Theme: Modern breakthroughs in the field of Quantum Mechanics and Applications

Quantum Mechanics 2018

Quantum Mechanics 2018

Conference Series LLC Ltd invites you to find a path to carve out a near-to-perfect platform where people like you and us can get together, stand together and discuss these possibilities.

Quantum Mechanics, Atlanta has been finalized to take place during July 20-21, 2018 in Atlanta, USA and will initiate its journey towards its aim of unifying people from different corner of the globe with the theme “Modern breakthroughs in the field of Quantum Mechanics and Applications”.


As the premier event, we have developed a program with your interests in mind. We have not only increased the number of opportunities for you to network with colleagues from across the world but also introduced more focused sessions that will feature cutting edge presentations, special panel discussions, and livelier interaction with industry leaders and experts.


Attend Quantum Mechanics 2018 to network with your peers, exchange expertise and experiences, and arm yourself with the latest information to take your department to the next level.

About conference:

The Global Conference series event organizer Conference Series LLC Ltd  invites all the participants from all over the world to attend the prestigious scientific International Conference on “Quantum Mechanics and Applications” which is to be held during July 13-14, 2018 at Toronto, Canada. It is among the World’s leading Scientific Conference which hosts scientific sessions and sub-sessions on cutting edge research and latest innovations in the field of Quantum Physics and Quantum technology across the globe. The attendees can find some exclusive sessions and panel discussions on latest originations in Physics.

Why to attend Quantum Mechanics2018?

With members from around the world focused on Quantum physics and Quantum technology this is your best opportunity to reach the largest assemblage of participants from the universities, colleges, research centres, societies, institutions, labs, associations, communities and companies etc. We want to make a worldwide meet in which data between researchers from the different controls can be effectively traded. The explanation behind bringing the general population at the meetings together is to catalyse empowering trades and connections between experts in different fields, from physical science to engineering. It will make new interdisciplinary systems and permit members to trade know-how and data to accomplish speedier and better results.

The field of Quantum physics and Quantum technology have not only helped the development in different fields in science and technology but also contributed towards the improvement of the quality of human life. The core aim of Quantum2018 conference is to provide an opportunity for the delegates to meet, interact and exchange innovative ideas in the various areas of Quantum physics and its technology. The joy of attending Quantum Mechanics2018 brings with it improvement and incremental growth in your approach to do things, in the broader manner to see things in international diversity.

Target Audience:

  1.  Physics Scientists
  2.  Research students and Research Institute
  3.  Professors, Students, Researchers from Physics
  4.  Managers and Business Intellect Professionals
  5.  Business Professionals from Electronic Industries
  6.  Advertising and Promotion Agency Managers
  7.  Delegates from Physical and Materials Science societies and Associations

Related Societies:

  1. American Institute of Physics (AIP)
  2. American Physical Society (APS)
  3. Australian Institute of Physics
  4. Canadian Association of Physicists
  5. Colombian Society of Physics (in Spanish)
  6. Chilean Society of Physics (in Spanish)
  7. European Physical Society
  8. European Materials Research Society (EMRS)
  9. The Egyptian Materials Research Society
  10. French Physical Society
  11. International Association of Mathematical Physics (IAMP)
  12. Institute of Particle Physics, Canada (IPP)
  13. Institute of Physics, United Kingdom
  14. International Organization of Chinese Physicists and Astronomers
  15. International Union of Crystallography
  16. International Union of Pure and Applied Physics
  17. Italian Physical Society
  18. Physical Society of Germany (DPG)
  19. Physical Society of Japan
  20. Portuguese Society of Physics
  21. Swiss Physical Society
  22. Italian Association of Physics Students
  23. The Abdus Salam International Centre for Theoretical Physics
  24. The International Liquid Crystal Society
  25. The International society for optics and photonics

Conference opportunities:

For Researchers and Faculty members:

  • Speaker presentations
  • Poster presentation
  • Symposium hosting
  • Workshop organizing

For Universities, Associations & Societies:

  • Association partnering
  • Collaboration proposals
  • Academic partnering
  • Group participation

For students and Research scholars:

  • Poster competition
  • Young Researcher Forum
  • Student attendee
  • Group registrations

For Business Delegates:

  • Speaker presentations
  • Symposium hosting
  • Book launch event
  • Networking opportunities
  • Audience participation

For Product manufacturers:

  • Exhibitor and Vendor booths
  • Sponsorship opportunities
  • Product launch
  • Workshop organization
  • Scientific partnering
  • Marketing and Networking with clients


Sessions & Tracks

Session 1

Track 1: Quantum Science

A Quantum is the physical quantity that can exist freely, particularly a discrete amount of electromagnetic radiation. Quantum thermodynamics is an emerging research field aiming to extend standard thermodynamics and non-equilibrium statistical physics to ensembles of sizes well below the thermodynamic limit, in non-equilibrium situations, and with the full inclusion of quantum effects. Fuelled by trial propels and the capability of future nanoscale applications this research effort is pursued by scientists with dissimilar backgrounds, including mesoscopic physics, statistical physics, many-body theory and quantum information theory who bring numerous tools and methods to the field. A quantum dominated state of magnetism on a two-dimensional grid with only one turn for every unit cell has been looked for a considerable length of time. Quantum Nanoscience is the branch of nanotechnology and the assessment area and Physical Science that uses strategies for quantum mechanics to the outline of new sorts of nanoscale materials and nanodevices, where usefulness and structure of quantum nanodevices are represented through quantum marvels and standards, ex. superposition, discretisation and trap.


Track 2: Quantum Field Theories

The history of quantum field theory starts with its creation by Paul Dirac. He tried to quantize the electromagnetic field in the late 1920s. Major developments in the theory were made in the 1950s, and directed to the introduction of quantum electrodynamics (QED). QED was so successful and truly predictive that efforts were made to apply the same basic concepts for the other forces of nature. By the late 1970s, these efforts were successful in the utilization of gauge theory to the strong nuclear force and weak nuclear force, producing the modern standard model of particle physics. Efforts to describe gravity using the same techniques have, to date, failed. Learning of quantum field theory is still flourishing, as are applications of its methods to many physical problems. It remains one of the most vital areas of theoretical physics today, providing a common language to several different branches of physics.


Track 3: Quantum Mechanics

Quantum mechanics is the subdivision of physics relating to the very small. At the scale of electrons and atoms, several equations of classical mechanics, which define how things move at everyday speeds and sizes, cease to be useful. In classical mechanics, the objects stay in an exact place at an exact time. However, in quantum mechanics, objects instead exist in a haze of probability; they have a certain chance of being at point A, another chance of being at point B and so on. Vital implementation of quantum theory consists of quantum superconducting magnets, chemistry, the laser and light-emitting diodes, semiconductors and the transistor such as the research, microprocessor and medical imaging such as magnetic resonance imaging and electron microscopy. Descriptions for several physical and biological phenomena are rooted in the nature of the chemical bond, most notably the macro-molecule DNA. The second quantum revolution takes profit of the phenomenon of entanglement. It's a usual phenomenon that basic researchers recognized as early as the 1930s. Until now, all the technologies you mentioned derive their utility from the wave property upon which quantum physics is based. Though, they are not perceived all things considered, quantum innovations are accordingly officially present and without them, many of our instruments would not be conceivable. The nature of entanglement has been known for past 85 years by contrast, has only been experimentally studied in the last four decades based on results by John Bell in the 1960s. Nowadays, entanglement forms the basis for various new potential applications such as quantum metrology, quantum communications and quantum computing. The second quantum revolution is usually understood to be the realization of these new possibilities.


Track 4: String Theory & Quantum Gravity

Perhaps the greatest challenge of modern theoretical physics is the quantization of the gravitational field. A consistent theory of quantum gravity seems to be required to answer questions about the early universe and the nature of black holes. A few Candidate Theories have been advanced in the course of the most recent decades. From one perspective, Superstring Theory and Supergravity go for a unification of gravity with the other key cooperation, and have their origins in QFT. Then again, non-perturbative methodologies, for example, Loop Quantum Gravity, Spin Foams and Group Field Theory continue from essential standards of General Relativity (GR). The first core area concerns the underlying structures and symmetries of these different theories, with the aim of distilling the crucial physical and mathematical objects for the correct formulation of quantum gravity. Among the endeavors to bring together quantum theory and gravity, string theory has attracted the most attention. Its premise is simple: Everything is made of tiny strings. The strings may be closed unto themselves or have loose ends; they can vibrate, stretch, join or split. Furthermore, in these complex appearances lay the clarifications for all wonders we watch, both matter and space-time included.


Track 5: Quantum Chromodynamics

As per quantum physics attempted to enlarge into the nucleus of the atom, new strategies were required. The quantum theory of the atomic nucleus, and the particles that make it up, is called quantum chromodynamics (QCD). String theory arose out of an attempt to explain this same behavior. QED attempted to simplify the situation by only analyzing two aspects of the atom — the photon and the electron — which it could do by treating the nucleus as a giant, very distant object. The laws of subatomic physics dictate that individual quarks are never seen in the wild; they always travel around in twos or threes. At sufficiently high temperatures, however—such as those reached in a high-energy particle collider—protons and neutrons are thought to disintegrate into a soup, or plasma, of individual quarks and gluons, before cooling and recombining into ordinary matter. The small building blocks are antiquarks and quarks, in which all the stuff is built, binding together to form neutrons and protons in a procedure explained by quantum chromodynamics. Currently, scientists are searching for the existence of mesons that don't fit the traditional patterns. If a meson is found to weigh more than predictable, something else must be going on. Scientists call these hypothetical particles exotic mesons and believe that gluons play an important role in their structure.


Session 2

Track 6: Quantum Condensed Matter Physics

The field of condensed matter physics discovers the microscopic and macroscopic properties of matter. Condensed Matter physicists study how matter arises from a large number of interacting atoms and electrons, and what physical properties it has as a result of these interactions. Monte Carlo techniques are effective computational instruments for studies of equilibrium properties of classical numerous molecule systems. Using a stochastic process for generating random configurations of the system degrees of freedom, such methods simulate thermal fluctuations, so that expectation values of physical observables of interest are directly obtained by averaging “measurements” on the configurations. The worldwide superconducting wire market was valued at USD 638.1 Million in 2016, and is required to develop at a CAGR of 9.6% from 2016 to 2021. The growing demand for superconductor based MRI systems, advancement in computer chip design technology, and synergies of high voltage transmission application and high efficiencies are the major factors driving the superconducting wire market. For the worldwide magnetic sensors market, the size is relied upon to achieve USD 3.65 billion by 2022 as indicated by another report by Grand View Research, Inc. Asia Pacific region dominates the global market in terms of demand and is projected to grow at a CAGR of nearly 12% over the forecast period. Existence of chief end-use industries in the region has prompted an expanding demand for such sensing modules in the region. Countries such as China, Japan, and India house most of the technological and automotive giants leading to an escalating demand over the forecast period.


Track 7: Quantum Transport

Quantum transport is now inspected with great success in other experimental platforms as cold atomic systems and photonic. The study of quantum effects on transport properties has been a precious tool to unveil fundamental properties of quantum matter. At the same time, it has been the key to the design of new nano-devices with specific functionalities. The Global Heat Transfer Market is poised to grow at a CAGR of around 9.8% over the next decade to reach approximately $4.2 billion by 2025. This report estimates and forecasts for all the segments on global along with the regional levels presented in the research scope. Europe has the largest market share for heat transfer materials, followed by North America and Asia-Pacific. Europe accounted for more than one-third of global heat transfer fluid market. The major European market is in Spain and Germany. Asia-Pacific region is expected to witness higher growth rate compared to other regions. Europe is expected to remain the market leader owing to growing industrial expansion in the region. Emerging market in India and China is expected to raise the market share of Asia-Pacific in the global heat transfer market in upcoming future. The market size is calculated based on the revenue generated through sales from all the given segments and sub segments in the research scope. The market analysis includes bottom-up and both top-down approaches for exact measures and data validation.


Track 8: Quantum Optics

Quantum optics utilizes quantum-mechanical and semi-established material science to look at wonders including light and its joint efforts with issue at sub tiny levels. Quantum dots (QD) are very small semiconductor particles, only several nanometres in size, so small that their optical and electronic properties differ from those of larger particles. The quantum dot market is relied upon to develop at a noteworthy CAGR rate; it holds an awesome potential to various industries, for example, purchaser, healthcare among others. The quantum dots technology is used in many applications due to the technological advancement such as low energy consumption, vibrant displays. The quantum dots market is estimated to grow at a CAGR of 63.23% from 2014 to 2020, which includes an in-depth analysis of the market by product, application, material, and geography. This report depicts market drivers, trends, and challenges concerning the worldwide quantum dots market, and forecasts the market size from 2014 to 2020, based on the materials, products, geography, and applications. This worldwide report gives a point by point perspective of the market across regions, specifically – North America (the U.S., Canada, Mexico), Europe (France, Germany, the U.K., Others), Asia-Pacific (Japan, China, India, South Korea, Rest of APAC), and RoW. The competitive landscape of the market presents a very interesting picture. The market is seeing new item dispatches, huge scale joint efforts, and agreements and partnerships over the esteem chain, with a number of tier-one players around the globe. Major players in the global quantum dot market include QD Vision, Inc. (U.S.), Nanosys, Inc. (U.S.), Nanoco Group Plc. (U.K.) among many others.


Track 9: Quantum Information & Quantum Computing

Theoretically, quantum computing aids in transmission power and processing, and will be capable of solving complex problems quicker than modern classical binary supercomputers. Quantum computing technology has potential to change dynamics in commerce, military affairs and strategic balance of power. Rising investments to progress quantum computing solutions for commercial applications is expected to support growth of the Global Quantum Computing Market. The U.S. Department of Energy announced its plans to invest US$ 16 Mn, with the objective to aid in designing new materials for supercomputers in August 2016. In September 2016, the Government of Canada announced its plans to invest in The University of Waterloo's Institute for Quantum Computing, a Canada based research institute, received a grant of US$ 76 Mn for the development of quantum technology solutions. A quantum computing research hub - Networked Quantum Information Technologies was formed by the UK Government under the UK National Quantum Technologies Programme (UKNQTP). The quantum computing market in Asia Pacific (APAC) is expected to be commercialized by 2019. The growth of quantum computing would be mainly in industries such as healthcare & pharmaceuticals, power & energy, defence, banking & finance, chemicals and the list goes on. Many researchers working on this domain would be attending the conference to share their valuable works and this would be a perfect platform to share yours with the global community.


Track 10: Quantum Technology

Quantum technology is a new arena of engineering and physics. In quantum technology transitions some of the properties of quantum mechanics, especially quantum superposition, quantum entanglement and quantum tunnelling, into practical applications such as quantum sensing, quantum computing, quantum simulation, quantum cryptography, quantum imaging and quantum metrology. Quantum superposition states can be very sensitive to many external effects, such as electric, magnetic and gravitational fields; rotation, acceleration and time, and therefore can used to make very accurate sensors. Quantum secure correspondences are the methods which are anticipated to be 'quantum safe' in the approach of a quantum processing frameworks that could break current cryptography frameworks. One significant component of a quantum secure communication systems is expected to be Quantum key distribution, or 'QKD': a method of transmitting information using entangled light in a way that makes any interception of the transmission obvious to the user.



Quantum mechanics is science dealing with the behavior of matter and light on the atomic and subatomic scale. It attempts to describe and account for the properties of molecules and atoms and their constituents—electrons, protons, neutrons, and other more esoteric particles such as quarks and gluons. These properties include the interactions of the particles with one another and with electromagnetic radiation (i.e., light, X-rays, and gamma rays).

The study of quantum mechanics is rewarding for several reasons. First of all, it illustrates the essential methodology of physics. Secondly, it has been enormously successful in giving correct results in practically every situation to which it has been applied. There is, however, an intriguing paradox. In spite of the overwhelming practical success of quantum mechanics, the foundations of the subject contain unresolved problems—in particular, problems concerning the nature of measurement. An essential feature of quantum mechanics is that it is generally impossible, even in principle, to measure a system without disturbing it; the detailed nature of this disturbance and the exact point at which it occurs are obscure and controversial. Thus, quantum mechanics attracted some of the ablest scientists of the 20th century, and they erected what is perhaps the finest intellectual edifice of the period.

Conference Series Ltd invites you to find a path to carve out a near-to-perfect platform where people like you and us can get together, stand together and discuss these possibilities. We welcome you to attend the International Conference on Quantum Mechanics and Applications which is going to be held in during July 20-21, 2018 in Atlanta, USA.

So let us all join and walk towards a new era of Quantum Mechanics with a aim to unify people from all around the globe.

Why Atlanta?

Atlanta is the capital of and the most populous city in the U.S. state of Georgia, with an estimated 2016 population of 472, 522. Atlanta is the cultural and economic center of the Atlanta metropolitan area, home to 5,710,795 people and the ninth-largest metropolitan area in the United States. Atlanta is the seat of Fulton County and a small portion of the city extends eastward into DeKalb County. Atlanta's economy is considered diverse, with dominant sectors that include logistics, professional and business services, media operations, and information technology. Atlanta has topographic features that include rolling hills and dense tree coverage, earning it the nickname of “the city in a forest”.

Atlanta is divided into 242 officially defined neighborhoods. The city contains three major high-rise districts, which form a north-south axis along Peachtree: Downtown, Midtown, and Buckhead. Surrounding these high-density districts are leafy, low-density neighborhoods, most of which are dominated by single-family homes. Downtown Atlanta contains the most office space in the metro area, much of it occupied by government entities. Downtown is home to the city's sporting venues and many of its tourist attractions. Midtown Atlanta is the city's second-largest business district, containing the offices of many of the region's law firms. Midtown is known for its art institutions, cultural attractions, institutions of higher education, and dense form. Buckhead, the city's uptown district, is eight miles (13 km) north of Downtown and the city's third-largest business district. The district is marked by an urbanized core along Peachtree Road, surrounded by suburban single-family neighborhoods situated among dense forests and rolling hills.

Top Companies:

1.     Cambridge Quantum Computing Limited

2.     HRL Laboratories

3.     Quantum Biosystems

4.     1QBit

5.     Optalysys

6.     QC Ware

7.     Magi Q

Market Analysis:

The global quantum cryptography forecasts the market size to grow from USD 285.7 Million in 2017 to USD 943.7 Million by 2022, at a Compound Annual Growth Rate (CAGR) of 27.0%. The quantum cryptography market is segmented on the basis of component (hardware and services), application, organization size, vertical, and region. The quantum cryptography market is witnessing a growing incident of cyber-attacks and increasing data security and privacy concerns. The major vendors in the quantum cryptography market include ID Quantique (Switzerland), MagiQ Technologies (US), Nucrypt (US), Infineon Technologies (Germany), Qutools (Germany), QuintenssenceLabs (Australia), Crypta Labs (UK), PQ Solutions (UK), and Qubitekk (US).

The global quantum cascade lasers market is expected to grow from USD 302.9 Million in 2016 to USD 374.8 Million by 2022 at a CAGR of 3.9% between 2017 and 2022. The report aims at estimating the market size and future growth potential of the QCL market based on packaging type, operation mode, fabrication technology, and geographic analysis. The report also aims at providing detailed information regarding the major factors influencing the growth of the quantum cascade laser market (drivers, restraints, opportunities, and industry-specific challenges) and strategically analyzes micromarkets with respect to the individual growth trends, future prospects, and contributions to the total market. The base year considered for the study is 2016, and the market size forecast is provided for the period between 2017 and 2022.

Quantum dots are small particles made of semiconductor materials; they exhibit quantum mechanical properties. Quantum dots have the capability to change light into any color in a visible spectrum with a high efficiency.  This technology can convert incoming energy into a color. Size and shape of quantum dots denote its electronic properties

The QD-based market research report takes an insight into the market through market size forecasts, value chain, market & product trends, competitive landscape, leading participants and their key developments, strategies, and profiles. It also analyzes the market by product, application, and material. The report also deals with all driving factors, restraints, and opportunities with respect to the global quantum dots market, which are helpful in identifying trends and key success factors for the industry. The report also provides an in-depth view on the material and, product markets along with drivers, opportunities, and restraints of the quantum dot market. The quantum dot market is estimated to reach $4,704.86 million by 2020, at a CAGR of 63.61% from 2014 to 2020.

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Conference Date July 20-21, 2018 -
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