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

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1. North West universities play a key role in Science and Technology, and have a combined turnover of over £1.2 billion, almost 1% of the region’s total economy. Leading companies, including those in the Aerospace Business, automotive supply and manufacturing companies, nuclear energy and medical research are closely linked to North West universities. More than 50,000 North West students graduate every year, including 25,000 with life science degrees. Over 69,000 science students are trained every year.

2. The Aerospace Business in the North West has a turnover of £6 billion, and is responsible for producing military and commercial aircraft and components which are used both in the UK and exported worldwide. Extensive R&D programmes ensure that the latest technologies are available to create the most advanced planes in the world. Countries all over the world rely on the North West Aerospace Business for their military and commercial aircraft requirements

3. The Chemistry Industry plays a vital role in the North West, and sales of chemicals contribute over £10 billion to the economy, equating to approximately 20% of the UK chemistry industry. Approximately 220,000 people are employed in this sector. In 2005, the Department of Trade and Industry announced that as part of the Technology Programme, one of the 19 new Knowledge Transfer Networks (KTNs) would be in Chemistry in the North West. KTNs help to share knowledge and research between businesses, academic institutions such as universities, and trade associations.

4. The North West and Cumbria in particular, is widely acknowledged as the centre of the UK Nuclear Energy industry, and is home to the Nuclear Decommissioning Authority. The research and development work done in this region has led the Government to conclude that utilising nuclear energy is part of a viable solution to meeting the energy needs of the UK.

5. There are over 50 research institutes, many of them multi-institutional, as well as traditional R&D departments. The North West is home to the Research and Development departments of several of the worlds leading companies, and business R&D investment in this region is greater than in any other part of the world except Asia. Recent reports show that 4 of the top 10 companies by R&D spending have significant facilities in the North West. Pharmaceutical development, including the largest cancer drug research centre in the UK, Aerospace Businesses, manufacturers of consumer products, as well as the Chemistry Industry and Nuclear Energy are well represented in the North West.

6. The North West’s seven science parks are home to many knowledge-based companies in diverse industries ranging from providing education to Nuclear Energy and decommissioning. Strong links to universities as well as research institutes and centres of knowledge, in the UK and abroad, help to ensure that Science and Technology in the North West is second to none.

7. Dedicated Strategic Science and Technology sites have been set up throughout the North West, and Manchester is aiming to become one of the UK’s first six Science Cities by 2015.

Manchester Science Park is internationally recognised as a centre of excellence, and is one of the most successful of its kind. Tenants include specialists in healthcare, telecoms, and digital media.

The Daresbury Science and Innovation Campus, near Warrington in Cheshire, is home to leading companies in diverse industries ranging from healthcare research to business support services. The nearby Daresbury Laboratory is one of the best-resourced science facilities in the UK.

Liverpool Science Park, right in the centre of Liverpool, is the fastest growing science park in the UK, and contains computer games, website design and software companies as well as solicitors specialising in intellectual property and technology law. Speke, also in Liverpool, is home to the National Biomanufacturing Centre, which is set to become the leading biopaharmaceutical design centre in Europe, and helps to create and develop new medicines

West Cumbria Science Park, near Whitehaven, has over 60 companies on site, ranging from ecology to engineering, many of which are involved in the Nuclear Energy Industry.

A Science Park in Lancaster is scheduled for development this year, and will be located close to the top-ten ranked university. This exciting new project will combine the renowned academic knowledge and resources of the University with local businesses know-how and the Lancaster Environment Centre.

8. With Manchester recently voted the most creative city in the UK, and Liverpool’s reputation as one of the leading cities for computer game design, the North West is at the forefront of new technologies as well as traditional Science and Technology. The use of ICT in education, website design and internet technologies, TV and film production, as well as other media industries, is all flourishing in the region, thanks to Science and Technology.

9. As well as looking to the future, the region’s scientific history is preserved through museums such as the World Museum in Liverpool, Quarry Bank Mill in Styal, Cheshire, and Wigan Pier. Visual displays as well as hands-on activities, demonstrations and different media show how Science and Technology has changed our lives, from mechanising everyday tasks to revolutionising manufacturing methods.

10. As well as the outstanding Science and Technology facilities, the North West is a popular business location thanks to its fantastic infrastructure. Within reach of 3 international airports, and a great motorway system, the North West is closer than you may think. In addition, the North West has many Areas of Natural Outstanding Beauty and the standard of living is high.

There has never been a better time to see how North West Science and Technology can help you.

To find out more about North West Science and Technology, and Research Institues, please visit www.NorthWestScience.com

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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.

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Inquiry Based Teaching and Learning

If you are looking for K-12 science lesson plans, web resources, and references to support inquiry based teaching and learning, you have probably found this search difficult. Like other web resources it takes time to surf the web and find them. What is needed is a directory of science inquiry based resources categorized into topics that support K-12 science teaching and learning. What is needed is for someone to do this for you.

Directory resources that are most valuable to K-12 science educators include lesson plans, assessment guides, curriculum guides, standards guidelines, search engines for science, and more. Also there is a need for online resources that support all science content areas.

Teaching Science using Technology

There are many types of technology strategies for teaching K-12 science. These include the use of web resources, online simulators, WebQuests, real-time data bases, online interactive websites, and many more options. A website that provides a directory of a wide variety of web based resources is very helpful to K-12 educators.

This type of website would be used to support their teaching strategies. Actively engaging students in learning, instead of being passive learners. You can take students on virtual field trips to places all over the world: zoos, volcanos in other countries, and more.

Additional Resources

Other K-12 online science education resources needed by teachers and parents include access to journals, current science news topics, and online science teaching research books. One particular resource that is needed is a guide for recommended reading books to support science at all grade levels. Reading is stressed even more today to meet state and national education requirements and an online resource would help educators save time trying to find books that meet content standards.

Because of the emphasis on standards and testing today, teachers do want to go to a website that waste their time. All resources need to be pre-screened to ensure that they meet national science standards’ guidelines for teaching science using inquiry based practices. Also, that the technology based resources on the website meets national technology and science standards.

A directory that has updated links is especially important to provide resources. Teachers and parents are tired of going to science directories that are full of dead links. It wastes their time and frustration sets in, because more valuable time has been wasted.

What is needed is an online science education resource website that is specifically designed for K-12 science educators and home schooling parents.

Science Inquiry and Technology website: http://www.science-inquiry.org

Technology and Writing Blog: http://drwetzel.wordpress.com

David R. Wetzel, Ph.D. – Currently a FreeLance Writer, Retired Science Education University Professor and Public School Science Teacher.

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In India, there are countless number of leading universities, such as IITs, Private Institutes, State Level Engineering Colleges and Regional Engineering Colleges that are engaged in making the career of future computer and IT engineers.

The demand of Indian Computer Science and IT Professionals is increasing day by day on a worldwide level. That’s why in a current scenario becoming a computer science and IT professional is a dream of many a young youth of India.

There is a broad spectrum of computer training comes under the study of computer science and information technology. When it comes to finding computer science schools, anyone has to go through a deep research that sometimes open different choices to the users. Computer courses can offer high-tech training for professional certification and several levels of college degrees in computer technology and computer science. It is completely up to you whatever you decide.

The main purpose of computers and IT colleges and institutes in India is to design programmes in a way that can prepare future network engineers, programmers, computer technicians and others for professional employment in the computer sciences field. A huge range of computer technology is covered under the study of computer sciences, so anyone should think think about his/her ultimate goal before enrolling himself/herself in any computer science courses.

If you are one of them who are looking for professional certification in one area of computers and information technology, you can find a number of colleges and institutes in India that provide computers and IT education. Among them, there are some institutes that demand for previous experience or training in computers and information technology. There are also some colleges that allow you to start from scratch.

If you are one of them who always seek for getting an advanced position in computer networking or information technology, you will have to find complete information about all college degrees in computer science. Some highly respected degrees of this field are Master of Science Degrees (MS),Bachelor of Science Degrees (BS) and Associate of Science Degrees (AS). The terminal degree of this filed is Doctorate of Science in Computer Science offered by renowned and widely-known universities in India. The higher degree you have, the more salary will come into your hand.

You can also include some business courses along with your computer and information technology education, if you are thinking to pursue your career in management, office administration or business technology.

There are a huge number of widely-renowned computers and IT colleges and institutes in India offering excellent computer science and information technology education required to be a computer and IT professional. You can get this education by enrolling yourself in any of the top colleges and institutes. These colleges and institutes help you to earn a diploma or a degree course according to you potential and skills by practicing them as professional.

Some colleges that offer excellent and specialized computer science and information technology courses and fellow programs are Amrita Institute of Computer Technology, Bankatlal Badruka College for Information Technology, Academy of Computer Technology, B.I.I.T. Heights Institute of Information and Technology, Baba Saheb Ambedkar Technical Educational Society, Alakananda Computer Training Centre, Department of Computer Science, Godavari Institute of Information Technology, etc. Some other institutes are A.J. College of Science and Technology, Axis College of Economics and Commerce, Academy of Computer Studies, Allahabad Agricultural Institute Deemed University, Banaras Hindu University, etc.

Shefali Roy is a webmaster of latestt.com. Here u can get the information related to career options and computers and IT colleges in India. For more details visit latestt.com

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Fortunately for students, many of these initiatives include financial incentives to help them complete campus-based or online degree programs in these fields. Texas Governor Rick Perry recently announced his support of a $100 million program to help students pursuing STEM-related degrees or certificates.

The STEM Challenge Scholarship program is intended to foster regional partnerships between colleges, school districts and employers in order to create and distribute financial aid awards in order to attract students to degree programs and careers in related industries.

Governor Perry said the scholarship program is intended to “encourage higher education institutions to design STEM programs that meet local employer needs, while providing Texas students the opportunity to pursue the education they need as they fulfill their potential.” He also proposed a plan to expand the state’s UTeach program, which provides tuition assistance to college students pursuing teaching careers in math and science.

Currently, the state provides $80 million to universities to help them increase their graduation rates, particularly in STEM fields. Prospective employers in these industries are launching similar initiatives to entire students to pursue STEM-related careers. For example, Tech Collective, a Rhode Island-based information technology (IT) and bioscience association, recently partnered with three other organizations to launch scholarship programs for students working toward degrees in IT-related subjects.

A total of five scholarships worth $7,000 are available through three different awards. The Lighthouse Computer Services/Tech Collective scholarship will provide two $1,000 awards to high school or college students who are working pursuing careers in the IT industry and have some affiliation with the U.S. military.

The company will partner with Fibertech Networks to award a $3,000 scholarship to a female high school student planning to enroll in a college degree program in information systems, computer systems or another IT-related field. Female and minority students who demonstrate commitment, dedication, academic excellence, leadership and determination are eligible to apply for the $1,000 Doug Schwinn/Tech Collective Scholarship.

Students who wish to take advantage of the growing opportunities in STEM-related industries may consider applying for similar awards that can help them finance higher education.

Now there are student loans and grants
available for degree programs online.

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Though some of the basic laboratory modus operandi includes dedicated work stations and software to program instrument, of recent an absolute functional robotic version that minimizes the manual work, is also being found invariably. This means that the robotic technology can reduce the time involved in the processes like pipetting, moving plates around, and various types of assay. The typical workday of individual scientists have been transformed due to the creativity, imagination and hard labor that goes in the research in the field of science and technology. Lab automation and Robotics has helped the scientist in saving time as now they can set up, run, and analyze the results of experiments in a fraction of the time they needed in the past. Thus, now the scientists have more time to think creatively about the implications of their experimentation and to design effective follow-up projects or develop alternative approaches to their work.

Not only this, the scope of application of these robotics and lab automation is very wide. Besides being used in the multiple pipettes for a thorough operation, various pharmaceutical company too want to make all their phases of research, automated. This newest trend in the laboratory market instruments assists the scientists to automate many basic laboratory procedures with minimal effort. Some of the main areas where the implementation of this technology is needed at large are laboratories that work with DNA sequencing, Genomics and micro satellite analysis.

Though this is fast becoming one of the most important requirement in any modern laboratory, the selection of them is a tedious and critical process. Any laboratory that aims to install this system must decide on which semi-automated or fully automated system to purchase. Other crucial factors to be kept in the mind are the need for this automation, the assay format used by the laboratory, technical support required by the lab automation and robotics and the potential disadvantages that can crop up after the installation of this system. Besides the consumer, the manufacturers of these laboratory and scientific instruments too need to take care. It is important for them to emphasize on the format of the product as their shapes, sizes and functions can vary significantly.

These lab automation and robotics are fast becoming a rage in the laboratory and scientific products industry and the manufacturers and suppliers of these lab equipments are working to broaden the range of assays that can be done on a system.

Having an experience of 9 years in the engineering and scientific industry, I have been working in this industry as an analyst and researcher. Besides, various other undertaking in the scientific and engineering markets to my credit, I have been associated with some of the most renowned marts of scientific and engineering products.
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Let’s look at some of the reasons why girls come to the STEM classroom with less of the core skills needed for success in this subject area. Overall, girls and boys play with different kinds of games in early childhood that provide different types of learning experiences. Most girls play games that emphasize relationships (i.e., playing house, playing with dolls) or creativity (i.e., drawing, painting). In contrast, boys play computer and video games or games that emphasize building (i.e., LEGO®), both of which develop problem-solving, spatial-relationship and hands-on skills.

A study of gender differences in spatial relations skills of engineering students in the U.S. and Brazil found that there was a large disparity between the skills of female and male students. These studies attributed female student’s lesser skills set to two statistically significant factors: 1) less experience playing with building toys and 2) having taken less drafting courses prior to the engineering program. Spatial relations skills are critical to engineering. A gender study of computer science majors at Carnegie-Mellon University (one of the preeminent computer science programs in the country) found that, overall, male students come equipped with much better computer skills than female students. This equips male students with a considerable advantage in the classroom and could impact the confidence of female students.

Are these gender differences nature or nurture? There is considerable evidence that they are nurture. Studies show that most leading computer and video games appeal to male interests and have predominantly male characters and themes, thus it is not surprising that girls are much less interested in playing them. A study of computer games by Children Now found that 17% of the games have female characters and of these, 50% are either props, they tend to faint, have high-pitched voices, and are highly sexualized.

There are a number of studies that suggest that when girls and women are provided with the building blocks they need to succeed in STEM they will do as well if not better than their male counterparts. An Introductory Engineering Robotics class found that while males did somewhat better on the pre-test than females, females did as well as the males on the post-test following the class’s completion.

Another critical area of gender difference that teachers of STEM should keep in mind has less to do with actual skills and experience and more to do with perceptions and confidence. For females, confidence is a predictor of success in the STEM classroom. They are much less likely to retain interest if they feel they are incapable of mastering the material. Unfortunately, two factors work against female confidence level: 1) most girls will actually have less experience with STEM course content than their male counterparts and 2) males tend to overplay their accomplishments while females minimize their own. A study done of Carnegie Mellon Computer Science PhD students found that even when male and female students were doing equally well grade wise, female students reported feeling less comfortable. Fifty-three percent of males rated themselves as “highly prepared” in contrast to 0% of females.

It is important to note that many of the learning style differences described above are not strictly gender-based. They are instead based on differences of students with a background in STEM, problem-solving, and hands-on skills learned from childhood play and life experience and those who haven’t had the same type of exposure. A review of the literature on minority students and STEM finds that students of color are less likely to have the STEM background experiences and thus are missing many of the same STEM building blocks as girls and have the same lack of confidence. Many of the STEM curriculum and pedagogy solutions that work for female students will also work for students of color for this reason.

Bridge Classes/Modules to Ensure Core Skills

Teachers will likely see a gap in the core STEM skills of female and minority students for the reasons described above. Below are some solutions applied elsewhere to ensure that girls and women (and students of color) will get the building block STEM skills that many will be missing.

Teachers in the Cisco Academy Gender Initiative study assessed the skill levels of each of their students and then provided them with individualized lesson plans to ensure their success that ran parallel to the class assignments. Other teachers taught key skills not included in the curriculum at the beginning of the course, such as calculating math integers and tool identification and use. Students were provided with additional lab time, staffed by a female teaching assistant, knowing that the female students would disproportionately benefit from additional hands-on experience.

Carnegie-Mellon University came to view their curriculum as a continuum, with students entering at different points based on their background and experience. Carnegie-Mellon’s new frame of a “continuum” is purposefully different than the traditional negative model in which classes start with a high bar that necessitates “remedial” tutoring for students with less experience, stigmatizing them and undermining their confidence. Below is a list of ideas and suggestions that will help ALL students to succeed in the STEM classroom.

1. Building Confidence

How do teachers build confidence in female students who often have less experience than their male counterparts and perceive they are behind even when they are not?

1) Practice-based experience and research has shown that ensuring female students have the opportunity to gain experience with STEM, in a supportive environment, will increase their confidence level.

2) Bringing in female role models that have been successful in the STEM field is another important parallel strategy that should be used to assist your female students in seeing themselves as capable of mastering STEM classes: if she could do it, then I can too!

3) Consistent positive reinforcement by STEM teachers of their female students, with a positive expectation of outcome, will assist them in hanging in there during those difficult beginning weeks when they have not yet developed a technology schema or hands-on proficiency and everything they undertake seems like a huge challenge.

2. Appealing to Female Interests

Many of the typical STEM activities for the classroom appeal to male interests and turn off girls. For example, curriculum in robots often involves monsters that explode or cars that go fast. “Roboeducators” observed that robots involved in performance art or are characterized as animals are more appealing to girls. Engineering activities can be about how a hair dryer works or designing a playground for those with disabilities as well as about building bridges. Teachers should consider using all types of examples when they are teaching and incorporating activities in efforts to appeal female and male interests. Teachers can also direct students to come up with their own projects as a way of ensuring girls can work in an area of significance to them.

Research also shows that there are Mars/Venus differences between the genders and how each engages in technology. Overall, girls and women are excited by how the technology will be used – its application and context. Men will discuss how big the hard drive or engine is, how fast the processor runs, and debate the merits of one motherboard or engine versus another. These are topics that are, overall, of less interest to most females.

The Carnegie-Mellon Study took into account the differences of what engages female students and modified the Computer Science programs’ curriculum so that the context for the program was taught much earlier on in the semester and moved some of the more technical aspects of the curriculum (such as coding) to later in the semester. Authors observed that the female students were much more positive about getting through the tedious coding classes when they understood the purpose of it. Teachers should ensure that the context for the technology they are teaching is addressed early on in the semester by using real world stories and case studies to capture the interest of all of their students.

3. Group Dynamics in the Classroom

Research studies by American Association of University Women and Children Now have found that most females prefer collaboration and not competition in the classroom. Conversely, most males greatly enjoy competition as a method of learning and play. Many hands-on activities in technology classes are set up as competitions. Robotics for example, regularly uses competitiveness as a methodology of teaching. Teachers should
be cognizant of the preference of many girls for collaborative work and should add-in these types of exercises to their classes. Some ways to do this are by having students work in assigned pairs or teams and having a team grade as well as an individual grade. (See Reading 2 on Cooperative Learning.)

Another Mars/Venus dynamic that STEM teachers should be aware of occurs in the lab there male students will usually dominate the equipment and females will take notes or simply watch. Overall, male students have more experience and thus confidence with hands-on lab equipment than their female counterparts. Teachers should create situations to ensure that their female students are spending an equal amount of time in hands-on activities. Some approaches have been: 1) to pair the female students only with each other during labs in the beginning of the class semester so that they get the hands-on time and their confidence increases, putting them in a better position to work effectively with the male students later on, 2) allot a specific time for each student in pair to use the lab equipment and announce when it’s time to switch and monitor this, and 3) provide feedback to male students who are taking over by letting them know that their partner needs to do the activity as well.

4. Moving Female Students from Passive Learners to Proactive Problem Solvers

The main skill in STEM is problem solving in hands-on lab situations. For reasons already discussed regarding a lack of experience, most girls don’t come to STEM classes with these problem-solving skills. Instead, girls often want to be shown how to do things, repeatedly, rather than experimenting in a lab setting to get to the answer. Adding to this issue, many girls fear that they will break the equipment. In contrast, male students will often jump in and manipulate the equipment before being given any instructions by their teacher. Teachers can address this by such activities as: 1) having them take apart old equipment and put it together again, 2) creating “scavenger hunt” exercises that force them to navigate through menus, and 3) emphasizing that they are learning the problem solving process and that this is equally important to learning the content of the lesson and insisting that they figure out hands-on exercises on their own.

Research has also shown that females tend to engage in STEM activities in a rote, smaller picture way while males use higher order thinking skills to understand the bigger picture and the relationship between the parts. Again, moving female students (and the non-techsavvy student in general) to become problem solvers (versus just understanding the content piece of the STEM puzzle) will move them to use higher order thinking skills in STEM.

Finally, many teachers have reported that many female students will often want to understand how everything relates to each other before they move into action in the lab or move through a lesson plan to complete a specific activity. The female students try to avoid making mistakes along the way and will not only want to read the documentation needed for the lesson, they will often want to read the entire manual before taking any action. In contrast, the male student often needs to be convinced to look at the documentation at all. Boys are not as concerned with making a mistake a long the way as long as what they do ultimately works. The disadvantage for female students is that they often are so worried about understanding the whole picture that they don’t move onto the hands-on activity or they don’t do it in a timely fashion, so that they are consistently the last ones in the class to finish. Teachers can assist female (and non-tech-savvy) students to move through class material more quickly by providing instruction on how to quickly scan for only the necessary information needed to complete an assignment.

5. Role Models

Since the numbers of women in STEM are still small, girls have very few opportunities to see female role models solving science, technology, engineering or math problems. Teachers should bring female role models into the classroom as guest speakers or teachers, or visit them on industry tours, to send the message to girls that they can succeed in the STEM classroom and careers.

Bibliography

Medina, Afonso, Celso, Helena B.P. Gerson, and Sheryl A. Sorby. “Identifying Gender Differences in the 3-D Visualization Skills of Engineering Students in Brazil and in the United States”. International Network for Engineering Eucation and Research page. 2 August 2004: [http://www.ineer.org/Events/ICEE/papers/193.pdf].

Milto, Elissa, Chris Rogers, and Merredith Portsmore. “Gender Differences in Confidence Levels, Group Interactions, and Feelings about Competition in an Introductory Robotics Course”. American Society for Engineering Education page. 8 July 2004: [http://fie.engrng.pitt.edu/fie2002/papers/1597.pdf].

“Fair Play: Violence, Gender and Race in Video Games 2001”. Children Now page. 19 August 2004: [http://www.childrennow.org/media/video-games/2001/].

“Girls and Gaming: Gender and Video Game Marketing, 2000”. Children Now page. 17 June 2004: [http://www.childrennow.org/media/medianow/mnwinter2001.html].

Tech-Savvy: Educating Girls in the New Computer Age. District of Columbia: American Association of University Women Educational Foundation, 2000.

Margolis, Jane and Allan Fisher. Unlocking the Computer Clubhouse: Women in Computer. Cambridge, MA: The MIT Press, 2003.

Taglia, Dan and Kenneth Berry. “Girls in Robotics”. Online Posting. 16 September 2004: http://groups.yahoo.com/group/roboeducators/.

“Cisco Gender Initiative”. Cisco Learning Institute. 30 July 2004: http://gender.ciscolearning.org/Strategies/Strategies_by_Type/Index.html.

Donna Milgram is founder and Executive Director of the National Institute for Women in Trades, Technology & Science (IWITTS). She is currently the Principal Investigator of the CalWomenTech Project, a $2 million National Science Foundation grant awarded in April 2006. She was also the Principal Investigator of the WomenTech Project, funded by the National Science Foundation, which had a goal of increasing the number of women enrolled and retained in technology education in three national community college demonstration sites. She led IWITTS’s partnership with the Cisco Learning Institute (CLI)/Cisco Gender Initiative. Ms. Milgram produced the interactive teacher training video “School-to-Work: Preparing Young Women for High Skill, High Wage Careers.”

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1. North West universities play a key role in Science and Technology, and have a combined turnover of over £1.2 billion, almost 1% of the region’s total economy. Leading companies, including those in the Aerospace Business, automotive supply and manufacturing companies, nuclear energy and medical research are closely linked to North West universities. More than 50,000 North West students graduate every year, including 25,000 with life science degrees. Over 69,000 science students are trained every year.

2. The Aerospace Business in the North West has a turnover of £6 billion, and is responsible for producing military and commercial aircraft and components which are used both in the UK and exported worldwide. Extensive R&D programmes ensure that the latest technologies
are available to create the most advanced planes in the world. Countries all over the world rely on the North West Aerospace Business for their military and commercial aircraft requirements

3. The Chemistry Industry plays a vital role in the North West, and sales of chemicals contribute over £10 billion to the economy, equating to approximately 20% of the UK chemistry industry. Approximately 220,000 people are employed in this sector. In 2005, the Department of Trade and Industry announced that as part of the Technology Programme, one of the 19 new Knowledge Transfer Networks (KTNs) would be in Chemistry in the North West. KTNs help to share knowledge and research between businesses, academic institutions such as universities, and trade associations.

4. The North West and Cumbria in particular, is widely acknowledged as the centre of the UK Nuclear Energy industry, and is home to the Nuclear Decommissioning Authority. The research and development work done in this region has led the Government to conclude that utilising nuclear energy is part of a viable solution to meeting the energy needs of the UK.

5. There are over 50 research institutes, many of them multi-institutional, as well as traditional R&D departments. The North West is home to the Research and Development departments of several of the worlds leading companies, and business R&D investment in this region is greater than in any other part of the world except Asia. Recent reports show that 4 of the top 10 companies by R&D spending have significant facilities in the North West. Pharmaceutical development, including the largest cancer drug research centre in the UK, Aerospace Businesses, manufacturers of consumer products, as well as the Chemistry Industry and Nuclear Energy are well represented in the North West.

6. The North West’s seven science parks are home to many knowledge-based companies in diverse industries ranging from providing education to Nuclear Energy and decommissioning. Strong links to universities as well as research institutes and centres of knowledge, in the UK and abroad, help to ensure that Science and Technology in the North West is second to none.

7. Dedicated Strategic Science and Technology sites have been set up throughout the North West, and Manchester is aiming to become one of the UK’s first six Science Cities by 2015.

Manchester Science Park is internationally recognised as a centre of excellence, and is one of the most successful of its kind. Tenants include specialists in healthcare, telecoms, and digital media.

The Daresbury Science and Innovation Campus, near Warrington in Cheshire, is home to leading companies in diverse industries ranging from healthcare research to business support services. The nearby Daresbury Laboratory is one of the best-resourced science facilities in the UK.

Liverpool Science Park, right in the centre of Liverpool, is the fastest growing science park in the UK, and contains computer games, website design and software companies as well as solicitors specialising in intellectual property and technology law. Speke, also in Liverpool, is home to the National Biomanufacturing Centre, which is set to become the leading biopaharmaceutical design centre in Europe, and helps to create and develop new medicines

West Cumbria Science Park, near Whitehaven, has over 60 companies on site, ranging from ecology to engineering, many of which are involved in the Nuclear Energy Industry.

A Science Park in Lancaster is scheduled for development this year, and will be located close to the top-ten ranked university. This exciting new project will combine the renowned academic knowledge and resources of the University with local businesses know-how and the Lancaster Environment Centre.

8. With Manchester recently voted the most creative city in the UK, and Liverpool’s reputation as one of the leading cities for computer game design, the North West is at the forefront of new technologies as well as traditional Science and Technology. The use of ICT in education, website design and internet technologies, TV and film production, as well as other media industries, is all flourishing in the region, thanks to Science and Technology.

9. As well as looking to the future, the region’s scientific history is preserved through museums such as the World Museum in Liverpool, Quarry Bank Mill in Styal, Cheshire, and Wigan Pier. Visual displays as well as hands-on activities, demonstrations and different media show how Science and Technology has changed our lives, from mechanising everyday tasks to revolutionising manufacturing methods.

10. As well as the outstanding Science and Technology facilities, the North West is a popular business location thanks to its fantastic infrastructure. Within reach of 3 international airports, and a great motorway system, the North West is closer than you may think. In addition, the North West has many Areas of Natural Outstanding Beauty and the standard of living is high.

There has never been a better time to see how North West Science and Technology can help you.

About the Author

Matthew J James

The reality is that overall women tend to have less experience with technology than their male counterparts, whether we are talking about computer technology or auto technology. Instructors who are successful in retaining female students recognize that they need to start with the basics during the beginning of the semester so that the less experienced students get the basic building blocks needed to be successful (this is helpful to male students missing those basics too). So that might mean an introduction to tool identification and use or the basics of navigating the Internet. Instructors should also provide open lab time for students in need of additional hands-on experience. If possible, staff the lab with a senior female student, women are often more comfortable asking questions of other women in a male-dominated field. For some best practice case study examples that illustrate these concepts look at the Cisco Gender Initiative’s Best Practice Case Studies developed by the Institute for Women in Trades, Technology and Science (IWITTS) (1).

Step Two: Collaborative Learning in the Technology Classroom

Many female students lack confidence in the classroom and this negatively impacts their learning ability. There are several reasons for this: first, overall, male students have more experience with technology, especially hands-on labs; second, male students tend to boast of their accomplishments while females tend to think that they are doing poorly even when they are doing well; third, male students tend to dominate in classroom discussions and lab activities.

Technology instructors can overcome these factors by using collaborative group methods in the classroom designed to increase student learning, interaction and support of each other. Some examples of these group methods are: 1) grade students in teams as well as individually; 2) put female students in positions of leadership in the classroom; 3) assign students to teams or pairs rather than leaving it up to them to pick their partners; 4) have female students work together in labs during the beginning of the semester; 5) enlist the help of whiz kids with the teaching of their fellow students, providing them with a constructive outlet for their talents.

Step Three: Contextual Learning

The recent adage that women are from Mars and men are from Venus is alive and well in the technology classroom — women and men have different learning styles when it comes to technology. Most men are excited by the technology itself — how fast it is, the number of gigabytes, the size of the engine. Most women are engaged by how the technology will be used — how quickly the network will run, how much information can be stored, how far the vehicle can go without refueling. These Mars and Venus differences have implications for the class curriculum: female students will better understand technical concepts in the classroom when they understand the context for them. Don’t front load your computer programming classes with writing computer code with no context for this if you want to retain most of your female students. For more information on this subject including off-the-shelf curriculums for teaching contextual technology read IWITTS’s Making Math and Technology Courses User Friendly to Women and Minorities: An Annotated Bibliography (2).

Step Four: The Math Factor

Most technology courses require an understanding of applied math. Many women and girls are fearful of math and have had negative experiences in the math classroom. This phenomenon is so common that courses and curriculum on math anxiety for women are in place around the country. The key to success in teaching most females math is — like technology — contextual and group learning. Fortunately many off-the-shelf curriculums exist for teaching math contextually, see IWITTS’s bibliography linked above. Many technology courses at the two-year college level have math prerequisites that are unrelated to the technology coursework and omit the applied math that will be needed. Technology courses should only require math that is relevant to their courses and/or develop contextual math modules to add to their curriculum.

Step Five: Connect the Women in Your Classes with Other Women

A female mentor or peer support network can help your students stay the course when they are feeling discouraged and can provide helpful tips for succeeding in a predominantly male environment. There are many on-line and real-time associations for women in technology, connect your female students to them. See the Career Links on WomenTechWorld.org for a list of some of these networks. Also, WomenTechTalk on WomenTechWorld.org — a free listserv for women in technology and students — provides a combination of support and expert career panels to it’s over 200 members from across the U.S.

Donna Milgram is founder and Executive Director of the National Institute for Women in Trades, Technology & Science (IWITTS). She is currently the Principal Investigator of the CalWomenTech Project, a $2 million National Science Foundation grant awarded in April 2006. She was also the Principal Investigator of the WomenTech Project, funded by the National Science Foundation, which had a goal of increasing the number of women enrolled and retained in technology education in three national community college demonstration sites. She led IWITTS’s partnership with the Cisco Learning Institute (CLI)/Cisco Gender Initiative. Ms. Milgram produced the interactive teacher training video “School-to-Work: Preparing Young Women for High Skill, High Wage Careers.” Ms. Milgram’s recent conference presentations include: the NSF ATE Conference “Recruiting Women to Science, Technology, Engineering & Math” (2004) and California Educating for Careers Conference in 2003.

Bibliography: (1) http://gender.ciscolearning.org/Strategies/Strategies_by_Region/North_America/United_States/Index.html

(2) http://www.iwitts.com/assets/1.5_BiblioMathTechFriendly.PDF

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