It was a monumental accomplishment that galvanized the nation’s fascination with science and technology and inspired the creation of an educational video series known as the Science Screen Report.
Developed to enhance curriculums throughout our nation’s schools by stimulating students curiosity in science, it’s no coincidence that as it approaches its 40th anniversary, the Science Screen Report is more relevant than ever.

“Students are far more immersed in their studies when they can experience the world beyond the written pages of their textbooks and see it live, in full color and in three dimensions,” says Cleveland Middle School Librarian, Grace M. Dyrek.

Apparently many educators across the nation agree. When the Science Screen Report made its debut in 1970, less than 100 schools nationally were utilizing its services. Today nearly four decades later, more than 10,000 school districts use the series as an essential tool to help promote science as an invaluable subject.

“We cannot do enough to engage students in science. The sciences have never been more important to society than they are now,” says Scott Forman, President of Allegro Productions whose company produces the series from Palm Beach County, Florida. That advocacy is also shared by President Obama who stated, “Today more than ever before, science holds the key to our survival as a planet and our prosperity as a nation.” These are high stakes that will require a much deeper commitment to science than previously shown by U.S. schools, students and parents.

According to the Washington Post, science scores from the 2006 Program for International Student Assessment – a test given every three years – showed that U.S. 15 year-olds trailed their peers from many industrialized countries. It’s a trend that’s mirrored in American middle schools as well.

To help close and overcome that gap, Science Screen Report and its companion series, Science Screen Report For Kids, is designed to get students engrossed in science as early as possible – science is not a subject to simply just pass. “We’re trying to get kids interested in careers in science; show them it can be challenging, rewarding and full of opportunity,” adds Forman whose company produces eight programs per school year for each series.

Roughly 15 minutes in length and produced to directly address National Science Standards and Science Literacy Benchmarks, both series cover a variety of topics ranging from chemistry to the environment to physics, biology, medicine, ecology, engineering, space science, energy and oceanography.

Visually captivating to capture the attention and imagination of today’s technologically advanced kids, each Science Screen Report is accompanied by a thoroughly researched teacher guide. Prepared by a committee of educators, the guides provide background information, suggestions for critical thought, a glossary, career possibilities, resource and reference material, and tend to provoke lively classrooms discussions regarding the featured subjects.

Having worked for decades with the National Science Foundation’s Presidential Awards for Excellence in Mathematics and Science Teaching, the Science Screen Report continues to receive accolades. Series materials have also been used in the Smithsonian Institute’s Teacher Resource Center, and are listed in the resource guides of the Eisenhower National Clearinghouse, the U.S. Department of Energy, the U.S. Department of Education, and many other state and local agencies.

Although delivered to schools using the latest technology such as video streaming, supporters of the Science Screen Report face an age-old problem – funding. The series which augments an existing school’s curriculum is often subject to budget cuts. Currently it’s sponsored by hundreds of companies that enable thousands of school districts around the country to receive the program for free. Program sponsors receive a PBS type opening and closing message that appears at the beginning and end of every program that is viewed in the classroom.

Yet in this turbulent economy where cutbacks are the norm, Forman is optimistic that corporations will continue to see the value that Science Screen Report brings to the classroom. It’s an ideal situation; schools receive the award winning content at no cost, and corporations have an appropriate method for reaching their future employees and customers. It’s a logical way for these companies to invest in their own communities.

A small investment that Forman hopes will continue to provide American students and teachers with the tools they need to regain their place at the forefront of science and technology, and remain there for generations to come.

Steve Waxman

Article Source: http://EzineArticles.com/?expert=Scott_Forman

Today, classroom teachers may lack personal experience with technology and present an additional challenge. In order to incorporate technology-based activities and projects into their curriculum, those teachers first must find the time to learn to use the tools and understand the terminology necessary for participation in projects or activities. They must have the ability to employ technology to improve student learning as well as to further personal professional development.

Instructional technology empowers students by improving skills and concepts through multiple representations and enhanced visualization. Its benefits include increased accuracy and speed in data collection and graphing, real-time visualization, the ability to collect and analyze large volumes of data and collaboration of data collection and interpretation, and more varied presentation of results. Technology also engages students in higher-order thinking, builds strong problem-solving skills, and develops deep understanding of concepts and procedures when used appropriately.

Technology should play a critical role in academic content standards and their successful implementation. Expectations reflecting the appropriate use of technology should be woven into the standards, benchmarks and grade-level indicators. For example, the standards should include expectations for students to compute fluently using paper and pencil, technology-supported and mental methods and to use graphing calculators or computers to graph and analyze mathematical relationships. These expectations should be intended to support a curriculum rich in the use of technology rather than limit the use of technology to specific skills or grade levels. Technology makes subjects accessible to all students, including those with special needs. Options for assisting students to maximize their strengths and progress in a standards-based curriculum are expanded through the use of technology-based support and interventions. For example, specialized technologies enhance opportunities for students with physical challenges to develop and demonstrate mathematics concepts and skills. Technology influences how we work, how we play and how we live our lives. The influence technology in the classroom should have on math and science teachers’ efforts to provide every student with “the opportunity and resources to develop the language skills they need to pursue life’s goals and to participate fully as informed, productive members of society,” cannot be overestimated.

Technology provides teachers with the instructional technology tools they need to operate more efficiently and to be more responsive to the individual needs of their students. Selecting appropriate technology tools give teachers an opportunity to build students’ conceptual knowledge and connect their learning to problem found in the world. The technology tools such as Inspiration® technology, Starry Night, A WebQuest and Portaportal allow students to employ a variety of strategies such as inquiry, problem-solving, creative thinking, visual imagery, critical thinking, and hands-on activity.

Benefits of the use of these technology tools include increased accuracy and speed in data collection and graphing, real-time visualization, interactive modeling of invisible science processes and structures, the ability to collect and analyze large volumes of data, collaboration for data collection and interpretation, and more varied presentations of results.

Technology integration strategies for content instructions. Beginning in kindergarten and extending through grade 12, various technologies can be made a part of everyday teaching and learning, where, for example, the use of meter sticks, hand lenses, temperature probes and computers becomes a seamless part of what teachers and students are learning and doing. Contents teachers should use technology in ways that enable students to conduct inquiries and engage in collaborative activities. In traditional or teacher-centered approaches, computer technology is used more for drill, practice and mastery of basic skills.

The instructional strategies employed in such classrooms are teacher centered because of the way they supplement teacher-controlled activities and because the software used to provide the drill and practice is teacher selected and teacher assigned. The relevancy of technology in the lives of young learners and the capacity of technology to enhance teachers’ efficiency are helping to raise students’ achievement in new and exciting ways.

As students move through grade levels, they can engage in increasingly sophisticated hands-on, inquiry-based, personally relevant activities where they investigate, research, measure, compile and analyze information to reach conclusions, solve problems, make predictions and/or seek alternatives. They can explain how science often advances with the introduction of new technologies and how solving technological problems often results in new scientific knowledge. They should describe how new technologies often extend the current levels of scientific understanding and introduce new areas of research. They should explain why basic concepts and principles of science and technology should be a part of active debate about the economics, policies, politics and ethics of various science-related and technology-related challenges.

Students need grade-level appropriate classroom experiences, enabling them to learn and to be able to do science in an active, inquiry-based fashion where technological tools, resources, methods and processes are readily available and extensively used. As students integrate technology into learning about and doing science, emphasis should be placed on how to think through problems and projects, not just what to think.

Technological tools and resources may range from hand lenses and pendulums, to electronic balances and up-to-date online computers (with software), to methods and processes for planning and doing a project. Students can learn by observing, designing, communicating, calculating, researching, building, testing, assessing risks and benefits, and modifying structures, devices and processes – while applying their developing knowledge of science and technology.
Most students in the schools, at all age levels, might have some expertise in the use of technology, however K-12 they should recognize that science and technology are interconnected and that using technology involves assessment of the benefits, risks and costs. Students should build scientific and technological knowledge, as well as the skill required to design and construct devices. In addition, they should develop the processes to solve problems and understand that problems may be solved in several ways.

Rapid developments in the design and uses of technology, particularly in electronic tools, will change how students learn. For example, graphing calculators and computer-based tools provide powerful mechanisms for communicating, applying, and learning mathematics in the workplace, in everyday tasks, and in school mathematics. Technology, such as calculators and computers, help students learn mathematics and support effective mathematics teaching. Rather than replacing the learning of basic concepts and skills, technology can connect skills and procedures to deeper mathematical understanding. For example, geometry software allows experimentation with families of geometric objects, and graphing utilities facilitate learning about the characteristics of classes of functions.

Learning and applying mathematics requires students to become adept in using a variety of techniques and tools for computing, measuring, analyzing data and solving problems. Computers, calculators, physical models, and measuring devices are examples of the wide variety of technologies, or tools, used to teach, learn, and do mathematics. These tools complement, rather than replace, more traditional ways of doing mathematics, such as using symbols and hand-drawn diagrams.

Technology, used appropriately, helps students learn mathematics. Electronic tools, such as spreadsheets and dynamic geometry software, extend the range of problems and develop understanding of key mathematical relationships. A strong foundation in number and operation concepts and skills is required to use calculators effectively as a tool for solving problems involving computations. Appropriate uses of those and other technologies in the mathematics classroom enhance learning, support effective instruction, and impact the levels of emphasis and ways certain mathematics concepts and skills are learned. For instance, graphing calculators allow students to quickly and easily produce multiple graphs for a set of data, determine appropriate ways to display and interpret the data, and test conjectures about the impact of changes in the data.

Technology is a tool for learning and doing mathematics rather than an end in itself. As with any instructional tool or aid, it is only effective when used well. Teachers must make critical decisions about when and how to use technology to focus instruction on learning mathematics.

Article Source: http://EzineArticles.com/?expert=Hassan_Hussein

Within the past year a new form of stem cell research has begun. Stem cell research has always been riddled with controversy because of the need for human embryos. A new technique is being perfected that allows scientists to take the skin cells off of a patient and essentially transform them into stem cells (this has currently only been done on animals). With a patient’s own stem cells now (from the patients skin, no embryos needed) available they can then convert them into any cell in the body and replicate them. This is huge, and advancements can come quickly now because human embryos aren’t needed and politics won’t get in the way.

Recently The Large Hadron Collider project announced it’s soon-to-be completion. They installed the last major part in this huge under ground particle accelerator. Scientists are hoping by bashing elements and atoms at near light speeds they can unravel many of the mysteries in science and quantum mechanics. The Large Hadron Collider will possibly tell us if there are other dimensions, and possibly make Michio Kaku happy by also letting us know if strings do exist (sub atomic scale) and if String Theory is fact.

Lastly, we are also entering a new telescope type era. The Large Binocular Telescope has officially announced its competition. It has two 8.4 meter mirrors to view the night sky like never before. It will have ten times the resolution of the Hubble Telescope. Coming up we have the Kepler Mission which will look at 100,000 stars and look for earth-like planets in space. We also have the Giant Magellan Telescope, and The Thirty Meter Telescope (Major Funding By Gordon Moore) slated form completion by 2015.

Within the next 10 years these telescopes will be able to confirm if there are truly rocky earth-like worlds out there with the ingredients for life. Our new science is telling us that at least a quarter of all stars have planets orbiting them. Considering that there are about 400 billion stars in our galaxy, and at least 100 billion galaxies, the odds are great for earth-like planets to be around. We already have confirmed multiple rocky slightly larger than earth planets in the habitable zone. With our new technology and telescopes we can see just how many there are, and exactly what their atmospheres are made out of.

Going a step further. It’s possible we will make one of the biggest discoveries of all time within the next 20 years if we continue at the rate of technological advancement that we are going at. We may possibly know the answer to if there is other life out there, not from earth. I personally believe it could simply be there is or isn’t, but the scientific community is saying within 15-20 years we may finally have an answer.

Concluding. We are making huge advancements in medicine, technology, space, and other areas. It’s interesting to see how far we have come as a civilization. Hopefully along with our advancements we still realize how important the simple things are and keep our earth healthy and clean. It is an exciting future, enjoy the ride.

Mike Monahan is the Editor In Chief of Science-News.org

The headquarters for Science News

Article Source: http://EzineArticles.com/?expert=Michael_Monahan

Computers are now become the most valuable machine of the world. Today, almost more than 70% work is rely on the computers. It is also playing role in the world economy. There are many business are running on the basis of just a computer software. As online learning is depend on the internet .So, if person takes course related to IT, it becomes easy for the person to understand it. They don’t want to give much time to their study and can easily clear the exams There are actually many different specialties available when you get an online based degree in computer technologies. You can study computer science, software engineering, computer repair and maintenance, database programming, and a wide variety of other specialties within the realm of a degree in computer technologies at the internet. While learning they can easily apply their study in their current work. If a person is working in a IT company and wants its promotion. They can take a online degree course and can increase its impression on the boss.

A computer science student doesn’t need to get training of basics of internet such as creating new account on the websites, visiting websites, checking the e-mail, sending e-mail, downloading documents or course material from e-mails which will be provided by institute at regular intervals, uploading documents and sending it by attaching files, searching any topic by using search engines, about popular websites providing material for the education, chatting software’s for the live discussions, downloading software’s etc. They should choose the better course which provide them some knowledge of new technologies of programming and platforms such as .Net , Visual basic etc. Almost every type of online course is available for the computer students because they are well acquainted about the internet.

In the IT sector, the technology is increasing very fast. As new soft ware’s releases in the market new virus come out to break the software and hardware also. So, the companies need competent experts in computer technologies to fix computer problems and help employees make transitions. Companies are also hiring employers online and giving them work on the contract basis. So, the online degrees can work to show the profile in the online jobs.

Keith Londrie II is the Webmaster of http://best-online-degree-schools.com/ A website that specializes in providing information on Online Degrees that you can research on the internet. Please Visit http://best-online-degree-schools.com/ now!

Article Source: http://EzineArticles.com/?expert=Keith_Londrie