Crystallography 2020 | Paris | France | Allied Conferences | Meetings

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Theme

Latest Developments and Best Practices in Chemistry and Chemical Sciences

- Crystallography 2020

Welcome Message

Allied Academies pleasantly invite you to be a part of the ‘International Conference on Crystallography and Structural Chemistry’ on Aug 31st - Sep 1st, 2020 at Barcelona, Spain.

The milestone of the International Conference on Crystallography and Structural Chemistry will be the gathering of international experts and investigators to discuss the current situations and case studies, future innovations and improvements on the topic of Crystallography and Structural Chemistry. All the selected sessions will have sub-sessions which make the event more understandable and all the vital information will be discussed. Since the International Conference on Crystallography and Structural Chemistry is held for two days, the sessions will be on point which includes the topics of Crystallography and Structural Chemistry.

International Conference on Crystallography and Structural Chemistry, This event will focus on Application of Modern Chemistry, Advanced Spectroscopy and variety of Crystallography Sessions including Chemical Crystallography, Crystallography in Materials Science, Crystallography in Biology, Electron Crystallography, Crystallography Applications through invited plenary lectures, workshops, invited sessions, oral and poster presentations of unsolicited contributions.

The conference provides more focused sessions like symposium,lectures, workshops on a variety of topics, poster presentations and various programs for participants from all over the world.

The Conference gears up to provide you the opportunity to meet and interact with leading scholars, researchers, friends, colleagues, sponsors, exhibitors and functional change experience.

Maximize your personal involvement,engagement by getting together on Aug 31st - Sep 1st, 2020 with an interactive discussions and workshops at the conference, you will feel free to reach out and share your thoughts to continue your lifelong learning and build on the skills that make you successful. We invite you to join at International Conference on Crystallography and Structural Chemistry 2020 where you will be sure to have a meaningful experience with scholars around the world.

We look forward to seeing you in Barcelona, Spain!

Scientific Sessions/Tracks

SESSIONS/TRACKS

Track 1: Crystallography

Crystallography is a branch of science that deals with discerning the arrangement and bonding of atoms in crystalline solids and with the geometric structure of crystal lattices. Crystallography is used by most of the Pharmaceuticals and drug discovering companies to make useful modifications in drugs. In addition, Crystallography helps to research into how drugs target proteins, the molecules that are essential for living organisms to function properly. Crystals of Lithium niobite are used in the telecom markets. Crystallography can be found in all science aspects like Chemistry, Physics, Biology, Materials science and Mathematics, as well as in many industries.

Non-covalent control of structure
Design of multi-component crystals
2D Structures
Polymorphism
Crystal structure prediction
Property design
Crystal Nets (periodic graphs)
Crystal Growth & Design

Track 2: Nano Structure

Nanostructures are usually probed either optically (Spectroscopy, Photoluminescence) or in transport experiments. Nanostructure emphasis the analysis in all branches of Nano Chemistry, Nano Agriculture, Nanoscience and Nanotechnology. Nano structural detail is microstructure at nanoscale. In this session, mechanisms of enhancements in these spectroscopies, physicochemical behaviours of metals and surrounding materials, preparation methods of nanostructures, and techniques in measurements are reviewed.

Nanostructure in Chemistry
Applied nanoscience
Photonics and Nanostructures
Nanostructured Materials
Nanomaterials and Nanostructures

Track 3: Structural Isomerism

In Structural isomerism, the atoms are arranged completely in a different manner. Chain isomerism where the isomers differ in the order in which the carbon atoms are bonded to each other. Position isomerism where the main carbon skeleton is same, but they differ in the position of functional group attached to it. Functional group isomerism where isomers differ in functional group. In one of them, butane, the carbon atoms lie in a "straight chain".

Chemical Information and modelling
Biomolecular Structure and Dynamics
Physical chemistry
Physical organic chemistry
Structural Chemistry & Crystallography Communication

Track 4: Crystalline solids

Crystalline solids consist of atoms, ions and molecules arranged in definite and repeating three-dimensional patterns in a highly ordered microscopic structure, forming a crystal lattice that extends in all directions. Crystalline Solids focus is within the fields of Materials Chemistry and Chemical Physics, Thermodynamics.

· · Physics and Chemistry of Materials

· Cluster Science

· Structural Chemistry

· Non-Equilibrium Thermodynamics

· Structural Chemistry & Crystallography Communication

Track 5: Spectroscopy Applications

The energy levels of electrons in atoms and molecules are quantised, and the absorption and emission of electromagnetic radiation only occurs at specific wavelengths. In this way, most of the fluorescence signal, which is not as strongly wavelength-dependent, can be eliminated.

The Photoacoustic measures the sound waves produced upon the absorption of radiation. Ultraviolet (UV) and visible (VIS) spectroscopy. This is the earliest method of molecular spectroscopy. A phenomenon of interaction of molecular with ultraviolet and visible lights.

Absorption of photon result in electronic transition of a molecule, and electrons are promoted from ground state to higher electronic states.

Spectroscopy in Environmental Analysis
Spectroscopy in Biomedical Sciences
Spectroscopy in Astronomy
Spectroscopy in Laser-induced Fluorescence
Spectroscopy in Materials Science
Atomic Emission Spectroscopy (AES)
Atomic Absorption Spectroscopy (AAS)
Applications in Mass Spectrometry
Spectroscopy in the Photon Migration Regime

Track 6: Chemical Crystallography

Chemical Crystallography is a use of diffraction methods to the investigation of basic science. An incessant reason for existing is the recognizable proof of common items, or of the results of manufactured science tests, point by point sub-atomic geometry, intermolecular collaborations and supreme designs can likewise be considered. Structures can be examined as an element of temperature, weight or the utilization of electromagnetic radiation, or attractive or electric field: such studies involves just little minority of the aggregate. The strategies combined with modem PC contraptions and Advances in innovation makes this branch of science an unequivocal supplier of precise and exact estimations of sub-atomic measurements. Engineering of Crystalline and Non-crystalline Solids.

Structure and Properties of Functional Materials
Metal-organic Frameworks and Organic
Inorganic Hybrid Materials
Reactions and Dynamics in the Solid State
Mounting the Crystal

Track 7: Crystallography of Novel Materials

The properties of matter rely on upon which iotas are utilized and how they are fortified together. The properties of a material offer intimations with regards to the structure of the material. The quality of metals proposes that these molecules are held together by solid bonds. To comprehend the structure of a material, the sort of particles present, and how the iotas are organized and fortified must be known. Early organic and small biological molecules. Also, the micro-structure and macro-structure can influence these properties, but they mostly affect the mechanical properties and the rate of concoction response Mineralogy and metallurgy. It ought to be obvious that all matter is made of iotas. From the intermittent table, there are just around 100 various types of molecules in the whole Universe. These same 100 molecules shape a great many distinctive substances running from the air we inhale to the metal used to bolster tall structures. Metals carry on uniquely in contrast to pottery, and earthenware production act uniquely in contrast to polymers.

Metals and Alloys
Ceramics and Polymers
Thin films
Quasi-crystals
Amorphous Materials
Bulk Nitride Crystals
Novel crystallization strategies for XFEL studies

Track 8: X-Ray Crystallography

X-ray crystallography, the use of X-ray diffraction to determine the structure of crystals or molecules, such as nucleic acids. ... X-rays are diffracted by the electrons in the molecules and if molecular crystals of a compound are used, the electron density distribution in the molecule can be determined. Many of the medicinal chemicals that have been discovered by scientists are very difficult to produce naturally in large amounts.

Other researchers have used X-ray technologies to record the structures of proteins, haemoglobin, and the double-helix of DNA structure (deoxyribonucleic acid).

X-ray crystallography was initially used to investigate the structure of minerals, confirming and refining the crystallographic descriptions. Use of the technique was expanded to the investigation of metals, alloys, and inorganic and organic chemical substances. More recently, biomedical research has utilized the technique for the investigation of the structure and dynamics of proteins, nucleic acids, and other biological molecules. Research into microelectronics and semiconductors, as well as pharmaceutical research, continue to rely on the qualities of x-ray crystallography.

X-ray diffraction
Single-Crystal X-ray diffraction
Fourier transformation
Fibre diffraction
Powder diffraction
Contributions to Chemistry and Material Science
Elastic vs. Inelastic Scattering
Applications of X-ray diffraction

Track 9: Crystal Growth

X-beams are utilized to examine the basic properties of solids, fluids or gels. Photons interface and give data about the vacillations of electronic densities in the matter. A run of the mill test set-up is appeared a monochromatic light emission wave vector Ki is chosen and falls on the specimen. The scattered power is gathered as a component of the alleged dissipating point 2?. Versatile cooperation’s are described by zero vitality exchanges, with the end goal that the last wave vector KF is equivalent in modulus to Ki. The applicable parameter to examine the collaboration is the force exchange or diffusing vector q=Ki-KF, characterized by:

The scattered force I(q) is the Fourier Transform of g(r), the connection capacity of the electronic thickness r(r), which compares to the likelihood to discover a scattered at position r in the specimen if another scattered is situated at position 0 : flexible x-beam dissipating tests uncover the spatial relationships in the example. Little edge diffusing analyses are intended to quantify I(q) at little scrambling vectors q»(4p/l)q, with 2q going from couple of small scale radians to a ten of radians, to examine frameworks with trademark sizes running from crystallographic separations (few Å) to colloidal sizes (up to couple of microns).

Recent Developments in Crystal Growth
Crystal growth kinetics and mechanisms
Crystal morphology
Diamonds growth
Organic Crystal Scintillators
Phase Transitions: seeding, growth, transport
Melt Growth 1: hydrodynamic concepts, external fields
Melt Growth 2: microgravity and modelling
Aqueous solution, Ammon thermal growth
Growth from melt solution, liquid phase epitaxy

Track 10: Crystallography Applications

Crystallography method has been a broadly utilized device for illustration of mixes present in drain and different sorts of data acquired through structure work relationship. Although more point by point data from X-beam investigation has been secured from substances which are normally known to be crystalline, it has been amazing to discover substances generally, weight, extending, and so forth. Casein is a case of the last class of proteins. Stewart has demonstrated that even arrangements tend to accept a methodical game plan of gatherings inside the arrangement. Consequently, fluid drain ought to, and shows some sort of course of action. in any case, intriguing basic changes have been seen in butterfat, drain powder, casein and cheddar.

High-Resolution Charge Density Studies
Semiconductors and Insulators
X-ray method for investigation of drugs
X-ray method for investigation of textile fibres and polymers
X-ray method for investigation of bones
Pre-clinical imaging
Spectroscopy at Fusion Reactors
Surface Stress Measurements
Photo-Crystallography

Track 11: NMR Spectroscopy vs. X-Ray Crystallography

Although they utilize different approaches, Spectroscopy, X-Ray Crystallography and nuclear magnetic resonance NMR comprise the two-best means of analysing protein structure and function at or near atomic resolution. The degree to which these techniques differ and complement each has been a source of long-standing debate. Do proteins amenable to structural analysis by NMR also crystallize well? Does crystallography provide better structural resolution? In analysing NMR dynamics experiments, for example, one can greatly benefit from existing crystal structure data onto which the NMR structural data can be superimposed. Similarly, NMR structure data can be used to supplement a crystal structure with more information on the protein's dynamics, binding information, and conformational changes in solution. Because a protein that can be analysed by NMR is not necessarily amenable to crystallization (and vice-versa), the two techniques, either alone or in conjunction with one another, serve as two of the top complementary methods for protein structure determination.

· Protein NMR Spectroscopy

· X-ray Protein Crystallography

· Data Analysis

· Protein Production

· Protein Stability and Crystallization

· Protein Size

· NMR Dynamics

· Crystallography Dynamic Structure Analysis

Track 12: Crystal Engineering

Crystal engineering is the design of molecular solids with specific physical and chemical properties through an understanding and manipulation of intermolecular interactions. Engineering strategies typically rely on hydrogen bonding and coordination bonds, but can also use other interactions, such as halogen bonds and ?–? interactions. A major development in the field of crystal engineering in the last decade is related to the development of design strategies for bi-component and higher multi-component crystals (also known as cocrystals). The study and formation of 2D architectures (i.e., molecularly thick architectures) has rapidly emerged as a branch of engineering with molecules. The formation (often referred as molecular self-assembly depending on its deposition process) of such architectures lies in the use of solid interfaces to create adsorbed monolayers. The field of 2D crystal engineering has advanced over the years especially through the advent of scanning probe microscopic techniques which enable one to visualize networks with sub-molecular precision. The many aspects of developments in this field include the understanding of interactions, studies on polymorphism, design of Nano porous networks.

Non-covalent control of structure
Design of multi-component crystals
2D Structures
Polymorphism
Crystal structure prediction
Property design
Crystal Nets (periodic graphs)
Crystal Growth & Design

Track 13: Biological Structure Determination

Knowing the three-dimensional structure of biological macromolecules, such as proteins and DNA, is crucial for understanding the functioning of life. Biological crystallography, the main method of structural biology, which is the branch of biology that studies the structure and spatial organization in biological macromolecules, is based on the study of X-ray diffraction by crystals of macromolecules. But now, it is being used to create videos of the body's inner workings at a hitherto unseen level of detail. This new view inside the body is likely to accelerate the development of more effective drugs for dementia and infection. It was a wacky alternative to other techniques for decades. But over time, scientists refined cryo-EM to the point that it earned a Nobel Prize for chemistry in 2017. But, crucially, there was a perfect storm of improvements in camera technology, image processing, reduced cost and increased computing power that has utterly transformed "blob ology" into "ultra-high-definition-3D-video-ology"

Mass spectrometry
NMR Spectroscopy
Bio-Macromolecular Crystallography
Proteolysis
Electron paramagnetic resonance (EPR)
Cryo-electron microscopy (cryo-EM)
Multi-angle light scattering
Small angle scattering
Ultrafast laser spectroscopy
Structure of interfaces

Track 14: Advances in Neutron Diffraction

This Special Topic describes the current state and new developments in neutron diffraction. However, the innovations are continuing, with concepts being explored to complete the instrument suites at the first target station at the SNS, upgrade diffraction suite capabilities at the HFIR, and indeed the design and instrumentation for a future second target station at the SNS. We are confident these new developments will help us meet the challenges for neutron diffraction in the coming decades. Capabilities at the HFIR and SNS broadly support scientific exploration in biology, chemistry, physics, materials science, geoscience, medicine, and more. The Special Topic connects technical advancements with the scientific discoveries they enable, providing a platform for increased visibility and stimulating further developments. The topic is divided in four parts: (1) Diffraction Suite Reviews; (2) State-of-the Art Neutron Instruments ; (3) Novel Neutron Sample Environments; and (4) Advances in Neutron Diffraction Measurements.

Nuclear scattering
Magnetic scattering
Hydrogen, null-scattering and contrast variation
Specific Applications of Neutron Scattering
Thomson scattering

Track 15: Nuclear Magnetic Resonance Crystallography

In the electromagnetic spectrum there is a range which came to light just about 40 years ago. This range is the radio wave region. The energy of this wave can excite the spin-moments of the nucleons in the nucleus or that of the electrons on the shell depending on its wavelength. The strengths and weaknesses of one of the two methods fortunately are of those kinds which supplement the holes and gaps in the other method to make it possible . There may be several instances when only one method could be used. If the two methodologies had the same basics, principles, strengths and weaknesses we may be not capable to solve lots of structural problems. We should thank this possibility to the technical development which could catch different biophysical principles.

Dipolar interaction
Non-covalent interactions
Solid-State NMR
Crystal Structure Refinements
Applications of NMR
NMR spectroscopy
NMR crystallography

Market Analysis

MARKET ANALYSIS

Summary

The International Conference on Crystallography and Structural Chemistry is the platform to gain or share knowledge in the new technological developments in the field of science, engineering, and technology. This conference brings together professors, researchers, scientists, students in all the areas of material science, Crystallography, Spectroscopy, Physics and Chemistry which provides an international forum for the spreading of approved research. We are honoured to invite you all to attend and register for the International conference on Crystallography and Structural Chemistry, Crystallography and applications in Modern Chemistry” which is scheduled for April27-28, 2020 in Barcelona, Spain.

We invite you to join us at International conference on crystallography and Structural Chemistry, where you will be sure to have a meaningful experience with scholars from around the world. All members of the Crystallography 2020 organizing committee look forward to meeting you in Barcelona, Spain.

IMPORTANCE AND SCOPE

World-renowned speakers, the most recent techniques, tactics, and the newest updates in fields of Crystallography and Structural chemistry are hallmarks of the conference. The milestone of the International Conference on Crystallography and structural science will be the gathering of international experts and investigators to discuss the current situation and case studies, future innovations and improvements on the topic of Crystallography and Structural Science. All the selected sessions will have sub-sessions which make the event more understandable and all the vital information will be discussed. Since the International Conference on Crystallography and Structural Chemistry is held for two days, the sessions will be on point which includes the topics of Crystallography and Structural Science.

The study focusses on the processing of new materials that facilitates its applications to the next generation of Students, Engineers, and its high marketability has a great impact on the economy of the country. In the new decade, the sustainability and influence on the environment lie in the core of material development.

Global X-ray Crystallography Market

The global X-ray crystallography market is prognosticated to be popularized by the application of the technique for researching protein structures and assessing protein-ligand interactions, protein- nucleic acid complexes, viruses, and enzymes. Besides determining biological macromolecules and protein structure, X-ray crystallography could be used to reconstruct molecular crystalline structures. Commercially, the technique could be engaged to examine crystalline structures in jewels and art if acts, electronic chips, cosmetics, bones and teeth, and DNA and conduct pharmaceutical drug discovery.

2014 was declared as the International Year of Crystallography(IYCr2014) by United Nations Educational, Scientific, and Cultural Organization(UNESCO) for celebrating the significant role of the technique and promoting more discovery and research in the same field. With the course of time, the global X-ray crystallography market is prophesied to receive a strong impetus on the back of newer applications broadening the commercial employment of the technique.

However, other prime end users of the technique could be manufacturing firms involved in demanding research and development activities conducted in the physical and atomic science domain. More opportunities for increasing the demand in the global X-ray crystallography market are forecasted to arise from the engagement of players in research and development activities performed in the fields of cosmetics, pharmacy, and biotechnology. The clinical application of examining atomic composition of crystalline structures in a human body could help the technique gain extensive recognition in hospitals and research laboratories.

key players in this X-Ray Crystallography instruments market are:–

Philips healthcare
SiemensHealthcare
Toshiba
Hitachi
Carestream
Hologic
Samsung Medison
Important application areas of X-Ray Crystallography Instruments are also assessed based on their performance. Market predictions along with the statistical nuances presented in the report render an insightful view of the X-RayCrystallography Instruments market. The market study on Global X-Ray Crystallography Instruments Market 2018 report studies present as well as future aspects of the X-Ray Crystallography Instruments Market primarily based upon factors on , key trends and segmentation analysis.

Application of X-Ray Crystallography Instruments market are:

Pharma
Biotech
Chemical
Scientific
Others
Product Segment Analysis of the X-Ray Crystallography instruments market is:

X-Ray Powder Diffraction
Single-crystal X rd.
In this study, the years considered to estimate the market size of X-Ray Crystallography Instruments market are as follows:-

· History Year: 2013-2017

· Base Year: 2018

· Estimated Year: 2019

· Forecast Year 2019 to 2024

GlobalX-Ray Crystallography market competition by top manufacturers, with production, price, and revenue (value) and market share for each manufacturer; the top players including.

1. Scientific Equipment

2. Materials Science International

3. MVB Scientific

4. Rigaku

5. Shim

Mass Spectrometry market:

The growth of this market is majorly driven by technological advancements in mass spectrometry, government initiatives for pollution control and environmental testing, increasing spending on pharmaceutical R&D across the globe, government regulations on drug safety and growing petrochemical industry. However, the high cost of equipment is likely to restrain the growth of the market during the forecast period. The global mass spectrometry market is expected to reach USD 5.27 Billion by 2022 from USD 3.68 Billion in 2017, at a CAGR of 7.4%.

UV/Visible Spectroscopy market:

In the coming years, the market is expected to witness the highest growth rate in the Asia-Pacific region. However, longevity of instruments and the dearth of skilled professionals is likely to restrain the growth of the market to a certain extent during the forecast period. Market is poised to reach USD1,163.2 Million by 2021, growing at a CAGR of 4.3 % during the forecast period of 2016 to 2021.

Major Crystallography Associations around the Globe:

British Crystallography Association (BCA)
Indian Crystallographic Association (ICA)
European Crystallographic Association (ECA)
French Crystallographic Association (FCA)
Asian Crystallographic Association (ACA)
Turkish National Crystallographic Association
Croatian Crystallographic Association
International Union of Crystallography
German Society for Crystallography
German Mineralogical Society
Korean Crystallographic Association

Molecular Spectroscopy Market:

The molecular spectroscopy market is poised to grow at a CAGR of 7.0%, over the forecast period, 2019-2024. The prime factors that are responsible for the growth of the market include rapid adoption in the pharmaceutical industry, penetration of MS technology in various verticals, and increased emphasis for the discovery of newer molecules by pharmaceuticals. This rising affinity toward this technology has been widely adopted and has resulted in the growth of the market. Molecular spectroscopy is a technology that is widely adopted across the different application sectors, including pharmaceuticals and many others.

There have been continuous efforts in the pharmaceutical industry to undertake advanced research and development that is leading to increased adoption of various spectroscopy techniques, over the forecast period. There has also been an increase in the number of testing and research facilities, particularly in the field of pharmaceuticals. This will lead to the rise in the demand for laboratory and research equipment, such as molecular spectroscopy and other consumables. Hence, all these factors contribute to the increase of the market studied.

Key Market Trends:

NMR Spectroscopy is Expected to Show Highest Growth Over the Forecast Period This has also been found to be non-destructive and is analysed with the help of modern instruments. NMR techniques are also being used successfully in various food systems for quality control and research. NMR spectroscopy is used to determine the structure of proteins, amino acids profile, carotenoids, organic acids, lipid fractions, and the mobility of the water in foods. It is also used to identify and quantify metabolites in foods. In addition, the NMR spectroscopy is increasingly being used in biochemical and biological application areas, including hit and lead discovery, metabolite profiling, and in vivo spectroscopy (MRS)and imaging (MRI). The many new developments seen in the NMR spectroscopy are driving much-needed improvements in sensitivity and versatility. This will lead to the expansion of the number of applications of the technique, and hence, growth in the market studied.

Target Audience:

Materials Scientists /Research Professors /Spectroscopic Experts
Physicists /Chemists
Junior / Senior research fellows of Materials Science /Spectroscopy /Chemical Engineering
Directors of Materials/ Nanotechnologies /Spectroscopy companies
Members of different Materials Science, Physics, Chemistry, Spectroscopy, Crystallography Association

The Market Analysis report in terms of graphical representation

About Conference

This event will focus on Application of Modern Chemistry, Advanced Spectroscopy and variety of Crystallography Sessions including Chemical, Crystallography in Biology, Electron Crystallography, Crystallography Applications through invited plenary lectures, symposia, workshops, invited sessions, oral and poster presentations of unsolicited contributions. The conference provides more focused sessions like symposium, lectures, workshops on a variety of topics, poster presentations and various programs for participants from all over the world.The Conference gears up to provide you the opportunity to meet and interact with leading scholars, researchers, friends, colleagues, sponsors, exhibitors and functional change experience.

Maximize your personal involvement, engagement by getting together on Aug 31st - Sep 1st, 2020 with an interactive discussions and workshops at the conference, you will feel free to reach out and share your thoughts to continue your lifelong learning and build on the skills that make you successful. We invite you to join at International Conference on Crystallography and Structural Chemistry 2020 where you will be sure to have a meaningful experience with scholars around the world.