Self-healing in materials is the process by which materials reassemble after applications of stress. In everyday life, we often suffer from small bumps and grazes which we very quickly recover from. This process is an essential feature of living systems which helps to avoid sustaining permanent damage. 

The idea of self-healing has been of great interest in the materials field in recent years. If these properties could be emulated in synthetic materials, the applications would be vast. This year alone has seen many devastating earthquakes and tsunamis, the development of self-healing materials in buildings could help save millions of lives. 

December’s Paper of the Month comes from Yan et al., from Martin Luther University Halle-Wittenberg, who have been working on recreating self-healing in synthetic materials by incorporating it as an intrinsic dynamic network. 

Self-healing occurs when dynamic bond interactions break when stress is applied, but - with time - reform and restore the strength of the material. These types of bonds can be incorporated into the load carrying molecular backbone of a polymer which encourages the self-healing properties. 

For such a system to work the bond interactions of the material must be dynamic, thus weak bond interactions, which are more readily formed and broken, can be exploited. The molecular scaffold should also incorporate a matrix in which the reformation of bonds can occur. 

Previous work suggested that the time for self-healing is related to the time of relaxation of molecular processes. The relationship between the molecular relaxation process and self-healing has been analysed but the processes behind the self-healing were not elucidated. 
To uncover these processes, Yan et al., used a reversible network of telechelic polymers and conducted small angle x-ray scattering and rheological experiments. 

For clear analysis, the network formed by the molecules needs to be well controlled and structured but this is often difficult to achieve. In their experiments, Small Angle X-ray Scattering (SAXS) was used to prove the molecules form a network of small aggregates, which form through self-assembly and become weaker at elevated temperatures. They used a custom made HFS91 Capillary Stage adapted for vacuum in their heated Small-Angle X-ray Scattering experiments. This enabled them to investigate the relaxation process of the material. 

They used telechelic polyisobutylene (PIB) as the relaxation processes of the material were well separated. This in turn allowed them to analyse how the healing process was related to the relaxation of the molecule.
 
Their experiments underlined the molecular processes of healing, allowing them to envision common design rules. With more work, their findings can be used to create better self-healing molecules in the future. 

By Tabassum Mujtaba

Yan, T. et al. Unveiling the molecular mechanism of self-healing in a telechelic, supramolecular polymer network. Sci. Rep. 6, 32356; doi: 10.1038/srep32356 (2016).

Our sales team recently visited Colorado for the American Association of Pharmaceutical Scientists (AAPS) 2016 annual meeting.  

Industrial and academic delegates from all over the globe descended on the Mile High city of Denver to attend the meeting which covered a diverse range of topics: from drug product manufacturing and stem cell research, to novel pharmaceutical technology. 

Freeze drying and differential scanning calorimetry (DSC) are important techniques in the pharmaceutical industry and we were excited to be showcasing two new stages at AAPS: the optical DSC450 stage and the freeze-drying vial system FDVS. 

DSC is a technique used to measure temperature and heat flow associated with thermal transitions in materials.  The optical DSC450 system has been optimised to combine the measurement of transition temperatures and enthalpy changes while simultaneously imaging the sample, providing additional information about changes in morphology and colour. 

The Freeze Drying Vial System (FDVS) has been designed as a turn-key solution for simulating the industrial freeze drying process in a compact and efficient form. By incorporating vials, the FDVS works with a small sample volume and uses enough to simulate large scale industrial processes while still minimising sample wastage.

We also brought our humidity controller RH95, freeze drying cryostage FDCS and heating and cooling stage THMS600 which again proved popular within the market. The show reiterated the importance of sample characterisation within the pharmaceutical industry and the role Linkam has within it. 

While in the US, we also caught up with our American distributors – the McCrone Group. They graciously showed us around their facilities, including the famous Hooke College and gave us a tour of their private microscopy museum which has a collection of microscopes from the 17th century. We were treated to the delights of Chicago’s famous dining scene - and we are still trying to work off the additional weight!

We would like to give a big thank you to all those who came to see us at the show. We look forward to seeing you at the next pharmaceutical conference.  

By Tabassum Mujtaba

Graphene has been a hot topic in both fundamental science and practical applications since it was first isolated in 2004. It is the most conductive material known and has many other attractive properties such as flexibility, transparency and impermeability. This makes it suitable for application in wide-ranging areas such as sanitation, biomedical science and electronics. 

The incredible features and applications of this material can be generated by adding layers of graphene on top of a single graphene layer. The interlayer shear modes in these few-layer graphene are very important for understanding their exceptional properties. However, these modes are in very low frequency range with very weak intensities which greatly hinders exploration.

This month’s Paper of the Month comes from Nanyang Technological University, in Singapore. Cong, currently a professor of Fudan University, and Ting demonstrated methods of improving intensities of the shear modes of graphene layers which would in turn allow better probing of few-layer graphene itself and exploration of its application. 

Cong and Ting discovered a way to enhance such interlayer shear modes through folding the bernal-stacked graphene layers with certain twisting angles. They used Linkam’s electrical probe stage, the HFS600E-PB4, which has a temperature range of -196°C to 600°C in their temperature dependant in-situ Raman spectroscopy experiments. 

When asked to comment on the motivation behind their work, and the purpose of the Linkam stage, Dr Cong said: 

“Investigations of shear modes in few-layer graphene are greatly hindered by the truth that shear modes of graphene layers are extremely weak and almost fully blocked by a Rayleigh rejecter in Raman measurements. 

We found that the shear modes could be dramatically enhanced by properly folding graphene layers. Such strong signals offer the feasibility of performing systematically in-situ temperature Raman scattering measurements with the help of a Linkam stage. The vibrational symmetry, anharmonicity and electron-phonon coupling of the shear modes of graphene layers are uncovered through studies of temperature-dependent Raman spectroscopy. 

The Linkam stage which is compatible with our confocal low-frequency Raman system, helps us to realize the temperature-dependent Raman measurement with liquid nitrogen”.

Their research will provide a better insight into the mechanical and electrical properties of graphene. 

By Tabassum Mujtaba

Cong, C. & Ting, Y. Enhanced ultra-low-frequency interlayer shear modes in folded graphene layers. Nat Commun. 5:4709 | DOI: 10.1038/ncomms5709 (2014). 

The Colorado city of Denver, nick-named the Mile-High City because its elevation is exactly one mile above sea level, is a gateway to the snow-capped Rocky Mountains. This year it plays host to the American Association of Pharmaceutical Scientists (AAPS) 2016 annual meeting. 

This week, from 13th to 16th November, the Linkam sales team will be heading to the Colorado Convention Centre for this year’s meeting. We will be bringing our humidity generator RH95, the thermal stage THMS600 and the freeze drying cryo-stage FDCS196.

We are also excited to be announcing the launch of two new Linkam stages – a brand new vial based freeze drying system and a dual pan optical DSC. 

Many of our products are perfect for sample characterisation in the pharmaceutical market. They can be used for a variety of applications including quality assurance, developing freeze drying protocols, dissolution studies and many more.

Come and see us on booth 1470 to discuss how our stages can enhance your sample characterisation needs.

We look forward to seeing you there.