VASMIR was always my favorite of the nuclear rockets, it seems to be the one that combines the best features of high-powered, but low-risk. Too bad project prometheus isn't going anywhere... Oh well.

As for your idea of mining astroids, what I would suggest is to do the following. First of all, transport a satellite with lots of gold, iron, silicon if avaliable, copper, etc. Secondly, build a space factory. Then build satellites already in orbit, which would probably be cheaper than if they were built on the ground, they would be better, and best of all, they would already be in space. From there, you could make alot of cash, with which you could proceed to return some of the precious metals to the earth, but only the most precious.

There are a few problems with just taking platinum.

1. How are you going to filter it out?

2. That large of a chunck of platinum would seriously decrease the market value for it.

The chunck of rock in LEO would be easier, and wouldn't reduce the demand, especially since it would be hard to get the factory process started. Also, alot of the development of satellites goes into helping them launch successfully, so...

My idea is this. There is an astroid that has a chance of hitting the earth in 2036 called Apophis. It will be very close to the earth about 7 years earlier. Why not use this astroid, and just try to nudge it into orbit, I'm sure some really good simulations could figure out how to do it. What do you think?

This would be considerably easier with a comet-type object: just feed water/ammonia/methane solution to a big NTR. The comet is its own propellant tank, one might say....

I would also suggest going for something much smaller than Apophis, less than a 100 m long -- a fragment of a comet ??

> There are a few problems with just taking platinum.

Certainly, but I'm influenced by a lot of writings by people who've taken a long time and good hard looks at it. For every part of the process for which we don't know the best way, there are a dozen alternatives which would work well enough to carry it off. This quandary of ignorance of the best way is what's kept anybody from even trying. All that really matters is who gets there first, with anything at all which produces anything. "Perfect" is the enemy, while good enough" would do well enough.

>1. How are you going to filter it out?

We here shouldn't even go too far into describing the various ways. Suffice it to give a decent bibliography, and we're all (hopefully, eventually,) passingly familiar with the basics.

An excellent place to start:

permanent.com    Projects to Employ Resources of the Moon and Asteroids Near Earth in the Near Term

Plenty of good articles, from processes and techniques, to products and services, to a near-term private profitable mission.

As well, there are any number of reports and articles in professionally peer-reviewed journals, from Geology or mining to the AIAA and SSI which talk about the many & varied suggested processes.

>. That large of a chunck of platinum would seriously decrease the market value for it.

So? it'd still pay off the mission investment and give whoever flew the mission an immense technical lead in a huge, immensely profitable, completely open arena. In his book "Mining the Sky" John S. Lewis reported on a survey of asteroidal resources by J.Kargel of the USGS: the platinum group and precious metals alone from a 1km stony asteroid, if brought back to Earth markets would be worth ~$5trillion, though flooding the markets with so much at once would drop the value to only ~$300 billion.(wah...)

>... There is an astroid that has a chance of hitting the earth in 2036 called Apophis. It will be very close to the earth about 7 years earlier. Why not use this astroid, and just try to nudge it into orbit, I'm sure some really good simulations could figure out how to do it.

That's close to how it'd work. "Closeness" or simple physical proximity (at any point in time) don't matter so much. What matters is Delta-V needed to reach it, or complete total velocity change. This determines (for instance) how much of a mass placed in LEO could be payload for the destination, and how much is fuel to be burned off getting there. One that's going to come by really close could be hard to reach if the relative velocity change is large. Others that might not come as close any time soon might need a tiny fraction of the total Delta-V to get to it with a meaningful payload.

Any of many of what are variously termed "Earth-Crossers" might do very well; Many of these (perhaps most if not all) are easier to get to than our Moon (though travel times are longer), and have far FAR better resources once you get there. Many which spend most of their time very close to 1 AU (Earth orbit from the Sun), taking very closely 1 year, are obvious good picks, since they obviously have orbits that don't require much velocity change to get to. This means that a given booster (or several shots assembled in LEO, more likely) could place more payload there, and something like a solar thermal rocket using asteroidal ices as reaction mass could very well propel it home. Most likely, it'd take close to a decade to bring it back, and we'd have to send relief crews out with more tools and supplies. It'd do a couple of Earth swing-by and maybe a swing by of Venus, all the while gradually warping its trajectory so there's less and less relative velocity each time. The last Earth pass might send it out around the Moon, which drags the last velocity out if it so it's captured around Earth finally. There have been many very similar scenarios described for asteroids in a given class (First they are classified according to their orbital characteristics, then it's a matter of finding one of whatever type you want or varying your processing techniques to match the type).

another good site:

NEOfuel.com: Near Earth Object fuel (rockets that take energy from one source, to energize propellants from another)