No good deed, p.19
No Good Deed, page 19
part #4 of Destiny Saga Series
“I think they’re right. Maybe not about being naive, but you are very trusting sometimes. You have to think about what’s best for you and all the people counting on you. And it’s not like you’re hurting him. Sure, there’s the loyalty thing, but in return, you are also making sure he never gets sick again and magically gets to be in the best shape of his life.”
“I gotta say, that was a nice perk,” Carter said, patting his stomach, which had previously been on its way to being a mid-sized gut.
“I’m not happy about it …. but fine. I suppose you’ll do it when he visits later this week?”
“That was our plan.”
“Fine, I guess,” I said grumpily.
Neither one was much for small talk and on a decision being made they both excused themselves and headed out.
“It really bugs you, huh?” Emily said as she lowered herself into my lap.
“It does. Everyone seems to think I'm obstinate, silly or naive. But I lived for so long with no control over my future, passed from this home to that or thrown into a group home, having to watch the couple of things I could call my own, to keep them from getting stolen. I never got to make my own choices, everyone else was telling me what’s best for me. This isn’t quite the same, but still … I don’t think you should change someone's life without telling them.”
“I guess.”
“Look how you took the news when we told you. And that was just over the small manipulations my biology does without my control. And I don’t blame you for that reaction since even that is taking some of your own self-determination away.”
“I over-reacted,” she said, looking sad.
“No, your reaction was perfectly normal, and totally understandable. It’s why I took so long to tell you because I was worried about it. Now imagine if I’d put you through the change without asking you.”
“I mean, wouldn’t I be ok with it, because of what the change does?”
“Sure, but if that wasn’t a factor, or you were aware of what you would have felt before you were changed, outside of how you’d feel because of the change. No one else seems to get that.”
“You know they do Cas. You know your Mom. Zoe. Vicki and Tami. None of them are bad people. None of them would want to take away someone’s free choice. Hell, look at what Tami went through, and how her parents tried to take her and Judy’s choices away, trying to marry Judy off to that … monster. And yet, they all agree there are times you have to accept reality as it is. There are people out there who would hurt you. And even more, who’d want to put you in a cage, and study and exploit you if they knew what you could do.”
“Doesn’t make it better.”
“And does digging in your heels and complaining every time someone has to point out reality to you again make it any better? Does it make reality different?”
“No.”
“They why do you make everyone have to fight this battle with you every time. They aren’t arguing that you go and contaminate hospital's blood supplies, changing a huge number of people indiscriminately. They don’t want to take away people's free choice any more than you do and only suggest you change someone when it’s important.”
“Vicki didn’t,” I said.
Until that moment, it hadn’t occurred to me I was still a little angry at her for that.
“She admitted what she did was wrong, and feels bad about it. And yet, had she brought it to you and asked about each person she wanted to change, would you have said no? Would it have been the wrong decision?”
“I don’t know,” I said obstinately.
“Yes, you do. Stop digging in your heels.”
“Ok, no, probably not.”
“So don’t hold it over her. She did wrong, but out of a good place.”
“Ok,” I said, sheepishly.
“And stop making everyone fight you. They shouldn’t have to get a lecture for doing what they’re supposed to do. Listen to them, and decide to say yes or no. If no, then you can argue with them. But don’t fight with them when you know they’re right, just to relieve your own guilt. That’s not fair to them.”
“Yes, ma’am.”
“Good. Now, you don’t really have anything that can’t wait until tomorrow, and we don’t have to head home yet.”
I smiled at her as she leaned in towards me, thankful that I had her, and everyone else, to point out when I was foolish, among other things.
The company had taken to scheduling their presentations and demos on Saturdays when I had the chance to devote an entire day to them. I knew that was one thing I wanted to shift around when we moved to the new house and started homeschooling. A flexible school schedule would allow the company to operate a bit more normally, instead of regularly having to bend to my schedule.
Thankfully, all of our people and Aaron Baxter, the CEO of MilTech, were used to the way we did things now, and no one had a problem with it. Aaron had flown in on Thursday, to go over some changes he’d requested with Ronald’s team about the desalinization system, but that had to be pushed back, extending his trip through early the following week, thanks to a sudden and unexpected case of food poisoning.
Or at least, that’s what he declared his sudden illness was.
“Feeling better?” I asked, trying to remember what Emily said and push the guilt I felt away.
“Yeah. That was so weird. I travel quite a bit, eat all kinds of weird things when I do, and it never fazes me. My wife even jokes about my cast iron stomach. I’m never going to hear the end of this when I get home.”
“Tell her we’re sorry you had to extend your trip, and next time we’ll have someone taste test your food for you.”
“Ha. Right.”
“You’re seeing Ronald’s people on Monday, right?”
“Yeah. We’ve got the scaling down, but something about the ship is causing the bacteria you guys created to clean the water to die off. It didn’t happen in our trials, but when we put it in the first Navy ship, they last less than a week.”
“Do they have you set to meet with Joan?”
“Yep. Ronald offered to fly back and be here for the meeting, but he and the rest of the team all said when it came to the bacteria, she was the girl to talk to.”
“Let me know if there is anything you need from me.”
“I’m confident we can work it out. It’s so specific to Navy ships, it has to be something we can trace down and fix. What I really need from you is the next thing. Between the drone and the desalinization system, your company is starting to make a real name for yourselves for engineering products that work. With so many companies trying to make end to end systems, which more often than not turn into boondoggles, there’s a real need for a company that sees a specific problem, and fixes it.”
“Well, if you can keep getting us in the door, we’ll keep coming up with new ideas. Thanks for the NASA connection, by the way.”
“Sadly, that’s all it is. There is a little rivalry between departments, and we’d prefer not to ruffle any feathers. So we can’t shop your stuff directly to them. If, however, this battery and solar panel turns out to be what it sounds like, I can think of a few of our systems that might find a home for it on the military side.”
“I’m not sure the solar panels will be good for you guys. From what I’ve seen, they’re over-designed for what you need, since they’re targeted specifically at space-based operations.”
“I don’t know about the first part. There are a lot of military installations that have to rely only on diesel power and flown in fuel because solar power is just not effective enough. They’d have to install a field of panels to get enough power for their needs. If you have something that generates enough power, and a battery able to charge fast enough, and with enough storage, there will be a lot of interest in that. I will admit that a faster charging, safer and larger storage battery all by itself is very interesting.”
“Yeah, I think you’ll definitely be able to find applications for that. First, let’s go in and see what Douglas has to say.”
He nodded and headed into the conference room Douglas had set up in. I made my way around the room to the engineer, who was busy typing away on the small, boxy laptop he’d set up and connected to a large monitor.
We all sat and waited patiently as Douglas flipped through his notes, apparently oblivious to everything around him, mumbling occasionally. He’d been so wrapped up in his lab that I hadn’t seen him much over the last two months, but I had noticed an increasing eccentricity that was starting to bother me. I made a mental note to talk to Ted about him, to make sure we didn’t let him work himself into a self-destructive state. Based on what he’d told me when we first met about how things had gone bad for him at his last job, I guessed that it wasn’t completely unusual for him to go off the deep end. But I didn’t want him to go too far.
“We’re all here when you want to start,” I said out loud.
His head shot up, and it was like he’d just noticed we were in the room.
“Yes, of course,” he said, standing up. “We are getting closer to the end of the space shuttles, and everyone believes they’ll be phased out in the next ten years for something more modern. We’re less than a year away from the scheduled first pieces of the international space station getting launched. With the growth of new technologies here on earth we’re going to see more and more satellites go up. All these will require new forms of power. Much of the technology we currently use is almost ten years old, with only some advancements. That’s why I’ve been so determined to find new, long-term forms of power. I’ve been working on two ideas simultaneously, a better, more rugged solar panel capable of more efficient transfers of solar energy into usable power; and a lighter, more stable battery with both faster charge times, and longer storage capacity. I’ll start with the batteries.”
He clicked a small button in his hand, and the slide projector lit up, throwing a mass of fairly disorganized data up for everyone to see.
“As you are probably aware, NASA has been transitioning from the silver-zinc batteries and nickel-hydrogen used during the 70s and 80s to lithium-ion batteries over the last few years, although the nickel-hydrogen models are still getting a lot of use in satellites.”
Most of us probably weren’t aware, but Douglas was one of those geniuses who had difficulty understanding that not everyone thought the same way as he did.
“The problem with the lithium-ion batteries is they are more susceptible to temperature extremes, with both their storage and transfer capabilities being affected by both very high and very low-temperature environments. Environments commonly found in space. They’ve gotten around this for the time being with heavy shielding on the battery to keep a more constant temperature, but that adds to the weight ratio and limits the number any satellite or manned vehicle can carry.”
“I believe that, instead of liquid or polymer electrolytes that are most commonly used now, the future will be in a true solid state battery. Lithium-ion batteries were close, but clearly, it isn’t the answer, and I believe we are already close to hitting the maximum potential for that medium, regardless of its other stability drawbacks. Now, my former colleagues were fast to remind me that the big barrier to practical large capacity solid state batteries was the cost, and they aren’t wrong. While we’ve been able to make solid-state rechargeable batteries for some time, cost has always been the major limiting factor.”
“My goal has been to find a medium that would be both efficient and affordable, and I think I finally have. The answer is graphene. It’s an excellent conductor of thermal and electrical energy, it's chemically inert, and it's both flexible and extremely lightweight. We can start by using a graphene lithium-ion hybrid incorporated into the cathodes of a lithium-sulfur cell. While it isn’t what I expect the end goal to be, it will be a lighter, safer and more efficient battery and a good starting place.”
“As to the specifics …” he started to say before I held up a hand, stopping him.
He’d switched the screen to a dense run of numbers, graphs and math that was way too technical for this kind of meeting.
“I think we can hold off on the specifics and save that for another day.”
“Ohh, right.”
“I have a question,” Aaron said.
“Yes?”
“You said it was safer, how so?”
“Well, an inherent problem in batteries using a liquid medium is its instability. Even the most stable ones can be made to burn or explode if sufficient force or temperature variance is applied. A graphene-based solid-state battery would not be nearly as susceptible to violent reactions.”
“I’d be interested to see the tolerance levels of your new batteries.”
“We haven’t done field testing yet to get specific numbers. However, that is planned soon. It was made clear to me that there might be military applications and we needed to know how the solid state batteries handled impact damage and thermal extremes.”
“I’d be very interested to see that data when you have it.”
“I’ll make sure we send it over once we’ve run some more tests,” I said. “Let's move on to the Solar Panels.”
“Right. Current solar cells are limited by their very nature in the amount of energy they can capture, with single digit efficiency in most cases. We’ve come at the problem from a few directions, and have had several breakthroughs that can be used in conjunction.”
“One of the main problems in current solar cells, is they are limited to a thin slice of the light spectrum. We’ve developed a multi-cell panel that uses layers of solar cells together, with each layer pulling from a different range of the light spectrum. While this does up the cost of the solar panel, and would normally up the weight, barring something I’ll speak of in a moment, it ups the efficiency of our solar panel to just shy of forty percent, which is a significant step up from the current panels. The reason for the higher weight and greater cost is the need for intermediate bands of varying materials as it covers each range of the available light.”
“The second breakthrough we made is that, instead of using a silicon base for the cells, we’ve switched to a material called Perovskite. There’s actually more than one type of Perovskite, as that relates to both a natural mineral and synthetic compounds that have had their structure changed to mimic the crystalline structure of the naturally occurring Perovskite. While naturally occurring Perovskite isn’t effective for our purposes, we’ve developed a synthetic version using the same structure, that we can grow into a near defect-free micro-millimeter scale film. Now, the problem with this, as our friends in Sweden found out, was that the band gap was greater than what you get in Silicon, lowering its efficiency. But we can actually use that larger gap to our benefit when layering it with slightly different formulations of the crystal lattice made for different wavelengths, as I said before. The two advances go hand in hand, each benefiting from the other’s shortcomings to make a material that, while the end product is essentially the same weight as current models of solar panel, has a significantly higher efficiency in energy production.”
“And, of course, you can see the need for a battery able to take a faster charge when you have a higher efficiency solar panel pushing more energy into that battery. We still have a few kinks to work out, but our small-scale pro-types have been extremely encouraging.”
I’d been looking in on his work, but I hadn’t realized how far he’d come with the package of technologies as a whole. But he was right when seen together, these would be a pretty major breakthrough. Of course, we’d need some other people in his field to look at it if we were going to get this past either NASA or the military. I’d been looking over the technical notes in the packet Douglas had handed out, but even my genetic enhancements didn’t help me when I lacked the technical training to understand pretty much anything beyond the explanation Douglas had just given.
Still, it seemed pretty exciting, and hopefully, we’d get our meeting with NASA and convince them of the viability of our technology. It seemed like a good sign toward another windfall for the company, which we needed with the amount of money we were pouring into Next Step.
Thanks to the change, and the shared ideals we had before my coworkers were changed, we all agreed on where we were going with Next Step, but that didn’t mean we could ignore all fundamentals of business. If we wanted to get to the next level and take the non-profit beyond our local boards into a national or even international scope (which I believed long term would be needed to really make humanity ready for the taking the final leap in evolution), we needed more money. A lot more.
And if Douglas could deliver on half of what he was promising, this was a good step in that direction.
Chapter 13
Emily and I trudged in late Friday evening, after a very long week. Douglas’s presentation had lit a fire under Ted and Marcus; and Aaron Baxter, who’d extended his stay through yesterday. We’d spent the first two days after the presentation getting a first-hand look at both the new solar panels and the new battery.
“I gotta say, that was a nice perk,” Carter said, patting his stomach, which had previously been on its way to being a mid-sized gut.
“I’m not happy about it …. but fine. I suppose you’ll do it when he visits later this week?”
“That was our plan.”
“Fine, I guess,” I said grumpily.
Neither one was much for small talk and on a decision being made they both excused themselves and headed out.
“It really bugs you, huh?” Emily said as she lowered herself into my lap.
“It does. Everyone seems to think I'm obstinate, silly or naive. But I lived for so long with no control over my future, passed from this home to that or thrown into a group home, having to watch the couple of things I could call my own, to keep them from getting stolen. I never got to make my own choices, everyone else was telling me what’s best for me. This isn’t quite the same, but still … I don’t think you should change someone's life without telling them.”
“I guess.”
“Look how you took the news when we told you. And that was just over the small manipulations my biology does without my control. And I don’t blame you for that reaction since even that is taking some of your own self-determination away.”
“I over-reacted,” she said, looking sad.
“No, your reaction was perfectly normal, and totally understandable. It’s why I took so long to tell you because I was worried about it. Now imagine if I’d put you through the change without asking you.”
“I mean, wouldn’t I be ok with it, because of what the change does?”
“Sure, but if that wasn’t a factor, or you were aware of what you would have felt before you were changed, outside of how you’d feel because of the change. No one else seems to get that.”
“You know they do Cas. You know your Mom. Zoe. Vicki and Tami. None of them are bad people. None of them would want to take away someone’s free choice. Hell, look at what Tami went through, and how her parents tried to take her and Judy’s choices away, trying to marry Judy off to that … monster. And yet, they all agree there are times you have to accept reality as it is. There are people out there who would hurt you. And even more, who’d want to put you in a cage, and study and exploit you if they knew what you could do.”
“Doesn’t make it better.”
“And does digging in your heels and complaining every time someone has to point out reality to you again make it any better? Does it make reality different?”
“No.”
“They why do you make everyone have to fight this battle with you every time. They aren’t arguing that you go and contaminate hospital's blood supplies, changing a huge number of people indiscriminately. They don’t want to take away people's free choice any more than you do and only suggest you change someone when it’s important.”
“Vicki didn’t,” I said.
Until that moment, it hadn’t occurred to me I was still a little angry at her for that.
“She admitted what she did was wrong, and feels bad about it. And yet, had she brought it to you and asked about each person she wanted to change, would you have said no? Would it have been the wrong decision?”
“I don’t know,” I said obstinately.
“Yes, you do. Stop digging in your heels.”
“Ok, no, probably not.”
“So don’t hold it over her. She did wrong, but out of a good place.”
“Ok,” I said, sheepishly.
“And stop making everyone fight you. They shouldn’t have to get a lecture for doing what they’re supposed to do. Listen to them, and decide to say yes or no. If no, then you can argue with them. But don’t fight with them when you know they’re right, just to relieve your own guilt. That’s not fair to them.”
“Yes, ma’am.”
“Good. Now, you don’t really have anything that can’t wait until tomorrow, and we don’t have to head home yet.”
I smiled at her as she leaned in towards me, thankful that I had her, and everyone else, to point out when I was foolish, among other things.
The company had taken to scheduling their presentations and demos on Saturdays when I had the chance to devote an entire day to them. I knew that was one thing I wanted to shift around when we moved to the new house and started homeschooling. A flexible school schedule would allow the company to operate a bit more normally, instead of regularly having to bend to my schedule.
Thankfully, all of our people and Aaron Baxter, the CEO of MilTech, were used to the way we did things now, and no one had a problem with it. Aaron had flown in on Thursday, to go over some changes he’d requested with Ronald’s team about the desalinization system, but that had to be pushed back, extending his trip through early the following week, thanks to a sudden and unexpected case of food poisoning.
Or at least, that’s what he declared his sudden illness was.
“Feeling better?” I asked, trying to remember what Emily said and push the guilt I felt away.
“Yeah. That was so weird. I travel quite a bit, eat all kinds of weird things when I do, and it never fazes me. My wife even jokes about my cast iron stomach. I’m never going to hear the end of this when I get home.”
“Tell her we’re sorry you had to extend your trip, and next time we’ll have someone taste test your food for you.”
“Ha. Right.”
“You’re seeing Ronald’s people on Monday, right?”
“Yeah. We’ve got the scaling down, but something about the ship is causing the bacteria you guys created to clean the water to die off. It didn’t happen in our trials, but when we put it in the first Navy ship, they last less than a week.”
“Do they have you set to meet with Joan?”
“Yep. Ronald offered to fly back and be here for the meeting, but he and the rest of the team all said when it came to the bacteria, she was the girl to talk to.”
“Let me know if there is anything you need from me.”
“I’m confident we can work it out. It’s so specific to Navy ships, it has to be something we can trace down and fix. What I really need from you is the next thing. Between the drone and the desalinization system, your company is starting to make a real name for yourselves for engineering products that work. With so many companies trying to make end to end systems, which more often than not turn into boondoggles, there’s a real need for a company that sees a specific problem, and fixes it.”
“Well, if you can keep getting us in the door, we’ll keep coming up with new ideas. Thanks for the NASA connection, by the way.”
“Sadly, that’s all it is. There is a little rivalry between departments, and we’d prefer not to ruffle any feathers. So we can’t shop your stuff directly to them. If, however, this battery and solar panel turns out to be what it sounds like, I can think of a few of our systems that might find a home for it on the military side.”
“I’m not sure the solar panels will be good for you guys. From what I’ve seen, they’re over-designed for what you need, since they’re targeted specifically at space-based operations.”
“I don’t know about the first part. There are a lot of military installations that have to rely only on diesel power and flown in fuel because solar power is just not effective enough. They’d have to install a field of panels to get enough power for their needs. If you have something that generates enough power, and a battery able to charge fast enough, and with enough storage, there will be a lot of interest in that. I will admit that a faster charging, safer and larger storage battery all by itself is very interesting.”
“Yeah, I think you’ll definitely be able to find applications for that. First, let’s go in and see what Douglas has to say.”
He nodded and headed into the conference room Douglas had set up in. I made my way around the room to the engineer, who was busy typing away on the small, boxy laptop he’d set up and connected to a large monitor.
We all sat and waited patiently as Douglas flipped through his notes, apparently oblivious to everything around him, mumbling occasionally. He’d been so wrapped up in his lab that I hadn’t seen him much over the last two months, but I had noticed an increasing eccentricity that was starting to bother me. I made a mental note to talk to Ted about him, to make sure we didn’t let him work himself into a self-destructive state. Based on what he’d told me when we first met about how things had gone bad for him at his last job, I guessed that it wasn’t completely unusual for him to go off the deep end. But I didn’t want him to go too far.
“We’re all here when you want to start,” I said out loud.
His head shot up, and it was like he’d just noticed we were in the room.
“Yes, of course,” he said, standing up. “We are getting closer to the end of the space shuttles, and everyone believes they’ll be phased out in the next ten years for something more modern. We’re less than a year away from the scheduled first pieces of the international space station getting launched. With the growth of new technologies here on earth we’re going to see more and more satellites go up. All these will require new forms of power. Much of the technology we currently use is almost ten years old, with only some advancements. That’s why I’ve been so determined to find new, long-term forms of power. I’ve been working on two ideas simultaneously, a better, more rugged solar panel capable of more efficient transfers of solar energy into usable power; and a lighter, more stable battery with both faster charge times, and longer storage capacity. I’ll start with the batteries.”
He clicked a small button in his hand, and the slide projector lit up, throwing a mass of fairly disorganized data up for everyone to see.
“As you are probably aware, NASA has been transitioning from the silver-zinc batteries and nickel-hydrogen used during the 70s and 80s to lithium-ion batteries over the last few years, although the nickel-hydrogen models are still getting a lot of use in satellites.”
Most of us probably weren’t aware, but Douglas was one of those geniuses who had difficulty understanding that not everyone thought the same way as he did.
“The problem with the lithium-ion batteries is they are more susceptible to temperature extremes, with both their storage and transfer capabilities being affected by both very high and very low-temperature environments. Environments commonly found in space. They’ve gotten around this for the time being with heavy shielding on the battery to keep a more constant temperature, but that adds to the weight ratio and limits the number any satellite or manned vehicle can carry.”
“I believe that, instead of liquid or polymer electrolytes that are most commonly used now, the future will be in a true solid state battery. Lithium-ion batteries were close, but clearly, it isn’t the answer, and I believe we are already close to hitting the maximum potential for that medium, regardless of its other stability drawbacks. Now, my former colleagues were fast to remind me that the big barrier to practical large capacity solid state batteries was the cost, and they aren’t wrong. While we’ve been able to make solid-state rechargeable batteries for some time, cost has always been the major limiting factor.”
“My goal has been to find a medium that would be both efficient and affordable, and I think I finally have. The answer is graphene. It’s an excellent conductor of thermal and electrical energy, it's chemically inert, and it's both flexible and extremely lightweight. We can start by using a graphene lithium-ion hybrid incorporated into the cathodes of a lithium-sulfur cell. While it isn’t what I expect the end goal to be, it will be a lighter, safer and more efficient battery and a good starting place.”
“As to the specifics …” he started to say before I held up a hand, stopping him.
He’d switched the screen to a dense run of numbers, graphs and math that was way too technical for this kind of meeting.
“I think we can hold off on the specifics and save that for another day.”
“Ohh, right.”
“I have a question,” Aaron said.
“Yes?”
“You said it was safer, how so?”
“Well, an inherent problem in batteries using a liquid medium is its instability. Even the most stable ones can be made to burn or explode if sufficient force or temperature variance is applied. A graphene-based solid-state battery would not be nearly as susceptible to violent reactions.”
“I’d be interested to see the tolerance levels of your new batteries.”
“We haven’t done field testing yet to get specific numbers. However, that is planned soon. It was made clear to me that there might be military applications and we needed to know how the solid state batteries handled impact damage and thermal extremes.”
“I’d be very interested to see that data when you have it.”
“I’ll make sure we send it over once we’ve run some more tests,” I said. “Let's move on to the Solar Panels.”
“Right. Current solar cells are limited by their very nature in the amount of energy they can capture, with single digit efficiency in most cases. We’ve come at the problem from a few directions, and have had several breakthroughs that can be used in conjunction.”
“One of the main problems in current solar cells, is they are limited to a thin slice of the light spectrum. We’ve developed a multi-cell panel that uses layers of solar cells together, with each layer pulling from a different range of the light spectrum. While this does up the cost of the solar panel, and would normally up the weight, barring something I’ll speak of in a moment, it ups the efficiency of our solar panel to just shy of forty percent, which is a significant step up from the current panels. The reason for the higher weight and greater cost is the need for intermediate bands of varying materials as it covers each range of the available light.”
“The second breakthrough we made is that, instead of using a silicon base for the cells, we’ve switched to a material called Perovskite. There’s actually more than one type of Perovskite, as that relates to both a natural mineral and synthetic compounds that have had their structure changed to mimic the crystalline structure of the naturally occurring Perovskite. While naturally occurring Perovskite isn’t effective for our purposes, we’ve developed a synthetic version using the same structure, that we can grow into a near defect-free micro-millimeter scale film. Now, the problem with this, as our friends in Sweden found out, was that the band gap was greater than what you get in Silicon, lowering its efficiency. But we can actually use that larger gap to our benefit when layering it with slightly different formulations of the crystal lattice made for different wavelengths, as I said before. The two advances go hand in hand, each benefiting from the other’s shortcomings to make a material that, while the end product is essentially the same weight as current models of solar panel, has a significantly higher efficiency in energy production.”
“And, of course, you can see the need for a battery able to take a faster charge when you have a higher efficiency solar panel pushing more energy into that battery. We still have a few kinks to work out, but our small-scale pro-types have been extremely encouraging.”
I’d been looking in on his work, but I hadn’t realized how far he’d come with the package of technologies as a whole. But he was right when seen together, these would be a pretty major breakthrough. Of course, we’d need some other people in his field to look at it if we were going to get this past either NASA or the military. I’d been looking over the technical notes in the packet Douglas had handed out, but even my genetic enhancements didn’t help me when I lacked the technical training to understand pretty much anything beyond the explanation Douglas had just given.
Still, it seemed pretty exciting, and hopefully, we’d get our meeting with NASA and convince them of the viability of our technology. It seemed like a good sign toward another windfall for the company, which we needed with the amount of money we were pouring into Next Step.
Thanks to the change, and the shared ideals we had before my coworkers were changed, we all agreed on where we were going with Next Step, but that didn’t mean we could ignore all fundamentals of business. If we wanted to get to the next level and take the non-profit beyond our local boards into a national or even international scope (which I believed long term would be needed to really make humanity ready for the taking the final leap in evolution), we needed more money. A lot more.
And if Douglas could deliver on half of what he was promising, this was a good step in that direction.
Chapter 13
Emily and I trudged in late Friday evening, after a very long week. Douglas’s presentation had lit a fire under Ted and Marcus; and Aaron Baxter, who’d extended his stay through yesterday. We’d spent the first two days after the presentation getting a first-hand look at both the new solar panels and the new battery.
