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There is an inexorable trend among college students to universal ownership, mobility, and access to technology.

Students were asked about the applications they used on their electronic devices. They reported that they use technology first for educational purposes, followed by communication.

presentation software was driven primarily by the requirements of the students' major and the curriculum.

Communications and entertainment are very much related to gender and age.

From student interviews, a picture emerged of student technology use driven by the demands of the major and the classes that students take. Seniors reported spending more time overall on a computer than do freshmen, and they reported greater use of a computer at a place of employment. Seniors spent more hours on the computer each week in support of their educational activities and also more time on more advanced applications—spreadsheets, presentations, and graphics.

Confirming what parents suspect, students with the lowest grade point averages (GPAs) spend significantly more time playing computer games; students with the highest GPAs spend more hours weekly using the computer in support of classroom activities. At the University of Minnesota, Crookston, students spent the most hours on the computer in support of classroom activities. This likely reflects the deliberate design of the curriculum to use a laptop extensively. In summary, the curriculum's technology requirements are major motivators for students to learn to use specialized software.

The interviews indicated that students are skilled with basic office suite applications but tend to know just enough technology functionality to accomplish their work; they have less in-depth application knowledge or problem solving skills.

According to McEuen, student technology skills can be likened to writing skills: Students come to college knowing how to write, but they are not developed writers. The analogy holds true for information technology, and McEuen suggested that colleges and universities approach information technology in the same way they approach writing.6

he major requires the development of higher-level skill sets with particular applications.

The comparative literature on student IT skill self-assessment suggests that students overrate their skills; freshmen overrate their skills more than seniors, and men overrate their skills more than women.7 Our data supports these conclusions. Judy Doherty, director of the Student Technologies Resource Group at Colgate University, remarked on student skill assessment, "Students state in their job applications that they are good if not very good, but when tested their skills are average to poor, and they need a lot of training."8

Mary Jane Smetanka of the Minneapolis–St. Paul Star Tribune reported that some students are so conditioned by punch-a-button problem solving on computers that they approach problems with a scattershot impulsiveness instead of methodically working them through. In turn, this leads to problem-solving difficulties.

We expected to find that the Net Generation student prefers classes that use technology. What we found instead is a bell curve with a preference for a moderate use of technology in the classroom (see Figure 1).

It is not surprising that if technology is used well by the instructor, students will come to appreciate its benefits.

A student's major was also an important predictor of preferences for technology in the classroom (see Table 3), with engineering students having the highest preference for technology in the classroom (67.8 percent), followed by business students (64.3 percent).

we found that many of the students most skilled in the use of technology had mixed feelings about technology in the classroom.

he highest scores were given to improved communications, followed by factors related to the management of classroom activities. Lower impact activities had to do with comprehension of classroom materials (complex concepts).

The instructors' use of technology in my classes has increased my interest in the subject matter. 3.25 Classes that use information technology are more likely to focus on real-world tasks and examples.

I spend more time engaged in course activities in those courses that require me to use technology.

Interestingly, students do not feel that use of information technology in classes greatly increases the amount of time engaged with course activities (3.22 mean).12 This is in direct contrast to faculty perceptions reported in an earlier study, where 65 percent of faculty reported they perceived that students spend more time engaged with course materials

Only 12.7 percent said the most valuable benefit was improved learning; 3.7 percent perceived no benefit whatsoever. Note that students could only select one response, so more than 12.7 percent may have felt learning was improved, but it was not ranked highest. These findings compare favorably with a study done by Douglas Havelka at the University of Miami in Oxford, Ohio, who identified the top six benefits of the current implementation of IT as improving work efficiency, affecting the way people behave, improving communications, making life more convenient, saving time, and improving learning ability.14

Our data suggest that we are at best at the cusp of technologies being employed to improve learning.

The interactive features least used by faculty were the features that students indicated contributed the most to their learning.

he students in this study called our attention to performance by noting an uneven diffusion of innovation using this technology. This may be due, in part, to faculty or student skill. It may also be due to a lack of institutional recognition of innovation, especially as the successful use of course management systems affects or does not affect faculty tenure, promotion, and merit decisions

Humanities 7.7% 47.9% 40.2

What we found was that many necessary skills had to be learned at the college or university and that the motivation for doing so was very much tied to the requirements of the curriculum. Similarly, the students in our survey had not gained the necessary skills to use technology in support of academic work outside the classroom. We found a significant need for further training in the use of information technology in support of learning and problem-solving skills.

Course management systems were used most by both faculty and students for communication of information and administrative activities and much less in support of learning.

In 1997, Michael Hooker proclaimed, "higher education is on the brink of a revolution." Hooker went on to note that two of the greatest challenges our institutions face are those of "harnessing the power of digital technology and responding to the information revolution."18 Hooker and many others, however, did not anticipate the likelihood that higher education's learning revolution would be a journey of a thousand miles rather than a discrete event. Indeed, a study of learning's last great revolution—the invention of moveable type—reveals, too, a revolution conducted over centuries leading to the emergence of a publishing industry, intellectual property rights law, the augmentation of customized lectures with textbooks, and so forth.

Qualitative data were collected by means of focus groups and individual interviews. We interviewed undergraduate students, administrators, and individuals identified as experts in the field of student technology use in the classroom. Student focus groups and interviews of administrators were conducted at six of the thirteen schools participating in the study.

The institutions chosen represent a nonrepresentative mix of the different types of higher education institution in the United States, in terms of Carnegie class as well as location, source of funding, and levels of technology emphasis. Note, however, that we consider our findings to be instructive rather than conclusive of student experiences at different types of Carnegie institutions.

Both the ECAR study on faculty use of course management systems and this study of student experiences with information technology concluded that, while information technology is indeed making important inroads into classroom and learning activities, to date the effects are largely in the convenience of postsecondary teaching and learning and do not yet constitute a "learning revolution." This should not surprise us. The invention of moveable type enhanced, nearly immediately, access to published information and reduced the time needed to produce new publications. This invention did not itself change literacy levels, teaching styles, learning styles, or other key markers of a learning revolution. These changes, while catalyzed by the new technology, depended on slower social changes to institutions. I believe that is what we are witnessing in higher education today.

The qualitative data suggest a slightly different picture. Students have very basic office suite skills as well as e-mail and basic Web surfing skills. Moving beyond basic activities is problematic. It appears that they do not recognize the enhanced functionality of the applications they own and use.

It cannot be assumed that they come to college prepared to use advanced software applications.

25.6 percent of the students preferred limited or no use of technology in the classroom.

"Information technology is just a tool. Like all tools, if used properly it can be an asset. If it is used improperly, it can become an obstacle to achieving its intended purpose. Never is it a panacea."

In his recent Harper's article "The Ecstasy of Influence," the novelist Jonathan Lethem imaginatively reviews the history of appropriation and recasts it as essential to the act of creation.3

He asserts that visual, sound, and text collage "might be called the art form of the twentieth century, never mind the twenty-first."

Lethem concludes: "Finding one's voice isn't just an emptying and purifying oneself of the words of others but an adopting and embracing of filiations, communities, and discourses."

It's no mere coincidence that the rise of modernist genres using collage techniques and more fragmented structures accompanied the emergence of photography and audio recording. Reading Walter Benjamin's highly influential 1936 essay "The Work of Art in the Age of Mechanical Reproduction,"4 it's clear that the profound effects of reproductive technology were obvious at that time. As Gould argued in 1964 (influenced by theorists such as Marshall McLuhan5), changes in how art is produced, distributed, and consumed in the electronic age have deep effects on the character of the art itself.

The result has been a flood of work created by largely anonymous media artists who are reimagining the iconography of popular culture, unearthing forgotten artifacts and contextualizing them anew. One only has to spend an hour surfing YouTube.com to get a sense of the subversive fun being had by hundreds of thousands of culture mashers.6

he statement "users will never add metadata" was becoming a mantra at gatherings of increasingly frustrated learning object promoters (again, I was often present) and when most learning object repositories were floundering, resource-sharing services such as del.icio.us and Flickr were enjoying phenomenal growth, with their user communities eagerly contributing heaps of useful metadata via simple folksonomy-oriented tagging systems.

Educators might justifiably argue that their materials are more authoritative, reliable, and instructionally sound than those found on the wider Web, but those materials are effectively rendered invisible and inaccessible if they are locked inside course management systems.

It's a dirty but open secret that many courses in private environments use copyrighted third-party materials in a way that pushes the limits of fair use—third-party IP is a big reason why many courses cannot easily be made open.

Pageflakes (http://www.pageflakes.com/), another RSS-based personal portal, supports a number of education-specific templates for tracking grades and displaying class schedules along with resources; pages with such sensitive information can also be made private.13

nother Pipe that Hirst has created is the "OpenLearn Unit Outlinks Search Hub Pipe," which extracts "all the outgoing links from a course unit, then feeds these into a Yahoo Search pipe, which uses the domains as search limits for the search."20 In other words, this Pipe can create a filtered search of trusted domains that are relevant to a particular course, and the filtered search will adjust automatically as new links are added to the course materials. Of course, this added functionality requires open content and a reusable data format in order to work properly.

If the course unit in question is locked away in a course management system behind a password firewall, Pipes cannot access the data required to create the customized search. As with content remixing, open access to materials is not just a matter of some charitable impulse to share knowledge with the world; it is a core requirement for participating in some of the most exciting and innovative activity on the Web.

. Working with the Scottish students they could then find out the stories behind these artefacts and create a Google Map which tracks these stories geographically, historically and anecdotally."21

All too often, college and university administrators react to this type of innovation with suspicion and outright hostility rather than cooperation. Witness the recent case at Harvard, where students, frustrated with the quality of the official institutional Web portal, decided to build their own portal, entitled Crimson Connect (http://www.crimsonconnect.com/), using RSS feeds and, for the most part, existing free software tools. University officials responded by demanding the removal of material that had been syndicated from password-protected course pages.25

those of us in higher education who observe the successful practices in the wider Web world have an obligation to consider and discuss how we might apply these lessons in our own contexts. We might ask if the content we presently lock down could be made public with a license specifying reasonable terms for reuse. When choosing a content management system, we might consider how well it supports RSS syndication.

Two of my favorite YouTube clips are the remix of The Shining's trailer (http://www.youtube.com/watch?v=iVjl7gK4HGU) and the mashup of the original Star Trek TV series with a Monty Python song (http://www.youtube.com/watch?v=eEnyT0_BjxA). These two videos themselves illustrate the difference between a remix and a mashup.

But what is so special about the egocentric perspectives and situated learning now enabled by emerging media? After all, each of us lives with an egocentric perspective in the real world and has many opportunities for situated learning without using technology. One attribute that makes mediated immersion different and powerful is the ability to access information resources and psychosocial community distributed across distance and time, broadening and deepening experience. A second important attribute is the ability to create interactions and activities in mediated experience not possible in the real world, such as teleporting within a virtual environment, enabling a distant person to see a real-time image of your local environment, or interacting with a (simulated) chemical spill in a busy public setting. Both of these attributes are actualized in the Alice-in-Wonderland interface.

Net Generation learning styles stem primarily from the world-to-the-desktop interface; however, the growing prevalence of interfaces to virtual environments and augmented realities is beginning to foster so-called neomillennial learning styles in users of all ages.

Immersion is the subjective impression that one is participating in a comprehensive, realistic experience.

Beyond actional and symbolic immersion, advances in interface technology are now creating virtual environments and augmented realities that induce a psychological sense of sensory and physical immersion.

Inducing a participant's symbolic immersion involves triggering powerful semantic associations via the content of an experience.

The research on virtual reality Salzman and I conducted on frames of reference found that the exocentric and the egocentric FORs have different strengths for learning. Our studies established that learning ideally involves a "bicentric" perspective alternating between egocentric and exocentric FORs.

The capability of computer interfaces to foster psychological immersion enables technology-intensive educational experiences that draw on a powerful pedagogy: situated learning.

The major schools of thought cited are behaviorist theories of learning (presentational instruction), cognitivist theories of learning (tutoring and guided learning by doing), and situated theories of learning (mentoring and apprenticeships in communities of practice).

Situated learning requires authentic contexts, activities, and assessment coupled with guidance from expert modeling, mentoring, and "legitimate peripheral participation."8 As an example of legitimate peripheral participation, graduate students work within the laboratories of expert researchers, who model the practice of scholarship. These students interact with experts in research as well as with other members of the research team who understand the complex processes of scholarship to varying degrees. While in these laboratories, students gradually move from novice researchers to more advanced roles, with the skills and expectations for them evolving.

Potentially quite powerful, situated learning is much less used for instruction than behaviorist or cognitivist approaches. This is largely because creating tacit, relatively unstructured learning in complex real-world settings is difficult.

Initial research on Environmental Detectives and other AR-based educational simulations demonstrates that this type of immersive, situated learning can effectively engage students in critical thinking about authentic scenarios.

However, virtual environments and ubiquitous computing can draw on the power of situated learning by creating immersive, extended experiences with problems and contexts similar to the real world.9 In particular, MUVEs and real-world settings augmented with virtual information provide the capability to create problem-solving communities in which participants can gain knowledge and skills through interacting with other participants who have varied levels of skills, enabling legitimate peripheral participation driven by intrinsic sociocultural forces.

Situated learning is important in part because of the crucial issue of transfer. Transfer is defined as the application of knowledge learned in one situation to another situation and is demonstrated if instruction on a learning task leads to improved performance on a transfer task, typically a skilled performance in a real-world setting

Moreover, the evolution of an individual's or group's identity is an important type of learning for which simulated experiences situated in virtual environments or augmented realities are well suited. Reflecting on and refining an individual identity is often a significant issue for higher education students of all ages, and learning to evolve group and organizational identity is a crucial skill in enabling innovation and in adapting to shifting contexts.

Immersion is important in this process of identity exploration because virtual identity is unfettered by physical attributes such as gender, race, and disabilities.

Thanks to out-of-game trading of in-game items, Norrath, the virtual setting of the MMOG EverQuest, is the seventy-seventh largest economy in the real world, with a GNP per capita between that of Russia and Bulgaria. One platinum piece, the unit of currency in Norrath, trades on real world exchange markets higher than both the Yen and the Lira (Castronova, 2001).14

Multiple teams of students can access the MUVE simultaneously, each individual manipulating an avatar which is "sent back in time" to this virtual environment. Students must collaborate to share the data each team collects. Beyond textual conversation, students can project to each other "snapshots" of their current individual point of view (when someone has discovered an item of general interest) and also can "teleport" to join anyone on their team for joint investigation. Each time a team reenters the world, several months of time have passed in River City, so learners can track the dynamic evolution of local problems.

In our research on this educational MUVE based on situated learning, we are studying usability, student motivation, student learning, and classroom implementation issues. The results thus far are promising: All learners are highly motivated, including students typically unengaged in classroom settings. All students build fluency in distributed modes of communication and expression and value using multiple media because each empowers different types of communication, activities, experiences, and expressions. Even typically low-performing students can master complex inquiry skills and sophisticated content. Shifts in the pedagogy within the MUVE alter the pattern of student performance.

Research shows that many participants value this functionality and choose to access the Web page after leaving the museum.

Participants in these distributed simulations use location-aware handheld computers (with GPS technology), allowing users to physically move throughout a real-world location while collecting place-dependent simulated field data, interviewing virtual characters, and collaboratively investigating simulated scenarios.

he defining quality of a learning community is that there is a culture of learning, in which everyone is involved in a collective effort of understanding. There are four characteristics that such a culture must have: (1) diversity of expertise among its members, who are valued for their contributions and given support to develop, (2) a shared objective of continually advancing the collective knowledge and skills, (3) an emphasis on learning how to learn, and (4) mechanisms for sharing what is learned. If a learning community is presented with a problem, then the learning community can bring its collective knowledge to bear on the problem. It is not necessary that each member assimilate everything that the community knows, but each should know who within the community has relevant expertise to address any problem. This is a radical departure from the traditional view of schooling, with its emphasis on individual knowledge and performance, and the expectation that students will acquire the same body of knowledge at the same time.26

This immersion in virtual environments and augmented realities shapes participants' learning styles beyond what using sophisticated computers and telecommunications has fostered thus far, with multiple implications for higher education.

Students were most effective in learning and problem-solving when they collectively sought, sieved, and synthesized experiences rather than individually locating and absorbing information from some single best source.

Rheingold's forecasts draw on lifestyles seen at present among young people who are high-end users of new media

Notion of place is layered/blended/multiple; mobility and nomadicity prevalent among dispersed, fragmented, fluctuating habitats (for example, coffeehouses near campus)

Rather than having core identities defined through a primarily local set of roles and relationships, people would express varied aspects of their multifaceted identities through alternate extended experiences in distributed virtual environments and augmented realities.

one-third of U.S. households now have broadband access to the Internet. In the past three years, 14 million U.S. families have linked their computers with wireless home networks. Some 55 percent of Americans now carry cell phones

Mitchell's forecasts25 are similar to Rheingold's in many respects. He too envisions largely tribal lifestyles distributed across dispersed, fragmented, fluctuating habitats: electronic nomads wandering among virtual campfires. People's senses and physical agency are extended outward and into the intangible, at considerable cost to individual privacy. Individual identity is continuously reformed via an ever-shifting series of networking with others and with tools. People express themselves through nonlinear, associational webs of representations rather than linear "stories" and co-design services rather than selecting a precustomized variant from a menu of possibilities.

More and more, though, people of all ages will have lifestyles involving frequent immersion in both virtual and augmented reality. How might distributed, immersive media be designed specifically for education, and what neomillennial learning styles might they induce?

Guided social constructivism and situated learning as major forms of pedagogy

Peer-developed and peer-rated forms of assessment complement faculty grading, which is often based on individual accomplishment in a team performance context  Assessments provide formative feedback on instructional effectiveness

Mediated immersion creates distributed learning communities, which have different strengths and limits than location-bound learning communities confined to classroom settings and centered on the teacher and archival materials.27

Multipurpose habitats—creating layered/blended/personalizable places rather than specialized locations (such as computer labs)

Neomillenial Versus Millennial Learning Styles

Emphasis is placed on implications for strategic investments in physical plant, technology infrastructure, and professional development.

o the extent that some of these ideas about neomillennial learning styles are accurate, campuses that make strategic investments in physical plant, technical infrastructure, and professional development along the dimensions suggested will gain a considerable competitive advantage in both recruiting top students and teaching them effectively.

such as textbooks linked to course ratings by students)

Mirroring": Immersive virtual environments provide replicas of distant physical settings

Middleware, interoperability, open content, and open source

Finding information Sequential assimilation of linear information stream

Student products generally tests or papers Grading centers on individual performance

These ideas are admittedly speculative rather than based on detailed evidence and are presented to stimulate reaction and dialogue about these trends.

f we accept much of the analysis above

students of all ages with increasingly neomillennial learning styles will be drawn to colleges and universities that have these capabilities. Four implications for investments in professional development also are apparent. Faculty will increasingly need capabilities in:

Some of these shifts are controversial for many faculty; all involve "unlearning" almost unconscious beliefs, assumptions, and values about the nature of teaching, learning, and the academy. Professional development that requires unlearning necessitates high levels of emotional/social support in addition to mastering the intellectual/technical dimensions involved. The ideal form for this type of professional development is distributed learning communities so that the learning process is consistent with the knowledge and culture to be acquired. In other words, faculty must themselves experience mediated immersion and develop neomillennial learning styles to continue teaching effectively as the nature of students alters.

Differences among individuals are greater than dissimilarities between groups, so students in any age cohort will present a mixture of neomillennial, millennial, and traditional learning styles

The technologies discussed are emerging rather than mature, so their final form and influences on users are not fully understood. A substantial number of faculty and administrators will likely dismiss and resist some of the ideas and recommendations presented here.

there is an almost insatiable interest in factual information made available online

rbitrarily restricting access to factual information simply directs the flow around the institution restricting access. Britannica could be earning over a hundred million dollars a year from advertising revenue – that’s what it is projected that Wikipedia could earn, just from banner advertisements, if it ever accepted advertising. But Britannica chose to lock itself away from its audience.

under no circumstances do you take yourself off the network.

t seems as though many of our institutions are mired in older ways of thinking, where selfishness and protecting the collection are seen as a cardinal virtues. There’s a new logic operating: the more something is shared, the more valuable it becomes.

In a landmark settlement of a long-running copyright dispute with book publishers in the United States, Google agreed to pay a license fee to those publishers for their copyrights – even for books out of print. In return, the publishers are allowing Google to index, search and display all of the books they hold under copyright.

Each of these texts is indexed and searchable – just as with the books under copyright, but, in this case, the full text is available through Google’s book reader tool. For works under copyright but out-of-print, Google is now acting as the sales agent, translating document searches into book sales for the publishers, who may now see huge “long tail” revenues generated from their catalogues.

Since Google is available from every computer connected to the Internet (given that it is available on most mobile handsets, it’s available to nearly every one of the four billion mobile subscribers on the planet), this new library – at least seven million volumes – has become available everywhere. The library has become coextensive with the Internet.

When CD-ROM was introduced, twenty years ago, it was hailed as the “new papyrus,” capable of storing vast amounts of information in a richly hyperlinked format. As the limits of CD-ROM became apparent, the Web became the repository of the hopes of all the archivists and bibliophiles who dreamed of a new Library of Alexandria, a universal library with every text in every tongue freely available to all.

We have now gotten as close to that ideal as copyright law will allow;

For libraries, Google has established subscription-based fees for access to books covered by copyright.

Within another few years, every book within arm’s length of Google (and Google has many, many arms) will be scanned, indexed and accessible through books.google.com. This library can be brought to bear everywhere anyone sits down before a networked screen. This librar

The library has been obsolesced because it has become universal; the stacks have gone virtual, sitting behind every screen. Because the idea of the library has become so successful, so universal, it no longer means anything at all. We are all within the library.

The central task of the librarian – if I can be so bold as to state something categorically – is to bring order to chaos. The librarian takes a raw pile of information and makes it useful.

At its most visible, the book cataloging systems used in all libraries represents the librarian’s best efforts to keep an overwhelming amount of information well-managed and well-ordered.

Google seems to have abandoned – or ignored – library science in its own book project. I can’t tell you why this is, I can only tell you that it looks very foolish and naïve.

because the library is universal, library science now needs to be a universal skill set, more broadly taught than at any time previous to this. We have become a data-centric culture, and are presently drowning in data. It’s difficult enough for us to keep our collections of music and movies well organized; how can we propose to deal with collections that are a hundred thousand times larger?

longtail

Wikipedia Scanner

This database is possible thanks to a combination of Wikipedia policies and (mostly) publicly available information.

The online encyclopedia allows anyone to make edits, but keeps detailed logs of all these changes. Users who are logged in are tracked only by their user name, but anonymous changes leave a public record of their IP address.

The result: A database of 34.4 million edits, performed by 2.6 million organizations or individuals ranging from the CIA to Microsoft to Congressional offices, now linked to the edits they or someone at their organization's net address has made.

By exposing the anonymous edits that companies such as drugs and big pharmaceutical companies make in entries that affect their businesses, it could help experts check up on the changes and make sure they're accurate, he says.

Data obtained from these sessions with high school and college seniors in Indiana, Oregon, and Virginia

From the beginning, however, a problem arose in that those middle school students went on to high schools and later to colleges that did not (and do not) provide this type of rich learning experience—a learning experience that can best be achieved when technology is used in the service of learning.

Less attention has been given to how to help students achieve the desired learning outcomes through technology.

comparatively little support has been devoted to helping faculty use computers and other technologies in creative and innovative ways to deepen student learning.

institutional structures and practices to resolve technical problems that faculty invariably encounter are very limited or are not the type of aid needed. Such lack of support limits the amount of time faculty can spend on what they do best—building a compelling curriculum and integrating technology for more powerful learning.

To develop intentional learners, the curriculum must go beyond helping students gain knowledge for knowledge's sake to engaging students in the construction of knowledge for the sake of addressing the challenges faced by a complex, global society.

integrating study abroad into courses back on the home campus;

Consider this scenario:

Faculty concerns perhaps center less on being "replaceable" and more on worrying that the teaching and learning enterprise will be reduced to students gathering information that can be easily downloaded, causing them to rely too heavily on technology instead of intellect.

First, traditional age students overwhelmingly prefer face-to-face contact with faculty to mediated communication. Second, technology used in the service of learning will require more—not less—sophistication on the part of students as they engage in processes of integration, translation, audience analysis, and critical judgment.

Faculty with expertise in one or more subjects, who have been exposed to what we know about how people learn, can determine how to enhance this learning through the use of technology. But simply understanding how to use technology will not provide the integration needed to reach the desired learning outcomes.

There is a need for integrating technology that is in the service of learning throughout the curriculum. More intentional use of technology to capture what students know and are able to integrate in their learning is needed.

perhaps the most revealing data came from the next question: Do you allow cell phones in school? Most participants said students can carry cell phones as long as they keep them turned off during class; yet, most also agreed that cell phones could be useful for instruction. Participants also said that if students bring personal devices to school, 40 to 60 percent of those students bring a device with broadband access.

"Educators want their students to be able to use these technologies, but they don't know how they can be applied in the classroom."

"Schools first need to develop a plan of action for when new technologies are introduced and then determine their bandwidth needs. Then they'll be getting somewhere," she said.

Steve Hargadon, director of the K12 Open Technologies Initiative at the Consortium for School Networking, and founder of www.classroom20.com. Hargadon developed his social networking site for educators as a way to get educators used to the idea of social networking not always as a scary, educationally empty phenomenon. "We have to look at the tools and the devices behind popular technologies. Just because bad things sometimes happen on Facebook doesn't mean the technology itself can't be useful. It just depends how it's used," he said. Hargadon says that for educators, profile pages can be portfolios and background information for others to see. The "friends" you are making are really "colleagues," he said--and uploading content and adding commentary provides authentic feedback to your ideas. "Common interest groups can be turned into group projects, and the discussion forums allow for asking questions and getting engaged in meaningful conversation. The wisdom of the group will always help when trying to solve problems," he said.

For these panelists, the shift in education from a teacher-centric, factory-style model to a more dynamic model filled with ubiquitous access to information, newly created content, and personal devices is not a struggle if you start with a plan--because only by being open to new ideas will today's students be tomorrow's innovators.

Twitter is fast becoming a serious platform for discourse and discussion. More than a status app, it is being used as a first alert mechanism for the dissemination of news and for immediate discussion surrounding that news. It is the coverage of news events and the continued emergence of citizen journalism that will push Twitter toward the mainstream this year.

Increasingly mainstream news reporters and bloggers are utilizing Twitter to put up news tid bits as they happen, and commentary as it pops into their heads.

Twitter has smartly nourished a large set of tools that help people use the service. This makes it easier for people to get content on Twitter in the manner most convenient and most comfortable to them, which in the long run should help drive adoption of the service. "The API has been arguably the most important, or maybe even inarguably, the most important thing we've done with Twitter," Twitter co-founder Biz Stone told us in September.

The API has also allowed for mashups that filter Twitter content making it easier to find. One relevant Twitter aggregator is Politweets (our coverage), which brings together all the messages sent over Twitter about the US election.

Unlike TV or newspaper, Twitter allows for a conversation.

Twitter encourages discourse and feedback. For reporters that aren't afraid to get down and dirty, Twitter is a golden opportunity to build a rapport with readers and gauge public opinion. It also makes readers feel more connected to the news when they can participate in a discussion about it as it happens, often times with the people reporting it first hand.

"It's not right for every piece of information. It's certainly not well suited for longer analysis. But when it comes to instantly assembling raw data from several sources that then go into fully baked news stories, nothing beats it."

But for the mainstream audience, Twitter might need better filtering tools before people can really wrap their heads around it.

it's not threaded, so replies get shuffled around and often times, out of context, just become confusing. Further, when everyone is having a conversation at once, things get noisy. Twitter desperately needs a filter.

Twitter is being used more and more for mainstream news coverage. KPBS News San Diego uses Twitter to put out updates about stories, for example, and during the California wildfires last fall it was a must read. The potential for Twitter to be used for news dissemination is something the site's founders realized early on during an earthquake.

it seems likely that Twitter will become an increasingly more important point for the distribution of breaking news during 2008, to the extent that traditional journalists will begin to pay more and more attention to it the way they have to blogs.

Academics and their institutions have sold out to economic interests in the name of preserving the only system trustworthy enough to produce authoritative information.

I believe it is fair to label as “apartheid” any artificial social construct that privileges an elite minority to the detriment of a majority. The artificial construct doing that in the world of knowledge is the toll-access system of traditional scholarly communication.

Despite all the digitizing and online publishing now extant, despite the proliferation of websites and web users, despite the largely up-to-date technological infrastructure within academia, it is still the case that most of the world’s most important knowledge remains out of reach of most of the world. Keep that simple fact central in your mind as I revisit the mission statements of universities and academic presses that purport to promote scholarship for the general benefit of humankind.

“The mission of a university press,” said Daniel Coit Gilman, President of Johns Hopkins University in 1880, “is to assist the university in fulfilling its noble mission ‘to advance knowledge, and to diffuse it not merely among those who can attend the daily lectures—but far and wide.'" Universities and academic publishers are ostensibly dedicated to the very opposite of keeping people and knowledge apart. And yet, they do.

You really don’t need to go to the developing world to recognize that advanced knowledge is a big club with stiff entrance fees. Even middle class Americans will think twice before throwing down $30 for a scholarly article. How likely will this knowledge ever reach scholars in Mexico or India? And just how broadly can the editors of Subjectivity expect it to reach when subscribing costs $503/year?

Academic authors, editors, publishers, and distributors are simply not in the business of reaching the masses; they are in the business of reaching other specialists.

Academia banks on Intellectual Apartheid; its knowledge economy only rewards specialists publishing to specialists. In such a world, the “influence” of scholarship is not often correlated to real-world effects; it is usually correlated to how well a given work contributes to the specialist knowledge economy. Citation indexes measure reputations among specialists; “impact factor” relates not to real-world impact, but to reputation within the closed system.

one of the great secrets of academic publishing

academia could care less about whether anything its scholars do actually makes a difference in the world, except for the occasional puff piece to show to contributors or alumni. Reaching out to the whole world is the stuff that convocation speeches and university mission statements are made of, but in the day-to-day world of academia, actually reaching the world with one’s refined knowledge is not rewarded. In fact, it is often punished. Generalists, such as those who are using blogging to actually talk to the public about their ideas, are threatened with lack of tenure or advancement if they waste their time in anything but publications oriented towards their disciplinary peers.

A university’s reward system requires its faculty to publish in peer-reviewed journals. Peer-reviewed journals serve the purpose of authenticating knowledge, but at the same time they also wall in that knowledge by making it available only to those willing to pay for it.

There is an assumption that if something is “published” (meaning published in a conventional, peer-reviewed journal), then it is appropriately circulating and available.

It may be “circulating” among subscribers (a few hundred), but it is simultaneously being kept from the online public (a few billion).

Essentially, scholars whose work is measured in terms of how often their articles are cited within peer-reviewed literature demonstrate not so much the actual worth or impact of their ideas as they demonstrate their fidelity to a closed knowledge economy. Impact factor statistics are really loyalty points for the gentlemen's club: if you impressed other members of the club, you get to stay in it. If you try for other audiences--like the one's loftily imagined in university mission statements--you show disloyalty to the club.

scholars underestimate the value and influence of their work, voluntarily giving up what their work might mean and do if circulating among a public that is literally six or seven orders of magnitude larger in size that the subscriber base of the most used journals. And it's a shame that broader, open, multi-disciplinary review is considered inferior to one-time assessment by two or three experts. Can we really be sure that conventional peer-reviewed knowledge is as reliable as it pretends to be when its adherents resist transparency and the checks and balances of exposing this knowledge more broadly?

I call upon you to join me in a full divestment from intellectual apartheid.

Here's how each academic stakeholder can fight Intellectual Apartheid: Scholars: Publish your work in Open Access journals or arrange open access for publications in conventional journals. Use Creative Commons licensing (rather than signing away copyright) in order to preserve access to your own work Deposit your publications in institutional or disciplinary archives to ensure permanent open access and the broadest exposure to search engines. Refuse to peer-review manuscripts or serve in editorial capacities for any journal that does not accommodate open access. Cancel subscriptions to toll-access scholarship Wean yourself from using any research materials that an everyday person from a developing country wouldn't have full access to via the Internet

In training students, patrons, and faculty, teach them more about how and why to use open access resources rather than how to use expensive proprietary databases and services. Work with administrators to educate faculty about the benefits of open access publishing and rights management.

Administrators Create a university-wide mandate (as Harvard has done), requiring faculty to retain copyright of their scholarship and to license the non-exclusive depositing of that scholarship in the institutional archive. Update promotion and tenure policies to favor open access publications and to accommodate evolving scholarly genres (such as data sets, software, and scholarly tools that build the cyberinfrastructure). Require chairs and deans to educate faculty on evolving academic publishing models and to ready their conversion to using and publishing open access scholarship.

Although today's students are much more likely to begin their research online, Miller-Cochran said students still often perceive the articles, charts, and data found in books as more authoritative than online information.

"They tend to be trusting, perhaps even more so, of things they see in print," said Miller-Cochran, who has distributed the checklist research matrix to her students at North Carolina State. "We wanted [students] to be looking at all sources they were finding and asking more critical questions about the nature of what they have found."