
produced more collagen under mechanical stimulation.
Using an in vivo diabetic mouse model, the team further
showed that combining cell mechanotherapy led to
a 200% faster wound healing rate with 200% better
vascularization. As PEGDA is a non-biodegradable
material and the hydrogel was applied to the wound
surface rather than implanted, there was also no
material-associated inflammation as assessed by
counting the macrophage population and quantifying
inflammation genes.
Wound dressings play an important role in wound
management. Although most commercial products
are merely serving as a protective barrier, hydrogel
can be endowed with additional properties to make it
antibacterial or bioactive, which can accelerate wound
healing. The use of multifunctional hydrogels as active
wound dressings can help speed up wound healing, thus
reducing the overall time for patients to restore their
lifestyles and decreasing overall healthcare costs. •
REFERENCES:
1. Liu R, Petersen BJ, Rothenberg GM, Armstrong DG. Lower
extremity reamputation in people with diabetes: a
systematic review and meta-analysis. BMJ Open Diabetes
Res Care. 2021;9(1). doi: 10.1136/bmjdrc-2021-002325.
2. Pranantyo D, Yeo CK, Wu Y, et al. Hydrogel dressings with
intrinsic antibiofilm and antioxidative dual functionalities
accelerate infected diabetic wound healing. Nat
Commun. 2024;15(1):954. doi: 10.1038/s41467-024-44968-y
3. Han X, Saengow C, Ju L, Ren W, Ewoldt RH, Irudayaraj J.
Exosome-coated oxygen nanobubble-laden hydrogel
augments intracellular delivery of exosomes for
enhanced wound healing. Nat Commun. 2024;15(1):3435.
doi: 10.1038/s41467-024-47696-5
4. Tong B, Liao Z, Liu H, et al. Augmenting intracellular cargo
delivery of extracellular vesicles in hypoxic tissues through
inhibiting hypoxia-induced endocytic recycling. ACS
Nano. 2023;17(3):2537-2553. doi: 10.1021/acsnano.2c10351
5. Teot L, Ohura N. Challenges and management in wound
care. Plast Reconstr Surg. 2021;147(1S-1):9S. doi: 10.1097/
PRS.0000000000007628
6. Daigle P, Despatis MA, Grenier G. How mechanical
deformations contribute to the effectiveness of negativepressure wound therapy. Wound Repair Regen.
2013;21(4):498-502. doi: 10.1111/wrr.12052
7. Poteet SJ, Schulz SA, Povoski SP, Chao AH. Negative
pressure wound therapy: device design, indications, and
the evidence supporting its use. Expert Rev Med Devices.
2021;18(2):151-160. doi: 10.1080/17434440.2021.1882301
8. Shou Y, Le Z, Cheng HS, et al. Mechano-activated cell
therapy for accelerated diabetic wound healing. Adv
Mater. 2023;35(47):2304638. doi:10.1002/adma.202304638
20 MATERIALS SCIENCECredit: iStock
A study led by myself, Assistant Prof. Edison Huixiang
Ang from the National Institute of Education/Nanyang
Technological University Singapore, with Prof. XingLong Wu and Dr. Jin-Zhi Guo from Northeast Normal
University, has advanced sodium–ion battery technology.
By enhancing cathodes with a vanadium–iron phosphate
structure, we achieved superior ion conductivity and
stability using cost-effective, eco-friendly materials.
Published in Advanced Science under the 2023 Rising
Stars special collection, this breakthrough could
revolutionize large-scale energy storage.
Fueling tomorrow: Innovating
sodium–ion batteries for sustainable
energy
Driven by the need for cost-effective and eco-friendly
energy storage solutions, our team embarked on a
mission to enhance sodium–ion battery technology.
With a focus on improving cathode performance, our
research aimed to address the growing demand for
efficient energy storage in a rapidly evolving world.
To address the high cost, toxicity, poor conductivity,
structural instability and limited cycling performance
of conventional sodium (Na) super ionic conductor
(NASICON) materials, our team developed
Na₃.₀₅V₁.₀₃Fe₀.₉₇(PO₄)₃ (NVFP) encircled by highly
conductive Ketjen Black (KB). We aimed to achieve
enhanced ion diffusion, reduced volume change and
superior cycling stability, paving the way for more
sustainable and accessible energy solutions, aligning
with global efforts towards a greener future.
Supercharging Batteries With
Improved Material Design
Edison Huixiang Ang, PhD
TECHNOLOGYNETWORKS.COM
MATERIALS SCIENCE: REVOLUTIONIZING BATTERIES, BIOMATERIALS AND ADVANCED POLYMERS 21
Powering progress: Unveiling
breakthroughs in sodium–ion
battery technology
The team synthesized NVFP with KB via a ballmilling assisted sol-gel method. We examined the
structure modulation using in situ X-ray diffraction
and ex situ X-ray photoelectron spectroscopy during
electrochemical progress.
The key findings of the paper were that:
• Incorporating iron into vanadium-based cathodes
enhanced conductivity and stability.
• Pearl-like KB branch chains encircling NVFP particles
improved overall conductivity.
• An enhanced ion diffusion ability and low volume
change (2.99%) were observed in the modified
cathodes.
• Remarkable cycling performance was achieved: 87.7%
capacity retention over 5,000 cycles at 5 C.
• Full cells exhibited a capacity of 84.9 mAh g−1 at 20 C
with minimal capacity decay (0.016% per cycle at 2 C).
Empowering energy: Advancing
sustainable battery solutions
We attribute the enhanced performance of the modified
cathodes to a combination of factors. By incorporating
iron into the vanadium-based structure and introducing
the unique morphology of the KB branch chains, they
created a synergistic effect that significantly improved
conductivity and stability. This novel approach
addresses critical challenges, including reducing the
cost and toxicity of vanadium, enhancing ionic and
electronic conductivity, improving structural stability,
achieving durable cycling performance and maintaining
high energy density and rate capability in the sodium–
ion battery technology, laying the groundwork for
practical applications in energy storage systems. This
novel approach is environmentally friendly compared
to alternative approaches because it reduces the use of
toxic and expensive vanadium by incorporating cheaper,
earth-abundant iron, and enhances battery performance
and stability without relying on hazardous materials.
These findings represent a significant advancement in
the field of energy storage. By offering a cost-effective
and environmentally-friendly solution for large-scale
battery production, this innovation has the potential to
revolutionize various industries. From renewable energy
storage to electric vehicles, the adoption of sodium–
ion batteries could be accelerated, leading to a more
sustainable future.
While the study showcases impressive performance
enhancements, it primarily focuses on laboratory-scale
experiments. Scaling up production and overcoming
challenges in large-scale manufacturing remain
significant hurdles. Furthermore, the long-term stability
and performance of the modified cathodes in realworld applications necessitate further investigation.
Recognizing these limitations underscores the
importance of ongoing research and development to
realize the potential of this technology fully in practical
settings.
Pioneering progress: Charting the
path forward
We propose several avenues for future exploration.
Firstly, we suggest scaling up production processes to
evaluate the feasibility of large-scale manufacturing.
Additionally, investigating the long-term stability and
performance of the modified cathodes in practical
applications is crucial. Further experiments could
focus on optimizing the composition and morphology
of the cathode materials to enhance performance and
address the remaining challenges. Continual refinement
of this technology will be essential for its successful
integration into sustainable energy storage systems on a
commercial scale. •
Reference:
1. Zhao XX, Fu W, Zhang HX, et al. Pearl-structure-enhanced
NASICON cathode towards ultrastable sodium–ion
batteries. Adv. Sci. 2023;10(19): 2301308. doi:10.1002/
advs.202301308
22 MATERIALS SCIENCE
Synthetic polymers are a crucial, yet often overlooked,
aspect of daily life. From the hard plastics used in
packaging and consumer products to biocompatible
coatings for medical materials, to advanced lightweight
materials for automotive and aerospace engineering
– these polymer molecules underpin a huge variety of
modern advancements.1
As such polymers have become ubiquitous in everyday
life, polymer analysis techniques have become
increasingly important tools for scientists, allowing
them to properly assess the performance of these
materials in different environments.
There is a wide variety of analytical techniques that can
be applied to synthetic polymers, each offering a slightly
different look at the chemical or physical properties
of these compounds. Combining these methods,
academics and R&D scientists can better understand
and predict how these polymers will behave in different
scenarios, paving the way for more advanced materials
and breakthroughs in sustainability and plastics
recycling.
The importance of polymer analysis
Polymer materials are made up of hundreds or
thousands of repeating smaller “chain links,” known as
monomers. The average molecular weight of these long
polymer chains, as well as their density, crystallinity,
molecular mass distribution, degree of cross-linking and
the addition of any stabilizers or plasticizers can all have
a significant impact on the eventual physical, thermal
and mechanical properties of the polymer material.2
Modern polymer chemical analysis technologies offer
R&D scientists a way to look at this fundamental
structural information, which can be used to better
understand why a polymer is behaving in a certain way.
Exploring the Techniques Used
in Polymer Analysis
Alex Beadle
Credit: iStock
TECHNOLOGYNETWORKS.COM
MATERIALS SCIENCE: REVOLUTIONIZING BATTERIES, BIOMATERIALS AND ADVANCED POLYMERS 23
Industrial producers of polymers and plastic products
will also want to make use of mechanical testing
methods in their quality control processes to ensure
that their products meet all relevant performance and
safety standards.
Together, the broad range of existing polymer analysis
techniques can be used to support and drive the
creation of novel polymer materials with even more
favorable properties for specialist applications.
Chromatography and sustainable
plastics research
Chromatography is one of the first tools that a research
lab might apply when creating a novel polymer material.
“We usually start with chemical composition and
molecular weight (length of the polymer chains) to
assess new plastic materials,” said Erin E. Stache,
an assistant professor of chemistry at Princeton
University. “We can gather this information by using
nuclear magnetic resonance (NMR) and size exclusion
chromatography (SEC), sometimes also called gel
permeation chromatography (GPC).”
Despite recent advances, polymerization reactions
do not produce a completely uniform set of polymers
– there will be some natural variation in the chain
length and molecular weight of the final molecules.3
This molecular weight distribution can affect the
processability, mechanical strength and morphological
phase behavior of the polymer.4 As a result,
chromatographic methods play an important role in
allowing scientists to separate these molecules into
different fractions according to their size or weight and
analyze their relative distribution.
SEC uses porous gel beads packed inside a
chromatographic column to separate a polymer
dissolved in a solvent mobile phase according to their
size.5
Smaller polymer molecules and ones with a lower
molecular weight are more likely to get trapped in the
beads’ pores, and as a result will take more time to pass
through the chromatography column.
This molecular weight data can also be useful to
scientists wanting to study how polymers degrade in
certain environments. This is a central research theme
for the Stache Lab, in addition to its work investigating
new polymerization techniques that yield easily
degradable polymers and the recycling of waste plastics
back into their monomer building blocks or other
commodity chemicals.
“Degradation or depolymerization requires
characterization of the products,” Stache said. “These
techniques help determine changes in molecular weight
or modification of the polymer backbone. Then, we
use this information to assess the effectiveness of our
method and establish a mechanism for degradation or
depolymerization. This information helps us optimize
the process to be more efficient, always working
towards the goal of a single product with high recovery.”
Studying degradation with
spectroscopic techniques
Spectroscopy techniques can be a useful complement
to chromatographic techniques in polymer structural
characterization.
The advent of high-resolution mass spectroscopy
methods has seen this technique become increasingly
more utilized for polymer analysis. Used together
with chromatic separations, it is possible to generate
extremely accurate molecular weight distribution
measurements, as well as information relating to the
polymer’s end groups and topology.6
Nuclear magnetic resonance (NMR) spectroscopy,
Fourier-transform infrared (FT-IR) spectroscopy and
Raman spectroscopy are also common techniques
applied in polymer analysis. These techniques are
normally utilized for determining which functional
groups are present in a polymer.7
“During degradation, we focus on the impact on molar
mass, so GPC is really important for that where we can
[use it],” said Andrew Dove, a professor of chemistry
at the University of Birmingham. “NMR is also a very
useful technique for us and we are starting to look at
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MATERIALS SCIENCE: REVOLUTIONIZING BATTERIES, BIOMATERIALS AND ADVANCED POLYMERS 24
more advanced methods there, like diffusion NMR
and extending out at the moment to MRI [magnetic
resonance imaging] techniques for imaging.”
The Dove Research Group is heavily involved in
exploring different aspects of polymer degradation.
This includes the creation of biodegradable polymers
and new polymers that can be more easily recycled, as
well as polymers that can resist degradation in certain
environments, such as polymer materials being used in
the body for medical implants.
Just like the Dove group, the Stache lab also makes use
of spectroscopic techniques in their research to create a
fully-formed chemical and structural characterization of
the polymers they are working with.
“For small molecule (<500 g/mol) identification,
we use nuclear magnetic resonance (NMR), gas
chromatography (GC), mass spectrometry (usually
GC-MS), and infrared spectroscopy (FT-IR),” Stache
said. “Combining all these techniques allows us to
unequivocally determine the identity and quantity of
products being formed.”
Thermal techniques for polymer
materials characterization
Chromatographic and spectroscopic techniques allow
scientists to study what is going on at the molecular
level inside a polymer or plastic product. Thermal
analysis techniques provide feedback on a more macro
scale, giving an insight into the materials’ mechanical
properties and thermal behavior.
The most commonly applied thermal polymer
characterization techniques are: differential scanning
calorimetry (DSC), thermogravimetric analysis (TGA),
thermomechanical analysis (TMA) and dynamic
mechanical thermal analysis (DMTA).8
Using one or a
combination of these techniques, it is possible to build
up an idea of how a new polymer will react during
manufacturing or when exposed to various external
forces.
Each of these methods operates on the principle of
exposing a polymer material to heat, cold or a changing
temperature and studying how the material and its
properties vary under these conditions.
TGA is concerned with studying changes in mass as a
polymer is heated, which can be used to investigate the
material’s thermal stability as well as the determination
of any volatile species or fillers in the material. DSC
is a calorimetry technique commonly used to study a
material’s phase transitions. TMA and DMTA are both
used to study a material’s response to external forces
at different temperatures, with TMA using a constant
force and DMTA applying periodically oscillating forces
to assess deformation and kinetic properties such as
thermal expansion.9
“TGA tells us the degradation temperature of the
polymer, that is, the temperature at which the polymer
will start to break down,” said Stache. “DSC tells us
more about the physical properties of the polymer,
such as glass transition temperature (Tg
) and melting
temperature (Tc
),”
“T
g
will tell us if the polymer is hard and glassy or soft
and rubbery at a given operating temperature,” she
explained. “Tc
tells us the temperature at which the
polymer will start to melt and flow.”
Beyond assessing the performance of newly synthesized
polymer materials, these thermal analysis methods are
also routinely applied for studying polymer degradation.
“We are interested in how degradation affects
the materials’ properties, so we do a lot of the
characterization by thermo-mechanical methods, like
DSC, TGA, DMTA, tensile testing, etc.,” said Dove.
In addition to chromatographic, spectroscopic and
thermal analysis methods, there are a raft of other
analytical techniques that can be applied to polymer
analysis. X-ray diffraction and X-ray scattering data
can be used to provide additional insights on the
crystallinity of semi-crystalline polymers.10 Microscopy
techniques can also provide extra information on
a polymer’s microstructure and micromechanical
properties.7
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MATERIALS SCIENCE: REVOLUTIONIZING BATTERIES, BIOMATERIALS AND ADVANCED POLYMERS 25
Collectively, these techniques all contribute to the fabric
of the polymer science sector, allowing researchers to
produce more advanced, high-performance polymer
materials with more favorable recycling and degradation
profiles tailored to suit the modern world. •
ABOUT THE INTERVIEWEES:
Erin Stache is an assistant professor of chemistry at Princeton
University. Research in her lab integrates organic chemistry, photo
chemistry, inorganic materials, and polymer chemistry to pioneer
fresh advancements in materials science and synthesis. A major
aim of the Stache Lab is finding solutions for a more sustainable
plastics economy through the application of innovative catalytic
methods.
Andrew Dove is a professor of chemistry at the University of
Birmingham. He leads the Dove Research Group, a multinational
collection of vibrant and dynamic researchers that are focused
on challenges in polymer and materials science. He is part of
the Birmingham Plastics Network, an interdisciplinary team of
more than 40 academics working together to shape the fate and
sustainable future of plastics. This unique team brings together
chemists, environmental scientists, philosophers, linguists,
economists and experts in many other fields, to holistically
address the global plastics problem.
REFERENCES
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2. Physical, thermal, and mechanical properties of
polymers. In: Biosurfaces. John Wiley & Sons, Ltd;
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3. Murphy EA, Zhang C, Bates CM, Hawker CJ.
Chromatographic separation: A versatile strategy to
prepare discrete and well-defined polymer libraries.
Acc Chem Res. 2024;57(8):1202-1213. doi:10.1021/acs.
accounts.4c00059
4. Walsh DJ, Schinski DA, Schneider RA, Guironnet D.
General route to design polymer molecular weight
distributions through flow chemistry. Nat Commun.
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5. Pasch H, Bungu PE. 45 Years of polymer HPLC: A short
review. Macromol Mater Eng. 2023:2300354. doi:10.1002/
mame.202300354
6. Jackson CA, Simonsick WJ. Application of mass
spectrometry to the characterization of polymers. Curr
Opin Solid State Mater Sci. 1997;2(6):661-667. doi:10.1016/
S1359-0286(97)80006-X
7. Alqaheem Y, Alomair AA. Microscopy and spectroscopy
techniques for characterization of polymeric
membranes. Membranes. 2020;10(2):33. doi:10.3390/
membranes10020033
8. Menczel JD, Prime RB, Gallagher PK. Introduction. In:
Thermal Analysis of Polymers. John Wiley & Sons, Ltd;
2009:1-6. doi:10.1002/9780470423837.ch1
9. Saba N, Jawaid M. A review on thermomechanical
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composites. J Ind Eng Chem. 2018;67:1-11. doi:10.1016/j.
jiec.2018.06.018
10. Polizzi S, Fagherazzi G, Benedetti A, Battagliarin M, Asano
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3057(91)90130-G
MATERIALS SCIENCE: REVOLUTIONIZING BATTERIES, BIOMATERIALS AND ADVANCED POLYMERS 26
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CONTRIBUTORS
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materials science and engineering. He holds a
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University of St Andrews, Scotland.
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Andy Tay received his PhD from the University
of California, Los Angeles, focusing on
neuromodulation and engineering. He
subsequently completed his postdoctoral
training at Stanford University where he
developed nanotechnologies for immunoengineering. Andy Tay is currently a Presidential
Young Professor at the National University of
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Edison Huixiang Ang,
PhD
Dr. Edison H. Ang possesses a broad background
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she investigated the effects of materials on
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Steven has a BSc in pharmacology and a
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Previous to this, she was a science content
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