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rachnasagargrp · 4 years ago

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Get Latest CBSE Sample Paper (MCQ) Science for 2021 Term 1 Board Exams- Rachna Sagar

Together with CBSE Sample Paper, Science has been designed as per the special scheme of assessment vide CBSE Circular No. 75/2021 for Term 1 ( For 2021 Nov-Dec Examination ) for Class 10 has been prepared as per the latest assessment pattern.

Together with EAD Science Sample Paper (with answers) is a perfect step-by-step approach to ensure one’s readiness for Term 1 board examination. This Sample Paper for Class 10 assists the students with the right practice and approach to the newest MCQ pattern.

EAD—Easy, Average, Difficult

The content matter in this EAD 12+1 Science Sample Paper Class 10 has been arranged as complete papers with three levels of difficulty—Easy, Average and Difficult (EAD).

Easy: The first set of papers in this CBSE Sample Paper 2021 is based on 'Easy' concept, thus contains Multiple Choice Questions of simple level, which a student can attempt at the beginning of the preparatory stage.

Average: The next set based on 'Average' concept (MCQs) is graded to a level of difficulty to test mid-level preparedness for the examination.

Difficult: The challenging papers allocated to the third set based on 'Difficult' concept are a test of complete preparedness for the examination.

The EAD sample paper is a self-test drive for the students.

Key Features

This Sample Paper includes:

CBSE (2021-2022) Term 1 Sample Paper.

3 Sample Papers each of Easy, Average & Difficult level.

2 Pre-Board Papers based on CBSE pattern.

1 Mock Paper Based On CBSE Pattern with OMR Sheet.

Includes Assertion Reasoning and Case-Based Objective Type Questions.

The 4-Step Process

Step 1 The students are advised to attempt the set of EASY Papers first and obtain at least 80% marks to move onto the next set of papers which is Average.

Step 2 If the student obtains 75% marks in the AVERAGE category of this EAD 12+1 Science Sample Paper Class 10, he/she can switch to the next category, i.e., Difficult.

Step 3 If 70% marks in DIFFICULT category have been obtained, the students are expected to take the PRE-BOARD PAPERS that are exactly based on the CBSE pattern.

Step 4 Attempt the MOCK PAPER (given at the end) for a final-go for your board exam preparations.

Why EAD Latest Sample Papers?

Learning gets strengthened with practice and its evaluation uplifts the preparation. The answers of the MCQs have been given at the end of each Sample Paper for evaluation purposes. The CBSE Sample Papers for class 10 All Subjects 2021-2022 have been prepared by a panel comprising experienced teachers, tabulators and examiners, who have jointly come up with a student-friendly approach to prepare the students for the forthcoming CBSE Board Examination. Repetitive practice of CBSE Sample Papers for class 10 All Subjects 2021-2022 will surely help the students to make their mark in the CBSE Board Examination.

Good Luck!

#BOARD PAPERS #term 1 Science Sample Paper Class 10 #EAD sample paper #Term 1 CBSE Sample Papers for class 10 #CBSE Sample Paper #Class 10 #CBSE Class 10 #board exams #CBSE Sample Papers for class 10 #Term 1 Sample Papers for class 10

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nemesisbinxartifactseries · 6 years ago

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Artifact Series J

J. Allen Hynek's Telescope

J. Edgar Hoover's Tie

J. McCullough's Golf Ball

J. Templer's Wind-Up Tin Rooster *

J. C. Agajanian’s Stetson

J.T. Saylors's Overalls

J.M. Barrie’s Swiss Trychels

J.M.W. Turner's Rain, Steam and Speed-The Great Western Railway *

J.R.R. Tolken's Ring

Jack-in-the-Box

Jack's Magic Beanstalk

Jack Daniel's Original Whisky Bottle

Jack Dawson's Art Kit

Jack Duncan's Spur *

Jack Frost's Staff

Jack Kerouac's Typewriter

Jack Ketch's Axe

Jack LaLanne's Stationary Bike *

Jack London's Dog Collar

Jack Parson's Rocket Engine

Jack Sheppard's Hammer

Jack Sparrow's Compass

Jack Torrance's Croquet Mallet

Jack the Ripper's Lantern *

Jackie Robinson's Baseball

Jackson Pollock's "No. 5, 1948"

Jackson Pollock's Pack of Cigarettes

Jackson Pollock's Paint Cans

Jack's Regisword

Jack Vettriano's "The Singing Butler"

Jack's Wrench

Jacob and Wilhelm Grimm's Kinder- und Hausmarchen

Jacob "Jack" Kevorkian's Otoscope

Jacob Kurtzberg's Belt *

Jacqueline Cochran's Brooch

Jacques Aymar-Vernay’s Dowsing Rod

Jacques Cousteau's Goggles

Jacques Cousteau's Diving Suit

Jacques-Louis David's Napoleon Crossing the Alps *

Jade Butterfly

Jadeite Cabbage

Jalal-ud-Din Muhammad Akbar's Smoke Pipe

Jamaica Ginger Bottle

Jaleel White's Hosting Chair

James Abbot McNeill Whistler's Whistler's Mother *

James Allen's Memoir

James Bartley's Britches

James Ben Ali Haggin's Leaky Fountain Pen

James Bert Garner’s Gas Mask

James Bett's Cupboard Handle

James Braid's Chair *

James Brown's Shoes

James Bulger's Sweater

James Buzzanell's Painting "Grief and Pain"

James Buzzanell’s Survey Books

James C. McReynolds’ Judicial Robe

James Chadwick's Nobel Prize

James Clerk Maxwell's Camera Lens

James Colnett's Otter Pelt

James Condliff's Skeleton Clock

James Cook's Mahiole and Feather Cloak

James Craik's Spring Lancet

James Dean's 1955 Prosche 550 Spyder, aka "Little Bastard"

James Dean's UCLA Varsity Jacket

James Dinsmoor's Dinner Bell

James Eads How’s Bindle

James Earl Ray's Rifle

James Fenimore Cooper's Arrow Heads

James Gandolfini's Jukebox

James Hadfield’s Glass Bottle of Water

James Hall III’s Shopping Bags

James Henry Atkinson's Mouse Trap

James Henry Pullen’s Mannequin

James Hoban's Drawing Utensils

James Holman’s Cane

James Hutton's Overcoat

James Joyce’s Eyepatch

James M. Barrie's Grandfather Clock

James M. Barrie's Suitcase

James Murrell's Witch Bottle

James Philip’s Riata

James Prescott Joule's Thermodynamic Generator

James Smithson's Money

James Tilly Matthews’ Air Loom

James Warren and Willoughby Monzani's Piece of Wood

James Watt's Steam Condenser

James Watt's Weather Vane

James W. Marshall’s Jar

Jan Baalsrud’s Stretcher

Jan Baptist van Helmont's Willow Tree

Jane Austen's Carriage

Jane Austen's Gloves

Jane Austen's Quill

Jane Bartholomew's "Lady Columbia" Torch

Jane Pierce's Veil

Janet Leigh's Shower Curtain

Janine Charrat's Ballet Slippers

Jan Janzoon's Boomerang *

Janis Joplin's Backstage Pass from Woodstock *

Jan Karski's Passport

Janus Coin *

Jan van Eyck’s Chaperon

Jan van Speyk's Flag of the Netherlands

Jan Wnęk's Angel Figurine

Jan Žižka's Wagenburg Wagons

The Japanese Nightingale

Jar of Dust from the Mount Asama Eruption

Jar of Greek Funeral Beans

Jar of Marbles

Jar of Molasses from The Boston Molasses Disaster

Jar of Sand

Jar of Semper Augustus Bulbs

Jar of Shiva

Jar of Sugar Plums

Jascha Heifetz's Violin Bow

Jason Voorhese's Machete

Javed Iqbal's Barrel of Acid

Jay Maynard's Tron Suit

Jean II Le Maingre's Gauntlets

Jean Baptiste Charbonneau’s Cradleboard

Jean-Baptiste-Siméon Chardin's Bubble Pipe

Jean Chastel's Silver Gun

Jean Eugène Robert-Houdin's Pocket Watch

Jean Fleury's Aztec Gold Coins

Jean-François Champollion’s Ideographic Dictionary

Jean Froissart's Mirror *

Jean-Frédéric Peugeot's Pepper Mill

Jean Hilliard’s Earmuffs

Jean Parisot de Valette’s Sword Sheath

Jean-Paul Marat's Bathtub

Jean Paul-Satre’s Paper Cutter

Jean-Pierre Christin's Thermometer

Jean Senebier's Bundle of Swiss Alpine Flowers

Jean Valnet's Aromatherapy Statue

Jean Vrolicq’s Scrimshaw

Jeanne Baret's Hat

Jeanne de Clisson's Black Fleet

Jeanne Villepreux-Power's Aquarium

Jeannette Piccard's Sandbag

Jeff Dunham's First Ventriloquist Box

Jefferson Davis' Boots

Jefferson Randolph Smith's Soap Bar

Jeffrey Dahmer's Handkerchief

Jeffrey Dahmer's Pick-Up Sticks

Jemmy Hirst's Carriage Wheel

Jenny Lind's Stage Makeup

Jeopardy! Contestant Podiums

Jerome Monroe Smucker's Canning Jars

Jerry Andrus’ Organ

Jerry Garcia's Blackbulb *

Jerry Siegel's Sketchbook

Jesse James' Saddle

Jesse James' Pistol

Jesse Owens' Hitler Oak

Jesse Owens' Running Shoes

Jesse Pomeroy's Ribbon and Spool

Jester's Mask

Jesus of Nazareth's Whip

Jesús García's Brake Wheel

Jet Engine from the Gimli Glider

Jet Glass Cicada Button

Jethro Tull's Hoe

Jeweled Scabbard of Sforza

Jiang Shunfu’s Mandarin Square

Jim Davis' Pet Carrier

Jim Fixx's Shorts

Jim Henson's Talking Food Muppets

Jim Jones' Sunglasses

Jim Londos' Overalls

Jim Robinson's Army Bag

Jim Thorpe's Shoulder Pads

Jim Ward's Piercing Samples

Jimi Hendrix's Bandana

Jimi Hendrix's Bong

Jimi Hendrix's Guitars *

Jimmie Rodgers Rail Brake

Jimmy Durante's Cigar

Jimmy Gibb Jr's Stock Car

Jimmy Hoffa's Comb

Jin Dynasty Chainwhip

Jingle Harness

Joan II, Duchess of Berry's Dress

Joan of Arc's Chain Mail

Joan of Arc's Helmet (canon)

Joan Feynman's Ski Pole

Joanna of Castile's Vase

Joan Rivers' Carpet Steamer

Joan Rivers' Red Carpet

Joe Ades's Potato Peeler

Joe Girard’s Keys

Joe Rosenthal's Camera Lens

Joel Brand's Playing Cards

Joséphine de Beauharnais' Engagement Ring

Johan Alfred Ander’s Piece of Porcelain

Johann Baptist Isenring’s Acacia Tree

Johann Bartholomaeus Adam Beringer's Lying Stones

Johann Blumhardt's Rosary

Johann Dzierzon’s Beehive Frame

Johann Georg Elser's Postcard

Johann Maelzel's Metronome *

Johann Rall's Poker Cards

Johann Tetzel's Indulgence

Johann Wolfgang von Goethe's Prism

Johannes Brahms' Coffee Creamer

Johannes Diderik van der Waals' Gloves

Johannes Fabricius' Camera Obscura

Johannes Gutenburg's Memory Paper *

Johannes Gutenburg's Printing Press *

Johannes Gutenberg's Printing Press Keys

Johannes Kepler's Planetary Model

Johannes Kepler's Telescope Lense

Johannes Kjarval’s Landscape Painting

John A. Macready's Ray-Bans *

John A. Roebling's Steel Cable

John A.F. Maitland's Musical Brainnumber *

John André’s Stocking

John Anthony Walker's Minox

John Axon's Footplate

John Babbacombe Lee’s Trapdoor

John Bardeen's Radio

John Bodkin Adams’ Stethoscope

John Brown's Body *

John Brown's Machete

John C. Koss SP3 Stereophones

John C. Lilly's Isolation Tank Valve

John Cabot's Map

John Carl Wilcke's Rug *

John Crawley's Painting

John Croghan's Limestone Brick

John Dalton's Weather Vane

John Dee's Golden Talisman

John Dee's Obsidian Crystal Ball

John Dee’s Seal of God

John DeLorean's Drawing Table

John Dickson Carr's Driving Gloves

John Dillinger's Pistol *

John D. Grady’s Satchel

John D. Rockefeller's Bible

John D. Rockefeller, Sr. and Jr.'s Top Hats

John Dwight's Hammer

John F. Kennedy's Coconut

John F. Kennedy's Presidental Limousine

John F. Kennedy's Tie Clip *

John Flaxman's Casting Molds

Sir John Franklin's Scarf

John Gay's Shilling

John Gillespie Magee, Jr.'s Pen

John H. Kellogg's Bowl

John H. Kellogg's Corn Flakes

John H. Lawrence's Pacifier

John Hancock's Quill

John Harrison’s Longcase Clock

John Hawkwood’s Lance

John Hendrix's Bible

John Henry Moore's White Banner

John Henry's Sledge Hammer

John Hetherington's Top Hat

John Holland, 2nd Duke of Exeter's Torture Rack

John Holmes Pump *

John Hopoate's Cleats

John Howard Griffin's Bus Fare

John Hunter's Stitching Wire

John Hunter's Surgical Sutures

John J. Pershing's Boots

John Jacob Astor's Beaver Pelt

John Jervis’ Ship

John Joshua Webb’s Rock Chippings

John Kay's Needle

John Keat's Grecian Urn *

John, King of England's Throne

John L. Sullivan's Boots

John Langdon Down's Stencils

John Lawson's Mannequin Legs

John Lennon's Glasses

John "Liver-Eating" Johnson's Axe

John Logie Baird's Scanning Disk *

John M. Allegro's Fly Amanita

John Macpherson's Ladle

John Malcolm's Chunk of Skin

John Malcolm's Skin Wallet

John McEnroe's Tennis Racket *

John Milner's Yellow '32 Ford Deuce Coupe

John Moore-Brabazon’s Waste Basket

John Morales' McGruff Suit

John Mytton’s Carriage

John Pasche's Rolling Stones Poster Design

John Paul Jones's Sword

John Pemberton's Tasting Spoon

John Philip Sousa's Sousaphone

John Rambo's Composite Bow

John Rykener's Ring

John Shore's Tuning Fork

John Simon's Mouthwash

John Simon Ritchie's Padlock Necklace

John Smith of Jamestown's Sword

John Snow's Dot Map

John Snow’s Pump Handle

John Stapp’s Rocket Sled

John Steinbeck's Luger

John Sutcliffe's Camera

John Sutter's Pickaxe

John Tunstall's Horse Saddle

John Trumbull's "Painting of George Washington"

John von Neumann's Abacus

John Walker's Walking Stick

John Wayne Gacy's Clown Painting *

John Wayne Gacy's Facepaint

John Wesley Hardin's Rosewood Grip Pistol

John Wesley Powell's Canoe

John Wesley Powell’s Canteen

John Wilkes Booth's Boot *

John Wilkes Booth Wanted Poster

John William Polidori's Bookcase

Johnny Ace's Gun

Johnny Appleseed's Tin Pot *

Johnny Campbell's University of Minnesota Sweater

Johnny Depp's Scissor Gloves

Johnny Smith's Steering Wheel

Johnny Weismuller's Loincloth *

Joker's BANG! Revolver

Jon Stewart's Tie

Jonathan Coulton's Guitar

Jonathan R. Davis' Bowie Knife

Jonathan Shay's Copy of Iliad/Odyssey

Jonestown Water Cooler

Jorge Luis Borges' Scrapbook

José Abad Santos' Pebble

José Delgado’s Transmitter

Jose Enrique de la Pena's Chest Piece

Jōsei Toda’s Gohonzon Butsudan

Josef Frings’ Ferraiolo

Josef Mengele's Scalpel

Josef Stefan's Light Bulbs

Joseph of Arimathea's Tomb Rock

Joseph of Cupertino's Medallion *

Joseph Day's Sickle

Joseph Ducreux's Cane

Joseph Dunninger's Pocket Watch

Joseph Dunningers’ Props

Joseph E. Johnston Confederate Flag

Joseph Force Crater's Briefcases

Joseph Fourier's Pocket Knife

Joseph Glidden’s Barbed Wire

Joseph Goebbels' Radio *

Joseph Jacquard's Analytical Loom

Joseph Bolitho Johns’ Axe

Joseph Kittinger's Parachute

Joseph Lister's Padding

Joseph McCarthy's List of Communists

Joseph Merrick's Hood

Joseph-Michel Montgolfier's Wicker Basket

Joseph Moir’s Token

Joseph Pilate's Resistance Bands *

Joseph Polchinski’s Billiard Ball

Joseph Stalin's Gold Star Medal *

Joseph Stalin's Sleep Mask *

Joseph Swan's Electric Light

Joseph Vacher's Accordion

Joseph Vacher's Dog Skull

Joseph Valachi's '58 Chevrolet Impala

Josephus' Papyrus

Joseph Wolpe's Glasses

Josephine Cochrane's Dishwasher

Joshua's Trumpet *

Josiah S. Carberry's Cracked Pot

Joshua Vicks' Original Batch of Vicks Vapor Rub

Josiah Wedgewood's Medallion

Jost Burgi's Armillary Sphere *

Jovan Vladimir's Cross

Juana the Mad of Castiles' Crown

Juan Luis Vives' Quill Set

Juan Moreira’s Facón

Juan Pounce de Leon's Chalice

Juan Ponce de León's Helmet

Juan Seguin's Bandolier

Jubilee Grand Poker Chip *

Judah Loew ben Belazel's Amulet *

Judas Iscariot’s Thirty Silver Coins

Judson Laipply's Shoes

Jules Baillarger's Decanter

Jules Leotard's Trapeze Net

Jules Verne's Original Manuscripts

Julia Agrippa's Chalice

Julia Child's Apron *

Julia Child's Whisk

Julian Assange’s Flash Drive

Julie d’Aubigny's Sabre

Julius and Ethel Rosenberg's Wedding Rings

Julius Asclepiodotus’ Shield Boss

Julius Caesar's Wreath

Julius Wilbrand's Lab Coat Buttons *

Jumanji

Jumper Cables

Junji Koyama’s Vegetables

Jure Sterk's Ballpoint Pen

Jürgen Wattenberg's Leather Provision Bag

Justa Grata Honoria’s Engagement Ring

Justin Bieber's Guitar

Justinian I's Chariot Wheel

Justin O. Schmidt's Wasp Mask

Justus von Liebig's Fertilizer Sack

Justus von Liebig's Mirror

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kathleenseiber · 4 years ago

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‘Like venom causing through the body’ – Enzyme may drive COVID death

Related to the neurotoxins in rattlesnake venom, this enzyme may predict whether a patient will die from COVID.

Researchers have identified what they believe to be the key driver behind COVID-19 severity and mortality – an enzyme that, if targeted therapeutically, could potentially help treat the disease.

According to a new study in The Journal of Clinical Investigation, the culprit is an enzyme that plays a role in severe inflammation in the body, and that’s related to the neurotoxins found in deadly rattlesnake venom.

The researchers, from the University of Arizona, in collaboration with Stony Brook University and Wake Forest University, all in the US, analysed blood samples from two cohorts of COVID patients and found that circulation of this enzyme – secreted phospholipase A2 group IIA, known more succinctly as sPLA2-IIA – may be the biggest predictor of whether a patient will die from the disease.

sPLA2-IIA is found in low concentrations in the healthy human body, and can defend it against bacterial infections by destroying the cell membranes of microbes. But, when the enzyme circulates at high levels, it can “shred” the membranes of vital organs, according to Floyd ‘Ski’ Chilton, senior author on the paper.

“[It] shares a high sequence homology to the active enzyme in rattlesnake venom and, like venom coursing through the body, it has the capacity to bind to receptors at neuromuscular junctions and potentially disable the function of these muscles,” says Chilton

“It’s a bell-shaped curve of disease resistance versus host tolerance. In other words, this enzyme is trying to kill the virus, but at a certain point it is released in such high amounts that things head in a really bad direction, destroying the patient’s cell membranes and thereby contributing to multiple organ failure and death.”

Together with available clinically tested sPLA2-IIA inhibitors, “the study supports a new therapeutic target to reduce or even prevent COVID-19 mortality,” says study co-author Maurizio Del Poeta, a professor in the Department of Microbiology and Immunology in the Renaissance School of Medicine at Stony Brook University.

Read more: What’s it like to have severe COVID-19?

“The idea to identify a potential prognostic factor in COVID-19 patients originated from Dr Chilton. He first contacted us last fall with the idea to analyse lipids and metabolites in blood samples of COVID-19 patients.”

Del Poeta and his team collected plasma samples, analysed medical charts and tracked down clinical data from 127 patients hospitalised at Stony Brook University between January and July 2020. A second independent cohort included 154 patient samples collected from Stony Brook and Banner University Medical Center in Tucson between January and November 2020.

“These are small cohorts, admittedly, but it was a heroic effort to get them and all associated clinical parameters from each patient under these circumstances,” says Chilton. “As opposed to most studies that are well planned out over the course of years, this was happening in real time on the ICU floor.”

The researchers used machine-learning algorithms to analyse thousands of data points, factoring in typical risk factors, including age, body mass index and pre-existing conditions, as well as more unusual factors such as biochemical enzymes and lipid metabolite levels.

Co-author Justin Snider, of the University of Arizona, says the role of sPLA2-IIA enzyme was an unexpected revelation. “The metabolites that surfaced revealed cell energy dysfunction and high levels of the sPLA2-IIA enzyme. The former was expected but not the latter.”

Using the same machine-learning methods, the team then developed a decision tree to predict COVID-19 mortality. They found that while most healthy individuals have around half a nanogram of the enzyme per millilitre circulating in their bloodstream, COVID-19 was particularly lethal among patients who had high levels of the enzyme, equal to or greater than 10 nanograms per millilitre.

“Many patients who died from COVID-19 had some of the highest levels of this enzyme that have ever been reported,” says Chilton, who has been studying the enzyme for more than 30 years.

Now, the team hopes to focus its efforts on identifying whether the enzyme is responsible for the existence of long COVID.

‘Like venom causing through the body’ – Enzyme may drive COVID death published first on https://triviaqaweb.weebly.com/

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awesomechrisharry · 4 years ago

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Kaolin Clay Market: Sales, Consumption, Demand and Forecast (2020-2025)

A new professional report Global Kaolin Clay market provides complete analysis about the market size, share, overview and growth prospects which are impacting the growth of the market. Global Kaolin Clay market report helps consumers to recognize the market challenges and opportunities. The Kaolin Clay market report extensively offers the latest information about the technological developments and market growth prospect on the basis of the regional landscape.

Request Free Sample Copy of Research Report at: https://optimusmarketreports.com/request-sample/432

The information available within the global Kaolin Clay market report isn't only supported the facts but also on the case studies, which analysts have included to deliver appropriate information to the clients during a well-versed manner. Moreover, for better understanding, the report includes statistical figures, graphs, tables, and charts associated with the knowledge mentioned in textual form. The report also provides the market dynamics like drivers, restraints, strategies & guidelines, trends, avenues, and technological improvements anticipated to possess an impression on the Kaolin Clay Market growth within the projected period.

Key Players in the global Kaolin Clay market covered in Reports:

BASF, Imerys, Ashapura Group, EICL Ltd., SCR-Sibelco, Thiele Kaolin Company, Kamin LLC, Lasselsberger Group, Quarzwerke GmbH, Sedlecky Kaolin A.S., 20 Microns, I-Minerals Inc., Kerakaolin, PLC., Kaolin Ead, Minotaur Exploration, Jiangxi Sincere Mineral Industry Co., Ltd., Active Minerals International, LLC., Burgess Pigment Company, Kaolin (Malaysia) Sdn. Bhd., Kerala Clays & Ceramic Products Ltd., UMA Group of Kaolin, Manek Group of Companies, Goonvean Holdings Ltd., Shree Ram Minerals, Mota Ceramic Solutions

Key Types in the global Kaolin Clay market covered in Reports:

Calcined

Water-Washed

Surface-Modified

Key Applications in the global Kaolin Clay market covered in Reports:

Paper

Ceramics

Fiberglass

Paints & Coatings

Rubber

Request for Discount of Research Report at: https://optimusmarketreports.com/request_discount/432

Regions & Countries Mentioned within the Kaolin Clay Report:

North America (United States)

Europe (Germany, France, UK)

Asia-Pacific (China, Japan, India)

Latin America (Brazil)

The Middle East & Africa

Key questions answered through this market research report:

What Are Market Kaolin Clay Market? What Are Challenges and Opportunities?

What Should Be Entry Strategies, Counter measures to Economic Impact, Marketing Channels for Kaolin Clay Industry?

Who Are the worldwide Key Players during this Kaolin Clay Market?

What’s market research of Kaolin Clay Market by Taking Applications and kinds in Consideration?

what's Economic Impact on Kaolin Clay Industry?

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About Us

Optimus Market Research is a premium market research report provider.We have successfully delivered research reports to greater than 800+ global clients.Our primary goal is to achieve in depth research analysis to help our clients with the most accurate business insights.We provide actionable insights through reports to make the right business decisions.OMR believes in giving you the perfect solution for your investment and therefore we interact with the clients to identify their principal needs and prepare real-time data to match them. Likewise we not only help by providing reports but also help them come up with ideas that would make them unique and unprecedented so that they may come at par or even overthrow your market competition.

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#Kaolin Clay Market #Kaolin Clay Market 2021

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lupine-publishers-oajess · 4 years ago

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Lupine Publishers |Stiffening of Clay by the Use of Paper Fly Ashes

Lupine Publishers | Open Access Journal of Environmental and Soil Sciences

Abstract

To improve the stiffness and bearing capacity of natural soils, traditionally lime or cement is used. This research focuses on the performance of an industrial residual product paper fly ash (generally treated as waste) as an alternative binder for soil stabilization. The present report summarizes the research carried out at the Ghent University. The research focused on the stabilization of kaolinite and bentonite clay. The experimental research consisted on monitoring the evolution of stiffening by time of a number of soil samples mixed with paper fly ashes. To this end, a non-destructive test was implemented to evaluate the small-strain stiffness of each specimen at different stages of curing. Kaolinite clay was chosen as reference clay material for stabilization. A commercial processed kaolin Rotoclay HB (Goonvean, St. Austell, UK) was used in this investigation. Kaolinite shows relatively low plasticity levels comparable to commonly found fine-grained soils. The non-destructive free resonant column test was used to evaluate the small-strain Young’s modulus (E0 ) of the soil specimens after stabilization with paper fly ash. The limited scatter of data suggests good repeatability and reliability. The first conclusions with regard to the application for soil stabilization are discussed.

Keywords: Soil Improvement; Paper Fly Ashes; Lime; Kaolinite; Bentonite; Free Resonant Column Test

Introduction

A limited bearing capacity of the subsurface may be the result of a bad quality and/or an insufficient compaction of the natural soil. For sandy soils the technique of improvement is in many cases compaction. For fine graded soils, and in case compaction doesn’t result in a higher bearing capacity, the soil can be mixed with stabilizing material. Traditionally lime or cement is used. Åhnberg [1] made an evaluation of the effect of different binders on the mechanical characteristics of clayey soils. In this research no direct relation could be made between the types of binders and the results of the modified soil characteristics. The authors confirmed that the change in strength of the soil depends on a number of factors. Previous research at the Ghent University proved that mixing paper fly ash improved the bearing capacity. Recently more research was carried out to confirm these results. Paper fly ash, with a significant lime content, results from the process of paper production. It is a residual product after incineration of paper and wood. The working effect of paper fly ashes as a binder are still insufficiently studied. The paper fly ashes discussed in this article have a large amount of free lime (9%). When paper fly ashes are mixed with clay two reactions occur [2]. In the first reaction there is an exchange of the cations in the soil and a flocculation immediately after mixing the binder with the clay. The second reaction is the pozzolanic reaction. This is a very slow reaction between CaO, H2O, SiO2 and Al2O3. In a previous study, made by Servaco [3] a lot of test results on the composition of paper fly ash were examined. In a later research Libbrecht [4] proposed 5% as an optimum percentage for mixing with silt. For this content the maximum CBR-value was reached. Out of a detailed research on the characteristics of paper fly ashes, made by the BAS Research and Technology Center [5], it could be concluded that paper fly ash contains a large percentage (13 %) of the mineral belite. Belite is also found in Portland cement and ensures the strength development over time. In 2018 [6] a first research on the influence of paper fly ashes on the stability of clay was made.

Materials and Methods

Kaolin clay was chosen as reference clay material for stabilization. A commercial processed kaolin Rotoclay HB (Goonvean, St. Austell, UK) was used in this investigation. Kaolinite shows relatively low plasticity levels, comparable to commonly found fine-grained soils. Table 1 summarizes some properties of this material. A freshly produced batch of paper fly ashes was provided by ATA International (commercial name Ecolime). The stiffening of Kaolin clay specimens stabilized with Ecolime at 6% dosage was monitored for a curing period of almost 200 days. The dosage of Ecolime was set based on the Eades & Grim test which determines the saturation dosage [7]. The test consists in measuring the pH of different soil-additive mixtures at different dosages and comparing them to the pH of the additive saturated solution (reference pH). The results of this test are illustrated in Figure 1. The upper boundary of Ecolime dosage for Kaolin clay treatment is about 6% in dry weight. Higher amounts of additive will produce no additional improvement. Therefore, it was decided to prepare samples at a dosage of 6%. Kaolin clay and Ecolime (at a dosage of 6%) were initially dry mixed in a dough mixer to ensure homogeneous distribution of the additive. Then, water was added to bring the mixture close to the optimum water content for standard Proctor compaction (w = 27%). Then, a number of specimens were compacted and cylindrical samples with a diameter of 50 mm and height of 100 mm were obtained through cutting and trimming. All specimens were allowed to cure in a humid environment at constant temperature of about 20oC.

The non-destructive free-free resonant column test was implemented here to evaluate the small-strain Young’s modulus (E0) of the soil specimens stabilized with Ecolime. The testing setup is illustrated in Figure 2. It consists of an accelerometer put in contact with the soil specimen at one end. At the other end, the soil specimen is impacted with a light hammer. The sample is laid horizontally on soft foam. The impact of the hammer generates waves of a broad range of frequencies. However, only the waves at a frequency similar to the fundamental frequency of the specimen will be amplified on its way to the accelerometer. Then, the signal captured with the accelerometer can be analyzed to evaluate the fundamental frequency of vibration of the specimen. Finally, this frequency can be correlated to the stiffness E0 through elasticity theory based formulations. The stiffening of kaolinite and kaolinitebentonite clay specimens stabilized with Ecolime at 6% dosage was monitored for a curing period of almost 200 days. The samples KEx refer to samples of kaolinite clay stabilized with 6% of Ecolime. The Figure 4 shows the comparison between the increase of stiffness between samples of kaolinite clay (KEx) and samples of a mixture of kaolinite clay (70%) (KEx) and montmorillonite (bentonite) clay (30%) (KBEx).

Results and Discussion

The results are illustrated in Figures 3 & 4. Figure 3 shows E0 -measurements on 12 specimens with the same dosage of 6% and natural kaolinite (K). The limited scatter of data suggests good repeatability and reliability. Moreover, the non-destructive technique produced a well-defined and continuous E0 increasing pattern. E0 was observed to increase almost linearly with time up to the 60th day of curing approximately. After that, the stiffness increasing rate significantly decreased. The evolution of E0 reflects the evolution of interparticle cementation in the clay fabric due to the addition of paper fly ash. However, the beneficial impact of the additive may also be affected by the composition and properties of the natural soil and local groundwater. In Figure 4 a difference can be seen between the kaolinite and the kaolinite-bentonite samples. The kaolinite-bentonite samples have a bigger initial E0 - modulus than the samples made from pure kaolinite. The different properties of the various families of clay minerals can be explained partly by the different levels of activity on the surface of the clay particle. Expansive clay minerals such as bentonite exhibit a high cation exchange capacity, whereas non-expansive clay minerals like kaolinite have a relative low cation exchange capacity.

Conclusion

The laboratory tests, in particular the free resonant column tests, indicate that a stabilization with paper fly ashes or with lime have similar properties. For soils with a high amount of kaolinite, paper fly ash has the same stabilization effect as lime. >For soils with a high amount of bentonite, lime is a better binder. After 28 days the effect of stabilization with paper fly ash is comparable with the stabilization with lime. Although the results are very promising, it remains important to study the chemical reactions in the sample with the X-ray diffraction method. The beneficial impact of the additive may also be affected by the composition and properties of the natural soil and local groundwater. More research is needed to confirm these results.

https://lupinepublishers.com/environmental-soil-science-journal/pdf/OAJESS.MS.ID.000150.pdf

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statzyreportsmarketresearch · 5 years ago

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Global Dairy Products Packaging Market

The report forecast global Dairy Products Packaging market to grow to reach xxx Million USD in 2019 with a CAGR of xx% during the period 2020-2025 due to coronavirus situation. The report offers detailed coverage of Dairy Products Packaging industry and main market trends with impact of coronavirus. The market research includes historical and forecast market data, demand, application details, price trends, and company shares of the leading Dairy Products Packaging by geography. The report splits the market size, by volume and value, on the basis of application type and geography. First, this report covers the present status and the future prospects of the global Dairy Products Packaging market for 2015-2024. And in this report, we analyze global market from 5 geographies: Asia-Pacific[China, Southeast Asia, India, Japan, Korea, Western Asia], Europe[Germany, UK, France, Italy, Russia, Spain, Netherlands, Turkey, Switzerland], North America[United States, Canada, Mexico], Middle East & Africa[GCC, North Africa, South Africa], South America[Brazil, Argentina, Columbia, Chile, Peru]. At the same time, we classify Dairy Products Packaging according to the type, application by geography. More importantly, the report includes major countries market based on the type and application. Finally, the report provides detailed profile and data information analysis of leading Dairy Products Packaging company. for free sample report please visit : https://www.statzyreports.com/report.php?reportname=SR150241 Key Content of Chapters as follows (Including and can be customized) : Part 1: Market Overview, Development, and Segment by Type, Application & Region Part 2: Company information, Sales, Cost, Margin etc. Part 3: Global Market by company, Type, Application & Geography Part 4: Asia-Pacific Market by Type, Application & Geography Part 5: Europe Market by Type, Application & Geography Part 6: North America Market by Type, Application & Geography Part 7: South America Market by Type, Application & Geography Part 8: Middle East & Africa Market by Type, Application & Geography Part 9: Market Features Part 10: Investment Opportunity Part 11: Conclusion Market Segment as follows: By Region Asia-Pacific[China, Southeast Asia, India, Japan, Korea, Western Asia] Europe[Germany, UK, France, Italy, Russia, Spain, Netherlands, Turkey, Switzerland] North America[United States, Canada, Mexico] Middle East & Africa[GCC, North Africa, South Africa] South America[Brazil, Argentina, Columbia, Chile, Peru] Key Companies Tetra Laval SIG Combibloc Amcor Elopak Smurfit Kappa Group DS Smith Packaging Sudpack Stora Enso Nippon Paper Group Greatview Scholle Corporation Weyerhaeuser Skylong Pulisheng Coesia IPI SERAC Ecolean Bihai International Paper Company Market by Type Paper and Paper Based Products Glass Tin Plate Aluminum Foil Timber (Wood) Plastics Laminates Market by Application Pasteurized Milk UHT Milk Yoghurt

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zeroviraluniverse-blog · 7 years ago

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Researchers observe electrons zipping around in crystals -- ScienceDaily

Visit Now - http://zeroviral.com/researchers-observe-electrons-zipping-around-in-crystals-sciencedaily/

Researchers observe electrons zipping around in crystals -- ScienceDaily

The end of the silicon age has begun. As computer chips approach the physical limits of miniaturization and power-hungry processors drive up energy costs, scientists are looking to a new crop of exotic materials that could foster a new generation of computing devices that promise to push performance to new heights while skimping on energy consumption.

Unlike current silicon-based electronics, which shed most of the energy they consume as waste heat, the future is all about low-power computing. Known as spintronics, this technology relies on a quantum physical property of electrons — up or down spin — to process and store information, rather than moving them around with electricity as conventional computing does.

On the quest to making spintronic devices a reality, scientists at the University of Arizona are studying an exotic crop of materials known as transition metal dichalcogenides, or TMDs. TMDs have exciting properties lending themselves to new ways of processing and storing information and could provide the basis of future transistors and photovoltaics — and potentially even offer an avenue toward quantum computing.

For example, current silicon-based solar cells convert realistically only about 25 percent of sunlight into electricity, so efficiency is an issue, says Calley Eads, a fifth-year doctoral student in the UA’s Department of Chemistry and Biochemistry who studies some of the properties of these new materials. “There could be a huge improvement there to harvest energy, and these materials could potentially do this,” she says.

There is a catch, however: Most TMDs show their magic only in the form of sheets that are very large, but only one to three atoms thin. Such atomic layers are challenging enough to manufacture on a laboratory scale, let alone in industrial mass production.

Many efforts are underway to design atomically thin materials for quantum communication, low-power electronics and solar cells, according to Oliver Monti, a professor in the department and Eads’ adviser. Studying a TMD consisting of alternating layers of tin and sulfur, his research team recently discovered a possible shortcut, published in the journal Nature Communications.

“We show that for some of these properties, you don’t need to go to the atomically thin sheets,” he says. “You can go to the much more readily accessible crystalline form that’s available off the shelf. Some of the properties are saved and survive.”

Understanding Electron Movement

This, of course, could dramatically simplify device design.

“These materials are so unusual that we keep discovering more and more about them, and they are revealing some incredible features that we think we can use, but how do we know for sure?” Monti says. “One way to know is by understanding how electrons move around in these materials so we can develop new ways of manipulating them — for example, with light instead of electrical current as conventional computers do.”

To do this research, the team had to overcome a hurdle that never had been cleared before: figure out a way to “watch” individual electrons as they flow through the crystals.

“We built what is essentially a clock that can time moving electrons like a stopwatch,” Monti says. “This allowed us to make the first direct observations of electrons move in crystals in real time. Until now, that had only been done indirectly, using theoretical models.”

The work is an important step toward harnessing the unusual features that make TMDs intriguing candidates for future processing technology, because that requires a better understanding of how electrons behave and move around in them.

Monti’s “stopwatch” makes it possible to track moving electrons at a resolution of a mere attosecond — a billionth of a billionth of a second. Tracking electrons inside the crystals, the team made another discovery: The charge flow depends on direction, an observation that seems to fly in the face of physics.

Collaborating with Mahesh Neupane, a computational physicist at Army Research Laboratories, and Dennis Nordlund, an X-ray spectroscopy expert at Stanford University’s SLAC National Accelerator Laboratory, Monti’s team used a tunable, high-intensity X-ray source to excite individual electrons in their test samples and elevate them to very high energy levels.

“When an electron is excited in that way, it’s the equivalent of a car that is being pushed from going 10 miles per hour to thousands of miles per hour,” Monti explains. “It wants to get rid of that enormous energy and fall back down to its original energy level. That process is extremely short, and when that happens, it gives off a specific signature that we can pick up with our instruments.”

The researchers were able to do this in a way that allowed them to distinguish whether the excited electrons stayed within the same layer of the material, or spread into adjacent layers across the crystal.

“We saw that electrons excited in this way scattered within the same layer and did so extremely fast, on the order of a few hundred attoseconds,” Monti says.

In contrast, electrons that did cross into adjacent layers took more than 10 times longer to return to their ground energy state. The difference allowed the researchers to distinguish between the two populations.

“I was very excited to find that directional mechanism of charge distribution occurring within a layer, as opposed to across layers,” says Eads, the paper’s lead author. “That had never been observed before.”

Closer to Mass Manufacturing

The X-ray “clock” used to track electrons is not part of the envisioned applications but a means to study the behavior of electrons inside them, Monti explains, a necessary first step in getting closer toward technology with the desired properties that could be mass-manufactured.

“One example of the unusual behavior we see in these materials is that an electron going to the right is not the same as an electron going to the left,” he says. “That shouldn’t happen — according to physics of standard materials, going to the left or the right is the exact same thing. However, for these materials that is not true.”

This directionality is an example of what makes TMDs intriguing to scientists, because it could be used to encode information.

“Moving to the right could be encoded as ‘one’ and going to the left as ‘zero,'” Monti says. “So if I can generate electrons that neatly go to the right, I’ve written a bunch of ones, and if I can generate electrons that neatly go to the left, I have generated a bunch of zeroes.”

Instead of applying electrical current, engineers could manipulate electrons in this way using light such as a laser, to optically write, read and process information. And perhaps someday it may even become possible to optically entangle information, clearing the way to quantum computing.

“Every year, more and more discoveries are occurring in these materials,” Eads says. “They are exploding in terms of what kinds of electronic properties you can observe in them. There is a whole spectrum of ways in which they can function, from superconducting, semiconducting to insulating, and possibly more.”

The research described here is just one way of probing the unexpected, exciting properties of layered TMD crystals, according to Monti.

“If you did this experiment in silicon, you wouldn’t see any of this,” he says. “Silicon will always behave like a three-dimensional crystal, no matter what you do. It’s all about the layering.”

#Crystals #electrons #observe #researchers #ScienceDaily #zipping #Facts

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nofomoartworld · 8 years ago

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How Real Estate Ate Nashville’s Smallest Art Gallery | #50States ofArt

The story is familiar to art scenesters from Chelsea to Honolulu's Kaka'ako arts district. For four glorious years, Nashville was home to a miniature experiment in guerrilla curation, which came to an abrupt end at the hands of the real estate market.

Nashville's Smallest Art Gallery (NSAG) proclaimed itself as, "the smallest functioning art gallery in Nashville, and dare we say, the world!" What it lacked in size, it made up for in freedom and ambition. Today, the gallery has been replaced by condos and a canine-themed bar where you can eat nachos out of a dog bowl.

Screencap via Google Maps

Rewind to the Ides of March, 2008. Hillary Clinton's first presidential bid is in full swing. Major print publications are (barely) realizing the internet is changing their business. The New York Times has just begun profiling Chelsea gallerinas. A few weeks prior, NSAG was nothing but a graffiti-ravaged display case, 27" wide and 37" tall. Thanks to area web designer Daniel Box, it's now a self-sustained gallery, complete with lights and a little solar panel to illuminate it by night. It clings to the wall of Peabody Shoe Repair in Nashville's walkable Hillsboro Village, a family-owned business that had operated in Nashville for 50 years.

Each month, Box curated a themed show. They had titles like Summer Book Club, Diorama Drama, and Matchbook Paintings, and every set was unified by thematic and physical limitations. Artists were Box's friends, or cold-called via the internet. Those who were worked with him would make original art proportional to the gallery. That was part of the fun: the challenge of making work that fit. Box says even small photographs didn't fit in the space—they had to be tiny. He featured many Nashville artists, but received submissions from as far away as The Netherlands. He got packages delivered from the artists at his place of business, arranged the show on poster board in his spare time, then changed out the work every four to six weeks.

Box describes the first show as as an act of opportunity. "I walked past the dilapidated, graffiti-covered box every day," he tells Creators. "Every time I thought, 'We should do something cool with this.'" One spring day he spontaneously started renovating. "I knew if we could kick it off, it would work," he says. "My girlfriend thought I was crazy. It was a leap of faith, that people would actually do it."

He enlisted his friends San Francisco-based street artist Ferris Plock, GRAMMY-nominated designer Matthew Curry, and Nashville artist Rachel Briggs to break the space in. In keeping with the Ides of March, the show's theme was a sense of impending doom. The artists rose to the occasion, offering portraits of kings, grotesque body horror, and images of crying girls.

Rachel Briggs, Stangle, Drown, Startle

During its short life span, NSAG was host to CGI killer robots, an architectural series based on the history of swimming pool design, and the matchbooks paintings of Korean artist Jee Hoon Stark, showcasing techniques learned from a Japanese miniature artisan. NSAG gave artists a space to try something new. The small scale and devoted community made it a fixture for curious Nashvillians, and without the pressure of monthly rent, Box could afford to take a risk with the artists he showed. "People liked it because it was a delightful surprise they weren't expecting as they were walking," Box says.

For born and raised Nashville artist Shana Kohnstamm, the gallery played a role in her development as an artist. "When Daniel put out the call-for-art, I was still transitioning from painting to felt work," she says. Her show, Surface Treat, was among the first public showings of a process she had been developing for two years. "I was eager to try out some small framed works and play around with what were basically sample pieces for different techniques," she says.

Images courtesy Shana Kohnstamm

A curator for Mobile, Alabama's Museum of Art viewed Surface Treat online and asked Kohnstamm to be a part of an exhibit called Size Matters in 2015. It was a big break for Kohnstamm. It was also NSAG's last show.

"It ended in typical fashion. It was torn town for generic condos," Box laments. "I was incredibly bummed." In 2012, he got a letter from The Hill Company, one of Nashville's largest landowners and the company managing his building. "The joke is that Hill would drive around with his accountant saying, 'I want that building,' and the accountant would have to say, 'Sir, you already own that one!'" Box says. The letted informed them that the building hosting both his office and Peabody Shoe Repair was to be torn down and rent hiked to a price far out of the Peabodys' price range.

"To be fair, the building was in disrepair," Box admits. "But it was fixable. The owners had no interest in fixing it. It was much easier for them to knock it down and put something in that would make more money."

Jee Hoon Stark, Matchook Paintings

While Box hasn't reopened the gallery, he still loves NSAG. "I kept doing it until they kicked us out. December 6, 2012 was the last show," he says. After the building was destroyed, he moved his office and moved on with his life. He now has four kids and spends his creative energy designing graphics and products.

Kohnstamm and Box exchanges ideas about restarting the gallery in 2015. "When I asked him about reviving the gallery, he said that he didn't have the time, but if I felt like starting it up again in a different incarnation, that was up to me," Kohnstamm says. She hasn't yet acted on the invitation.

These days, Box encourages others to maintain NSAG, and even offers me some advice about managing the project. The location isn't right for him—in an alternate universe, though, he might still be curating tiny art. Says Box, "I would definitely still be doing it if the building hadn't been knocked down."

Ferris Plock, Beware the Eades of March

Check out more work from Nashville's Smallest Art Gallery here.

"What Is This, A Gallery For Ants?" Yes.

Honolulu's 'Graffitification' Problem Can't Stop the POW! WOW! Art Festival

We Talked to the Artist Creating a Miniature City Out of Paper

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smitadeshmukh123 · 8 years ago

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Computer Aided Detection Market: Business Challenges, Emerging Technologies & Competitive Landscape

Transparency Market Research has published a new market report titled, “Computer Aided Detection Market: (By Imaging Modality: Mammography, Magnetic Resonance Imaging, Ultrasound Imaging, Tomosynthesis, Computed Tomography, and Others; By Application: Breast Cancer, Lung Cancer, Colorectal Cancer, Prostate Cancer, Liver Cancer, Bone Cancer, and Cardiovascular and Neurological Indications): Global Industry Analysis, Size, Share, Growth, Trends, and Forecast, 2016–2024.” According to the report, the global computer aided detection market was valued at US$ 437.0 Mn in 2015 and is projected to expand at a CAGR of 9.8% from 2016 to 2024 to reach US$ 1,015.60 Mn in 2024.

Computer aided detection is a technique that helps radiologists to interpret radiology images accurately and identify potential findings in order to avoid incorrect interpretations. There has been significant advancement in medical imaging technology since the late 1980s. The calculating ability of computers and quality of digital medical imaging have improved. This has led to widespread usage of computer aided detection systems. The global computer aided detection market is concentrated in the developed regions of the world. Additionally, rising patient awareness levels because of awareness programs organized by breast cancer charities is likely to drive the market, as these programs encourage women to undertake regular medical examinations.

Read Full Report: http://www.transparencymarketresearch.com/computer-aided-detection.html

Geographically, the computer aided detection market has been segmented into five major regions: North America, Europe, Asia Pacific, Latin America, and Middle East & Africa. North America held the largest share of 62.8% of the global computer aided detection market in terms of revenue in 2015, followed by Europe. Dominance of these two regions is due to rise in incidence and prevalence of breast cancer, growing awareness about early breast cancer screening, increase in the geriatric population, and rapid advancement in technologies. The U.S. held a major share of the market in North America as well as globally. According to World Cancer Research Fund (WCRF) statistics, North America had the highest number of new breast cancer cases in 2012 (around 226,125 in the U.S. alone).

The region is a major innovation hub, where leading companies in the segment conduct research and development.

Europe accounted for the second largest share of the global computer aided detection market in 2015 due steady rise in incidence of cancer and coronary artery diseases and introduction of a large number of white papers and publications validating the efficiency of CAD as a supportive diagnostic tool. According to the European Journal of Cancer published in 2013, breast cancer was the leading type of cancer in women in Europe. A report published by the European Union stated that breast, prostate, and colon cancers, and coronary artery diseases act as the largest cause of death in Europe. Countries such as Germany, France, Spain, and Italy have the highest growth rate of various types of cancers. According to the WHO, 450,000 new cases of colorectal cancer were reported in the WHO European Region, and 232,000 deaths in 2008. About 65% of all the new cases occur in high-income countries. Growing health care awareness among the population, need for digitization in the health care sector, and accuracy in detecting cancerous lesions are likely to drive demand for CAD in Europe.

Asia Pacific accounts for over 60% of the world’s population, which translates to a significant patient pool and large number of imaging procedures. According to the Asian Pacific Journal of Cancer Prevention (2010), there were more than 3 million new cancer cases and over 2 million cancer deaths in Asia. Projections suggest the number of new cancer cases in Asia will increase to 7.1 million by 2020 if existing prevention and management strategies remain unchanged. However, most of the countries in the region are positioning themselves as medical tourism destinations for developed nations. This will encourage health care providers to adopt advanced CAD in imaging technologies.

View exclusive Global strategic Business report : http://www.transparencymarketresearch.com/sample/sample.php?flag=S&rep_id=1442

The computer aided detection market in Latin America, Africa, and the Middle East is in the development phase. According to the Cancer Atlas, about 1.1 million new cancer cases and 600,000 cancer deaths are estimated to occur in Latin America and the Caribbean each year. Prostate cancer is the leading cause of cancer death among males, with about 51,000 deaths annually, followed by lung cancer and stomach cancer. Breast cancer is the leading cause of death among females, with about 43,000 deaths annually, followed by cervical and lung cancer. Furthermore, the burden of cancer is increasing in Africa because of the rapidly aging and growing population, and high prevalence of risk factors associated with economic transition, including smoking, obesity, physical inactivity, and reproductive behaviors. Latin America is one of the most promising regions for the growth of the medical imaging market, with Mexico and Brazil being the largest markets. Growing awareness about diagnostic procedures, low cost of imaging procedures, and rising investment in health care facilities and infrastructure are likely to drive the computer aided detection market in Brazil during the forecast period.

Hologic Inc., GE Healthcare, Invivo Corporation, Siemens Healthcare, and Agfa-Gevaert N.V. are the major players operating in the global computer aided detection market. Hologic Inc. was identified as the leading player in the global computer aided detection market in 2014, accounting for a share of over 35% in terms of revenue, followed by GE Healthcare and Invivo Corporation.

#Computer Aided Detection Market

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