We're all going on... LTA

Since the end of our coursework and final presentations there has been a steady stream of my fellow first year students leaving for exotic places and now it's my turn - off to CERN and Geneva on LTA.

An LTA (Long Term Attachment) is intended to get the students closer to our experiments as we try to make the transition from being clueless to useful in our adoptive teams - hopefully.

I joined LHCb and have already found it very useful being out here. CERN is the hub of activity for the (close to 60) institutions working on the project, whether based here or visiting, and I've had the oportunity to learn a lot in just a few short weeks.

Yesterday, I went underground to visit the experiment for the first, and maybe the last, time as it will be closed at the end of this week in preparation for the start-up of the collider. Many people have invested a lot of years and effort in the project and it was very impressive to see in all it's detail - even if it was difficult to reconcile the simplified diagrams that I knew with the mass of metal supports and cabling I saw.

As a UK-funded student, I'm living in a studio apartment arranged for me by STFC. It's in Geneva, close to the Old Town and about an hour's commute to the office at CERN. I recently got married and my wife has moved out here with me. She's finding plenty to do in the city, enjoying the relaxed atmosphere, shopping in outdoor markets and getting to grips with the local language.

French isn't essential here, with Geneva's large ex-pat community and English the common languge at CERN, but it helps to get the most out of what seems, so far, to be an interesting place to live.

In the control room

As we haven't had a post for a while, I thought I would write something. As I am sitting in the control room of the D Zero experiment, waiting for the beam to start up again, control room work seems like a good topic.

I will give a brief explanation of what the D Zero experiment is to begin with: I will try to keep the physics quite simple. D Zero is a colliding beam experiment at the Tevatron accelerator on the outskirts of Chicago. The Tevatron accelerates protons (hydrogen nuclei) and anti-protons to a high energy before colliding them. The collisions produce a large amount of energy, which takes the form of subatomic particles. These particles are then detected and analysed by the D Zero detector.

So far, so good. However, you have probably realised that the experiment doesn't work on its own: it needs a team of people to keep it running smoothly. A bit like the Marquess of Bute's wine, the D Zero experiment requires at least four people to be present at all times. These four are the CalMuo shifter (who looks after the calorimetry and the muon system), the Tracking shifter (who looks after the tracker), the DAQ shifter (who looks after data acquisition) and finally the captain, who co-ordinates everyone's efforts. I am trained as a DAQ shifter, so it's my job to make sure that the data is flowing properly.

The D Zero control room is a narrow rectangular room in the basement of the main D Zero building. There are long desks running along each side of the room, with numerous telephones, keyboards, computer mice, pens, wires and bells cluttering their surfaces: this is par for the course in most physics labs. My station is about halfway along the room, and above my desk loom various loudspeakers, whiteboards, soft toys, ringbinders, lists of telephone numbers and ancient post-it notes covered with faded handwriting. It is nine large computer monitors, however, which dominate the space above me. It is my job to watch these, in order to make sure that the experiment is collecting data as expected.

This isn't as difficult as it sounds; essentially I only really care about two screens: one which shows the rate of data flow (I begin to get worried if it shows zero), and one which shows any errors that are affecting the system. The rest will help me to identify any problems the system might have. Usually things can be fixed quite simply, but occasionally the problem is quite complicated. More often than not I will find that I need the help of another shifter to solve things (for example, if the calorimeter has an error, I need to work with the CalMuo shifter to fix it). If it is beyond us, it is time to call in the experts, but I have only had to do that once.

Things get a lot more complicated if someone needs to make repairs (usually to systems close to the detector, but not within it). When the accelerator is inactive, it is safe enough for teams to go into the collision hall to make repairs (there are stringent safety measures in place, of course). Because it is very rare for the accelerator to be off, everyone will come down to the control room at once to work on their particular system. These times require some co-ordination, as everyone needs the system changed in a particular way. Sometimes it can be hard to tell someone far more experienced than you that they have to wait for someone else, but usually someone more authoritative will help me out.

That is the busiest it gets though. Most of the time, the DAQ system is running well and doesn't need much attention. I have been on night shift (midnight to 8am) this week. This has the disadvantage of making me become nocturnal, but it is good in a way because I can chat with my friend in Hong Kong. I have also been playing "Limericks" with a friend in London to pass the time: we write a Limerick one line at a time, taking it turns to come up with the next line. The end results, to be frank, range from poor to absolutely terrible, but it helps pass the time.

Having worked in the control room, I now realise how much work it takes to run a major particle physics experiment. Before I started my PhD, I was under the impression that you turned the thing on, and it just ran, churning out great physics 24/7. I now realise how naive that was. But it makes me wonder about the LHC experiments: D Zero is tiny in comparison with them. They are planning to have hundreds of people operating these experiments at a time: how will they communicate with each other effectively? How can they organise themselves when a problem needs fixing? Do they have procedures to follow for any eventuality worked out in advance? And then there is the sheer size of the detector: when something breaks down, how do they intend to get to it to fix it? So, not only is the LHC a huge technical challenge, it is an enormous logistic and organisational challenge, and it will be interesting to see the solutions they come up with.

Whoops, that was a very long article... congratulations if you got this far! It is hard to say something exciting about something that is essentially quite boring, but at least it gives you an idea of some of the work that we have to do in particle physics.

The 2008 IoP Particle Physics Conference

Every year the great and the good of the UK HEP community (and a load of Ph.D. students) gather for the annual meeting of the particle physics group of the Institute of Physics. Over three days at the beginning of April the University of Lancaster played host to this year's conference.

The main programme was split into plenary sessions, which gave an overview of research in the field, and parallel sessions, which gave third year Ph.D. students (among others) a chance to present a talk about their research at a conference. The plenary sessions were great as they lifted your eyes up from your little corner of research to see something of the bigger picture (in the interests of shameful self-promotion of the Imperial HEP group, Prof. Jim Virdee opened the first plenary with a really interesting talk on the work that's been done to get the LHC detectors ready for LHC turn on, as well as some of the development that's been required to get to this stage with some really nice photos of how CMS has come together over the years) whilst the parallel sessions not only gave us third years a chance to present our work but also to see what everyone else has been up to (again, all the presentations that I saw by people from Imperial were excellent). There was also a poster session with a heavy T2K flavour, although there was a very interesting poster outlining the excellent work that's being done by the guys working on the Front End Test Stand...

As well as the academic program, an evening out in Lancaster and a conference dinner allowed for plenty of time to catch up with those who've been away on long term attachments (I think it was the first time that all of my year have been in the same place since our first year lectures!) as well as an opportunity to meet other people in the field. The night out in Lancaster saw a load of students do their best to take over a pizzeria, several very pleasant, very local pubs and (so I'm told) a closely fought drinking contest.

There was also an STFC Town Meeting during the conference, which given the recent funding problems, was a interesting introduction to physics politics. Never let it be said that physicists aren't passionate about what they do!

It was great to take some time out to be reminded of what we're all working towards, see what everyone's up to and catch up with people who haven't been around Imperial for a while but now it's back to the real world. I'm sure others can fill in any details that I've missed out...

Ouch, that hurts!

In spite of the somewhat appropriate title, this post is not about what STFC thinks about the LHCb experiment.


While I was searching for some material from my lecture at next week's Master Class I found the picture on the left. It's taken from the first episode of the the Big Bang Theory, a new sitcom now aired on Channel 4. For those who don't know it, it's basically like Friends, just with only nerds.

In the depicted scene (watch it) main character Sheldon supposedly explains some string theory to his neighbour Penny. A closer inspection shows that the white board has little to do with string theory. There's a simple calculation of the decay rate of the top quark to the bottom quark (assuming CKM unitarity) and then two Feynman diagrams of "FCNC" (flavour changing neutral current) top quark radiative decays. Finally there's a partial view of the CKM matrix. This scribble on this nerdy sociopath's white board could actually have been copied from my own white board (I mean, the one in my office). Ouch, that hurts!

The LHCb group at Imperial specialises in FCNC decays (actually of the b quark) as it is a very promising way of indirectly observing new particles too heavy to be accessed directly at a collider. They can hide in the loops shown on the picture (more). Many particles have been "discovered" indirectly this way before being actually produced directly at a collider. The race between direct and indirect will be on again when the LHC turns on.

Petition reaches 17,500 signatures. Thanks for your support!

Just a quick note to thank everyone who signed the online petition calling for government action on the STFC funding crisis. The petition has now closed and yielded an impressive 17,518 signatures. By the end it was one of the top 10 most supported petitions on the site. This is well beyond what any of us hoped for when we started out. Most encouraging was the depth of support from outside the affected fields, from the wider physics community to other areas of science and the general public. The petition attracted support from all levels of science, from the big names to undergraduates, many of whom organised a petition awareness day in physics departments nationwide.

The government's response so far hasn't been very different to the line they have been following throughout the debate "funding has broadly increased but tough decisions had to be made". However, the strength of support for the petition has clearly raised awareness of the consequences of the cuts both inside and outside of government. Hopefully this will help those negotiating to mitigate the damage.

Once again, thank you to everyone who supported the petition and spread the word. We have at the very least shown that science matters to more people than those holding the purse strings in Whitehall could have imagined!

Will

My Postgraduate Students' Physics Grandfather

Postgraduate advisor-advisee relationships often bring up discussions of physics genealogy -- for example the fact that students of my colleague Dave Wark, such as Ian, will share their physics grandfather with me.

Through all the variations such discussions can take, one common question is "what was my physics grandparent like?"

My advisor was Peter Fisher, and I was his first student, and there are lots of things I could say in response (and probably will), but it is not often that you can point to a clip from the Late Night with Conan O'Brien programme to answer the question....

So here he is in all his glory:
NBC Television(in the US), or, slightly more dodgily: A certain google-owned site

Sustainable Physics: SciBooNE's Recycling

Fermilab's daily newsletter, Fermilab Today, has recently published a nice article about SciBooNE. (Read it here!) The article discusses an interesting aspect of our experiment, which is that many of our detector components have been recycled from previous experiments. Our vertex detector (SciBar) and electromagnetic calorimeter (EC) both came to us from Japan where they were used very successfully in the K2K neutrino oscillation experiment. Actually, the EC originally was used in the CHORUS neutrino oscillation experiment at CERN, so it has been recycled twice---very good value for money! The third part of the detector is the muon range detector (MRD) which is made from iron and scintillators originally from the Fermilab hadron spectroscopy experiment E-605. (The photo above shows Joe cleaning some of the scintillators. [Photo courtesy of Fermilab Visual Media Services.]) We also used PMTs from a half dozen or more sources for the MRD. (The photo at left shows Hannah Newfield-Plunkett, an undergrad summer student from Cornell working on sorting out PMTs for the MRD.) We also used electronics for the readout of our PMTs and the data acquisition from the Fermilab equipment pool, PREP. This group at the lab is an enormously valuable resource and we really couldn't have built the experiment so quickly and inexpensively without them. To connect the recycled PMTs to the PREP electronics we also needed to find as many quality cables as possible because they are not cheap! We sorted through many thousands of old cables to find what we could use; they were stored in an old experimental hall which is now a kind of physics graveyard full of lots of old but still valuable and very useful equipment. The photo at right shows Michel Sorel and Joan Catala, both from Valencia University, sorting and testing cables. It was hot and dirty work!

The Fermilab Today article discusses all this work and more, and includes an audio interview with Joe. Check it out!

Petition to reverse recent funding cuts to Nuclear Physics, Particle Physics and Astronomy

Unfortunately my first post to this blog is motivated by difficult times for physics in the UK. As you will doubtless all be aware the UK funding body covering Astronomy, Nuclear and Particle Physics (STFC) has announced severe budgetary reductions affecting each of these fields. It is feared that grants may be cut by up to 25%. This being a particle physics blog I have no doubt that the readers are aware of the specific problems this has caused for our field. However, I wanted to bring home just how many people are affected by this across the broad spectrum of UK contributions to physics, from stellar observatories to power stations. If you share the feelings of many in the community that these changes simply can't go uncontested then please consider signing our petition on the 10 Downing Street website. Hopefully, if enough people sign up, in conjunction with the letter already sent to the government on behalf of the community, we will cause those responsible to think again before they seriously damage the future prospects for physics in the UK. Thanks for your support!

Exciting News from Fermilab

The new combined CDF/DZero Higgs limits were released last Friday. I would give you a URL to the results, except they haven't appeared on the Fermilab website yet.

This is because there is some even more exciting news than that. Here in the States, there is a television show called "NUMB3RS" (catchy title) about mathematicians and theoretical physicists who run around solving crimes. As a physicist who hasn't seen the show, this seems rather unlikely to me, as the last crime I solved was "who stole my orange juice?" Then again, I'm no theorist, so what would I know?

Anyway, according to 'Fermilab Today' (http://www.fnal.gov/pub/today/) a recent storyline involves one character (played by Peter MacNicol) considering leaving his exciting life of crime-fighting QFT in order to join the DZero experiment.

That's right, DZero.

The character gives his reasons for joining the experiment, hoping to discover the Higgs boson, concluding "What can be more spiritual?" I have to say, I can think of quite a few things that are more spiritual. In fact, I think I have had more spiritual moments in Bracknell - in BRACKNELL - than I have at DZero.

Don't get me wrong; the work here is rewarding, and I do see the mystery and the wonder of trying to work out why the universe is like it is. However, as the old saying goes, "The nearer the church, the further from God." Once you really get involved, you start to lose sight of the big picture; you get bogged down in all the little details. And besides, once Mr. MacNicol starts using ROOT, I can guarantee he'll feel a lot less spiritual.

Anyway, there are some fairly revealing quotes in the 'Fermilab Today' article. The first is from Darien Wood, the DZero spokesperson:

"We can always use more 'brilliant but socially awkward' physicists to help us find the Higgs"

I choose to paraphrase this as:

"We are so understaffed at DZero, we are willing to hire actors to pretend to be physicists"

Better yet is Alan Stone's reaction:

"In every episode, there is a crime. One can imagine the kind of story line they would need in order to film here (in Fermilab). There's just no possible positive spin."

To me, this seems like an oppurtunity for a great story, not a problem. Consider this: a starry-eyed theorist comes to DZero to find the Higgs. However, after a couple of weeks, he realises the frustrations due to the Object-Oriented graphics and analysis software he has to use. Eventually, he is drven mad, and flies to Switzerland to get revenge on the creator of the software. Then, the other mathematician-detectives come to CERN to investigate the grisly murder: you can just imagine the close up on the lead actor's face as he says: "Well, that's something to narrow this down... whoever did this certainly doesn't like ROOT."

The Rest of Last Week

Sorry for the silence, it has been a while since I had the time to sit down and try to satisfy Patrick's cravings....

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Tuesday

Get into College by 9am to do 1st Year Lab -- this is one of the 5 days this term that I have to come in so early!

These teaching labs can be as fun or as boring as the students want to make them, but I am impressed by them more often than not, and this group is exceptionally good, and right now they are discussing amongst each other about the experiment and hardly need my help.

Having said that, when asked to measure the index of refraction of a mystery liquid, one of the pairs of students tell me that they got 1.2 -- since a liquid with an index of refraction of 1.2 would be a rather special thing, I ask them what their error on that was, hoping for something like 0.1. Their answer: "we haven't done that yet!"

Over lunch, have a quick look at the previews for tonight's match. We won for the first time in ages on Saturday, and looking forward to it tonight. Our opponents are one of the few teams below us in the division, so we've got to win!

A couple of more tutorials from 2pm. The students will soon be writing an essay on a topic of their choice, so we go through some tips I have on making their writing more interesting. This may come across as profoundly ironic to readers of this blog.

From 4pm, we have our regular T2K Imperial group meeting. This time of year is fun because we usually have a few 4th year students doing their projects in our group, and we treat them as full group members, which means that they give regular reports on their progress like everyone else. Patrick and Paul are working on two separate projects, one on T2K nd280 physics and one on some detailed characteristics of some novel photosensors, and we hope that by February, they'll have answers to a some questions that we don't know yet.

You would have to ask the students themselves if they think it is just as fun for them....

Morgan and Joe are dialling in from Chicago again, which is good because it makes us feel good about being in London over the winter.

The group meetings sometimes run quite late, because they are the best forum for proper discussion (ie grillings), where we sort out misconceptions and disagreement. Today however, I was able to adjourn the meeting quite early, which gives me time to travel down to the stadium and stuff down a nice big serving of jerk pork, before seeing us come back from behind to win.

Now I think about it, this is the first time I've seen us win this season....

Wednesday

Today is one of those special days during the week when I have hardly anything scheduled except time for getting some research done. There is just one meeting, but apart from that, I have hours to get through my todo list at my leisure.

...except something unexpected crops up, and I lose a few hours doing things far removed from unravelling the mysteries of the neutrino sector of our model of the universe. I even had to excuse myself from the one meeting.

I wanted to go home early to pack my bags, or rather my single carry-on back of less than 10kg, but end up returning home at only about midnight. Which sounds fine except that I have to leave for the airport at 4am....


Thursday

This is the day of the second trip mentioned in a previous comment. The flight leaves at 7.30 from Stansted, so I get up at 3 and take the bus up to Liverpool Street Station at 4 and then the Stansted Express.

The flight is not bad at all considering I paid 6 pounds for it, and once we arrive, it only takes about a minute between going down the stairway and walking out of customs into the sun and warmth of Valencia.

The meeting is hosted by the Instituto de Fisica Corpuscular of the University of Valencia, and we immediately sit down for lunch which includes tortillas (omelettes), Iberico ham, all sorts of other yummy things, and beer. Having only slept a few hours, and being the sort of person I am, I refrain from touching the golden stuff.

I had scheduled the lunch at 11.30 so that we could have a long afternoon session, but the consequence of that was that the cafeteria had to open early specially for us, sorry!

There are about 15 people present at Valencia, and a similar number dialling in via a teleconference service, from across Europe and North America. We have to juggle the needs of everyone according to their time zones, which often can result in a total mess, but today, after some initial glitches, things go pretty smoothly. The fact that we are having arguments (constructive ones, mind you) over the conferencing system indicates that it is working well. Most of our meetings are teleconference only, but having a core face-to-face location makes things so much more productive.

This meeting is about making sure the software for the T2K nd280 detector is ready to real physics work. The software is the result of the effort of many people across the world, and encapsulates our knowledge of our experiment, so it is a big job to get it done, and to get it done right.

One of the most important items I put in the agenda was "Hot Chocolate and Churros", but for all the IFIC's hospitality, it does seem that was asking for too much!

Instead of specifying an end time for the afternoon session, I thought the best way to get the most out of the day was to continue until a Spanish person told us it was time for dinner. That duly happened at 8.30pm, so we pack up and trek across to the old town, where we indulge in loads of paella, a local speciality. I personally like Paella Valenciana, with chicken and rabbit meat, but today we are having seafood and vegetable paella. Positively yummy.

After dinner most of the group hit the bars and dives for some heroics on the town, but I, being the sort of person that I am, head straight for my hotel for a quiet night's sleep....

Friday

I get up early and walk to the tram stop well in time to make it for the start of the second day at 9.30am, but I wait and wait and no tram comes.

When one finally does arrive, I find that I am on the same tram as all the students who only went to bed just a few hours earlier, and I reschedule the start of the meeting to 10am.

Today's lunch is Paella Valenciana, so I have two platefulls. Yummy.

We continue till about 6.30pm, sorting out what we can do and can't do over the next several weeks and months. We have our work cut out for us, but it will all be worth it in the end!

This is when my week officially ends....

This Week

Since there hasn't been much activity on the blog for a while, I have decided to blog about my week. I hope this will serve as a warning to my colleagues that they should update the blog reasonably frequently!

Anyway, for a detailed account of a "typical" week for a lecturer at Imperial HEP, watch this space (or avoid it, as the case may be...).

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One of the founding principles of this blog was not to fill it with self-indulgent spewings, but my hand has been forced -- beware:

Sunday

Start the week in a good mood, a big chorizo omelette breakfast in the Portuguese area up the road from me.

I come in after lunchtime, a bit later than I wanted. It seems about a third of the offices down my corridor are occupied. Weekends are good because there is no teaching and fewer people come knocking on my door, although today a certain DZero physicist did come in asking to be rescued because he had locked himself out of his office....

The central event this coming week is a face-to-face meeting (as opposed to the usual teleconferences) that I have convened for the T2K experiment near detector physics software group. Today I am sending out a draft agenda for the meeting. We only have two days but a lot of work to get done, and because some people are dialling who can't travel this week from a variety of time zones, it is going to be quite difficult to arrange the sessions to suit everyone.

I also send out a reminder for some people to submit their sections of a report we are writing. Then I make a mental note to myself that I'd better get on with writing the bit that I am supposed to be responsible for.

I look through the laboratory notebooks of a dozen or so first year undergraduate students. Keeping a decent logbook of everything you do is an important part of a physicist's training, and while some are already amazingly good -- legible and detailed with lots of interesting jottings -- there are one or two where I can't figure what they were thinking. Some harsh words are in order, but then I remind myself about what I was like as a first year student, and hold back a bit....

Before catching the bus home, I continue drafting some recommendation letters that I am writing for a student. There are about 10 undergraduates that I have been tutoring who are graduating this year, so I know I'll be doing a lot of letter writing over the next several months! As far as so-called administrative tasks go, letter writing is something that I feel a sense of responsibility over -- if my wording is somehow off and the letter conveys the wrong impression, it could have a lasting effect on a person's life. One of my students graduated last year and is now studying at one of the very top Institutes in the US, diametrically opposite the one I went to (geographically), which isn't bad, although whether he actually needed any help from me to get in is another matter....


Monday

Get up early, work a bit on the report over a nice cup of tea.

Second year undergraduate tutorials at 11am, mostly about quantum mechanics. Today I am going through the postulates of QM with them, and how the physics concepts like states and measurements are linked to the mathematics, letting you calculate and predict things. In just a few months' time, they'll be able to calculate the behaviour of hydrogen atoms in laser beams and the like. In a couple of years, the lucky ones will have moved on to calculating what happens in particle interactions at a collider, or neutrino interactions with matter!

At Imperial Physics, we do tutorials in groups of about four students. I think this is about right, because for most issues that the students have, they can bounce ideas off each other and work things out on the board and come to the right conclusion, with just a bit of guidance. Any more and I think some students would find it more difficult to participate fully, any fewer and there wouldn't be the student interactions which can work so well.

Have lunch with Dave Wark at the Senior Common Room, where we are joined by a physicist from a different group. The conversation centres on the world economy, the price of CD players, and how much the space station costs.

1st year lab at 2pm. They are measuring the speed of light using a tabletop setup. My job is to wander about, saying "think about the errors, think about the errors...."

Later in the day, I receive some emails from a couple of personal tutees, asking to have chats with me. I sense some more letter writing coming my way. This week is full so I schedule sessions for next week.

In the evening, Dave, the students Ian and Francois and I attend a lecture from the IgNobel people, where some "improbable" research at Imperial are presented. It is good fun, and you can see how introducing the "quirkiest" science is a great way of showing how the scientific method works and why we all do it. The research on camel hydration and brain temperatures left a lasting impression on me.

Afterwards we end up having an extended chat with a certain prominent science journalist. Good science journalism is of course crucial for the public to understand the importance of basic research. We agree that having a good "rubbish-o-meter" is the most important thing for a journalist (although "rubbish" may not have been the exact word that was used). She also writes a lot of obituaries for scientists, and that seems to be bothering Dave somehow....

Travel

I promised Yoshi in front of the entire group that I would make a post to the Blog, so true to my word, here is a first effort.
As you are no doubt aware, the possibilities to conduct a HEP experiment in the UK are nowadays rather limited. Much of the group is involved in experiments which take place overseas. Ideally we send people overseas for an extended period of time, a Long Term Attachment (LTA), which allows them to minimize the effects of travel, and maximize their ability to participate in the experiment they are working on. This arrangment works well, but for some of us it is necessary to be both here and at the experiment at the same time. In some ways this gives us the best of both worlds, but it has the nasty side effect of requiring a lot of travel.
A typical morning for me at Imperial might actually begin at 5am in Geneva. There is flight that leaves before 7am and arrives in London so that I can be at Imperial by 9am. I can say with confidence that there is absolutely no glamour in the "jet-set" lifestyle. But honestly this is a pretty easy commute. 10 years ago when we were setting up the BaBar experiment at SLAC (near San Francisco) I regularly flew between California and London, a commute which can test your endurance, and involved regular resetting of my internal time-zone.
Members of the group are currently working overseas on experiments at Fermilab (near Chicago), SLAC (near San Francisco), CERN (near Geneva), and in Japan. There are some ways in which technology has made it possible to avoid some of the travel. Participating in meetings via telephone/video/internet conference is now much more practical. There are several systems where presentations are posted to a web site, and so particpants can see all the material on their local machines, and then follow and participate in the discussions via the conference call. This works reasonably well for many working meetings, and is used by most members of the group. There are difficulties with this as well due to the spherical nature of the earth, meetings which take place in the evening in Japan are in the morning here, meetings in the evening here are in the morning in California, and so there is actually a rather small window of "working hours" where these conferences can take place without causing one side or another to come in very early, or stay very late. Some times, however, it is just necessary to travel. It isn't yet possible to plug in cables on the telephone, and sometimes you just need to be in the same room as your colleagues or your detector to work through a problem.
I've picked out some of the difficulties of the travel, but it also comes with a lot of benefits. As well as getting to work in some very nice places, one gets the opportunity to work with colleagues from around the world. These interactions are extremely valuable in broadening our work methods and our ways of approaching various problems.
That's it for now, I've got a plane to catch...

Starting Out

It's the start of a new academic year and, for me, it's back in from the cold of the "real world". After 4 years working as a Market Analyst I'm having a great time settling in to a new life as a Postgraduate Student in the Imperial College HEP group. I dare not whisper "PhD Student" yet, as we have to get past year 1 first...

I'm one of 12 new students this year, which is apparently the highest number since 197_. We're an interesting mix of people, with a half-dozen countries represented. In the first term the focus for us is on study, which is especially useful for someone like me who's undergraduate notes are already browning with age. We have started a handful of courses so far, taught by members of the HEP group, and are also free to attend any interesting undergraduate courses; which most of us have been taking advantage of, when our schedules allow.

By the end of November, we're expecting to have been assigned to the projects that will take us through the full 4 years. There’s been a lot of discussion among us students already and a bit of early bribery from some of the staff – thank you for the beers all of you. We’re expecting some more formal presentations over the next few weeks and then we should have a better idea about who we should be buying the beers for.

Because there are so many of us this year, we're not all in the same office but being kept more-or-less together has been a great way to form some promising friendships already. I'd like to invite any of them who reads this to add a comment so we can hopefully give anyone thinking of starting here next year a good idea about what to expect.

How fit is your collaboration?

Social events are an important part of about any scientific conference. Some argue they are even the most important part of the programme as they allow people to get together and discuss in a more relaxed atmosphere than the three minutes question time after the talks. Usually one half-day is reserved for some kind of excursion.

It was no different at the LHCb collaboration week in Saint Nectaire a month ago. On Wednesday afternoon we could choose between (a) a guided tour of six roman churches, (b) a guided visit of a volcano, or (c) climb the Puy-the-Dôme. From the 200 participants, 130 chose option (c), a 500 m climb of the landmark mountain next to Clermont-Ferrand. The organizers counted 3h30 for the hike and told us to hurry up if we didn't want to miss the bus. Actually everybody had reached the summit in much less than two hours. Some of us even made a detour to climb the Puy de Pariou, a small volcano with a nice crater (straight under the blue paraglider on the picture above). We were all quite impressed by how fit the collaboration is! Nobody expected that so many people would choose to climb a mountain between two meetings.

We also elected a new spokesman for the LHCb experiment. After more than 10 years in charge of the design and construction of the LHCb experiment, Tatsuya Nakada will step down as spokesman next year. The new spokesman-elect is Andrey Golutvin, director of ITEP Moscow and co-convener with Ulrik of the rare decays working group. A new era is starting, with a new spokesman and hopefully real data very soon.

HEP vs SPAT football match

It was billed as the battle to see who held sway over football bragging rights in the Physics department. HEP vs. SPAT. There were many volunteers on both sides. The mouth watering clash was six weeks in the making and took place on Thursday last week - 04/10/07...or should have. Thanks to Murphy's law it did not. The SPAT footballing maestros couldn't put their money where their mouth was and pulled out at the worst possible time - the morning of the match. Apparently, a sweeping bout of freshers flu was to blame! Turning disappointment into action, HEP (Ajit, Aaron, Onuora, Tom) decided to go ahead and play. Fortunately, Deltadot (Wen, Mark, Gary, Dave, Reese) was at hand to oblige.



The match, which took place at Hyde Park, ended 7-5 in favour of Deltadot. It was evenly balanced for the first fifteen minutes as both sides probed for an opening. Deltadot finally made the extra-man count to get on the score sheet. The game was evenly poised at 2-1 in favour of Deltadot with both sides missing a few gilt-edged chances. At 7-4 they seemed to be running away with it but HEP pegged them back with uncompromising defence and a goal at the death.

Good job lads!

T2K Horn Testing

I've been in Japan for the the past week, working on horn tests for T2K's third neutrino horn at KEK (pictured at right). The horns are devices that create strong magnetic fields which are used to focus charged pions into a long decay region where they, not surprisingly, decay into neutrinos. T2K will employ three horns in series to create the world's most powerful neutrino beam. Each horn itself is essentially two concentric aluminium [sic] cylinders which carry
a high electric current. Between the two cylinders, a powerful magnetic field is created and that bends the paths of any charged particles passing through.

The horns must generate strong magnetic fields but they run in a high radiation environment so they must be very robust. The T2K horns will operate with an electric current of 320 kA. For this much current, the power is distributed along large aluminium striplines (pictured below) which feed the horns.



The work this week was mainly to test the structural stability of the newly constructed third horn. The first horn was tested extensively earlier this year. The currents and fields created by the horns are so strong that they exert tremendous mechanical stresses on the devices and must be tested extensively before being deployed in their final locations in the beamline. The mechanical forces are so strong that the horns emit an incredibly loud bang each time they are pulsed; it sounds as if someone were banging them with a sledgehammer. Given the amount of energy being pulsed through the horns when they operate, that's not a bad analogy.

The tests themselves are simple enough: we just run the horns in the same way that we will in the experiment. The horn experts spent the past few weeks preparing for the tests by setting up the DAQ and monitoring tools so that non-experts (like me) could come in and watch to make sure nothing went wrong. The plan was to test the horns for 10.5 hours per day in three shifts of 3.5 hours each. We didn't test the horn overnight because the noise is so loud you can hear it off-site, and it's important to keep good relations with the community surrounding the lab. The only hitch has been the extreme heat that Japan has been experiencing this summer. The building where the horns were tested does not have air conditioning, and if the temperature inside went over 37 C we halted operation until it went back down below that threshold. We lost three afternoons to the heat last week! Nevertheless it was a successful week: the horns were pulsed over 44,000 times last week while I was there.

Ask me... I'm an expert

Remember the posts about the Big Bang exhibition at the Science Museum? Well, if you haven't seen it yet hurry up. It's on until the 7th of October, after which it will be replaced by [not allowed to tell ;-) ].

To add a little more action to the displays the Science Museum set up a little interactive event last week where they would show some kit and have a couple of scientists explaining it. The plan was to have a cosmic ray detector and some Geiger counters. We provided the latter but they were quite useless in the end as nobody was able to bring anything even remotely radioactive to make them tick. So we concentrated on cosmic rays, which was not a bad idea anyway. Our colleagues from Bristol provided a scintillator and a small spark chamber, definitively the star of the show. It's much smaller than the huge one Imperial and RAL built long ago and we could not get to work again. At least the Bristol chamber worked nicely. Don't know if there's a lesson here...

It was a lot of fun explaining cosmic muons to the general public (although the general public found at the Science Museum is a quite biased sample) and answering the most unexpected questions. How do we know they are muons? Where do the cosmic rays come from? How does it work? Could they have triggered life? What's this black thing? (the trigger). Wouldn't the muons have all decayed before reaching the ground? (This guy knew more than expected). How do you get a satellite on orbit? Hmmm, somewhat unrelated, but I had a tag saying "asking me... I'm an expert" so I just had to know.

Many thanks to the Bristol guys David, Clare, Ben and John for providing the nice kit and to Will and Tom for representing Imperial.

Finally I agree with Gavin: we should try to build a similar chamber and display it on level 5.

A Week in the North of England

We just got back from the biennial High Energy Physics conference held by the European Physical Society, this year in "The North of England, at Manchester".
The poster for the conference was a nice Lowryesque image of the city, with matchstick physicists heading for the brand new Bridgewater Hall, where the main sessions were held.

As usual with conferences, the days were filled with rather intense schedules of parallel and plenary talks, while most evenings were kept aside for social events, where attendees discuss the day's talks with their colleagues and new people they have met, and which are usually accompanied by refreshments to help the discussions along (including the Beer Tasting that was organised by Lee Thompson of Sheffield, which I certainly appreciated).

Most of these social events involved Dave Wark, our colleague on T2K at Imperial, in his role as the chair of High Energy Physics at the EPS, standing up and trying to tell jokes in a room seemingly chosen such that no one was able to hear him. The first of these was at the very impressive Manchester Town Hall, where it was clear to see (but not hear) that the Lord Mayor was enjoying Dave's speech very much indeed. I later learnt that he was rattling off the names of physicists from Manchester who had made Nobel Prize-winning contributions to our field. This list included the likes of Rutherford, Chadwick, Blackett, Bethe and several more, which is actually quite amazing.

On the Sunday off, Dave and I checked out "The Lowry" gallery, where many of LS Lowry's works are on display, along with artefacts from life in the Industrial North, with contrasting images expressed mainly through paintings, photographs, Coronation Street (the TV soap for our international readership), and Labour Party pamphlets. It is a great day out and puts Manchester as we see it now in proper perspective. It was curious to note, however, that the conference poster was for some reason not based on Lowry's Manchester as depicted in paintings such as "The Lake".

Coming out of "The Lowry", one is confronted by "The Lowry Outlet Mall". Perhaps celebrating Manchester's place as the centre of consumer culture in the North would have pleased the artist. Then again perhaps not.

One of the centrepieces of this conference is the presentation of the EPS Prizes. This year the main prize went to Makoto Kobayashi and Toshihide Maskawa, of "Kobayashi-Maskawa Theory" fame, and the K and M in the "CKM Matrix", the "C" being Nicola Cabibbo. Their paper in 1973 showed that symmetry violations that had been seen in nature, but difficult to incorporate into the understanding of physics at the time, could be described if 6 quarks existed, which were linked together through a 3 by 3 component matrix. This was at a time when the existence of quarks themselves, and whether there were 3 or 4, was a point of contention (though I would like to state that was quite a bit before my time!).

I'll leave it to our colleagues on BaBar and LHCb and DZero to remind the world of the significance of that particular Matrix....

Kobayashi was able to make it here and gave a presentation in acceptance of the prize. Although both K & M were at Kyoto University when they wrote their seminal paper, he clearly wanted to demonstrate that the work was a result of the Nagoya tradition of theoretical and experimental physics, just like the earlier MNS (Maki-Nakagawa-Sakata) matrix that we have been probing in our neutrino experiments.

Later in the week I bumped into one of my 4th year project supervisors at Kyoto, Prof Masaike, who I hadn't seen for, well, shall we just say a very very long time. He is close to Prof Maskawa (whose Quantum Field Theory course I remember sitting in), and over a pint of some nice dark Mild, he let me know that not only was Maskawa unable to make it to this particular conference, but he has actually never left the country ever in his life. Perhaps it will take even more than the EPS prize to persuade him to travel outside of Japan....

What you missed at the Staff Party

Wednesday all Imperial Staff were invited to the Centenary Staff Party, basically a big garden party on Queen's and Prince's Lawns. If you didn't attend, here's what you missed:

• All shop and restaurant staff dressed in Edwardian style.
  
• A chance to see the inside of the giant marquee on Queen's lawn. Rumors that it's the largest marquee in the world are definitively wrong. It's not even the largest in the borough, as some websites claim the world's largest marquee was used at the Chelsea Garden show.
  
• The Fab Beatles, a Beatles cover band specialised in the early years up to and including Help! but without Yesterday. I learned that to make a good Beatles cover band you need four guys including one left-handed, one who can play the guitar, one who hardly can play drums and one wearing glasses, all of them with the appropriate hairdo. The latter John-guy didn't follow the rule and had anachronistic long hair. But he was clearly the best approximation among the four.
  
• Fake That, another tribute band. Honestly, I couldn't really judge how good they are as I don't really know what they are supposed to be faking... Ask Yoshi, he seemed to be much more knowledgeable. There's a picture of the band above, but my autofocus seemed more interested by the balloon in front of the stage.
  
• And of course, the rector's dance. Luckily youtube saved it for the posterity.

Overall it was a nice party. College should make it annual! I don't want to wait 100 years for the next one!

Royal Visit

I had a unique experience for an American this week: seeing the Queen in person. She visited the College as part of the Centenary events, and had a quite a busy day from what I've read---but I guess that's always the case when she visits someplace. In the picture I've posted, she is walking through Upper Dalby Court here in the South Ken campus with the Rector, Sir Richard Sykes, having just dedicated the new Biomedical Engineering Institute and on her way to congratulate the College on 100 years of greatness. I was one of the "well wishers" who gathered to greet her en route. I'll confess that it was fun because I have always been a fan of pomp and circumstance, but I was disappointed that she didn't have time to chat because I had honed my elevator pitch about experimental particle physics and was quite prepared to make her love our field. Another time, perhaps.

To What End?

Hello everyone, I've been thinking about what to post and looking at all the blog entries in the Imperial College HEP blog spot, it is obvious that the majority deal directly with the various HEP experiments carried out here at Imperial or with the HEP group itself. So I've decided to go the other direction - write on stuff that is indirectly related to HEP.

Of the long list of questions that I find interesting to mull over every now and again, I guess one of the more important ones would be my desire to understand the role of HEP in contributing to the well-being of society. Think about it; of what use is HEP to the day-to-day dynamics of society. When I leave the office and am out with my friends how does HEP contribute to my life? If I'm out shopping, sightseeing maybe, how does HEP contribute? Or if I'm simply spending time with family how does HEP contribute to how I interact with them? Another way to look at it would be to ask: how does HEP contribute to my understanding of myself as an independent entity with a role in society?

These questions are not asking about the opportunities that arise from working in a HEP environment such as travelling, attending conferences and the like. They are asking about the intrinsic purpose of HEP with respect to humanity's existence in the sea of creation. To answer, perhaps a good starting point would be to take a step back and try to figure out why HEP and indeed all institutions of knowledge became necessary in the first place.

The first important clue is that every human endeavour, be it Science, Technology, The Arts, Economics or Religion has as its original goal the desire to study and understand the human being, the environment or the interaction between the two, where the environment in this case refers to all physical creation that is separate from the human being, i.e. the earth, the universe, and so on.

The second clue is that a system, any natural system, will be composed of elements that are each unique. The uniqueness of each element automatically generates the property of diversity within the system. In a system that is composed of sentient, self-aware elements, for example human beings, this leads to the phenomena of demand under which each element recognizes its deficiencies relative to the strengths of the other elements within the system and reacts to this by striving to address the balance.

The third clue is that the act of striving is a natural action that is induced and controlled by the principle of evolution that permeates all creation.

And so combining clues 1, 2 and 3, we are left with the conclusion that HEP and indeed any other human endeavour exists for no other reason than to serve the phenomena of demand which is itself a natural attribute that is inherent within any system in creation. This is a sweeping statement. And it is one that raises a lot questions foremost of which are: What is demand? What is evolution? How are they defined and what are their origins? The answers to these questions become of even greater importance in the face of the realisation that there is still much that is unknown by the various institutions of knowledge in their attempts to plumb the depths of the mysteries of man and the environment. Society today is a paradox. It is the epitome of good health - evidenced by the immense technological progress over the last couple of decades, the space age, ground breaking discoveries, etc and yet it appears on the brink of imploding - evidenced by poverty, war and consumerism. How did it all go wrong?

The list of questions can be endless, but inevitably they are all tied in to a common theme - the origin, purpose and future of the human being in the cosmos. As it is today, humanity finds herself in real danger of completely missing the big picture as she concentrates on moving further and further down the path of the individual disciplines in search of the Holy Grail. What should be done to correct this imbalance?

I'll stop at this point and open the floor to comments. I must point out that this blog is somewhat of a teaser. All the questions have answers, no surprise there! However, the point of this blog is to emphasise the fact that HEP and indeed any other discipline in any of the institutions of knowledge exists only to serve demand. And so perhaps the key for maximizing the potential of HEP would depend on understanding fully what demand entails.

The Bubble Chamber Football Tournament (including results)

This year's Bubble Chamber Football Tournament is on Saturday 23 June, at UCL's training grounds somewhere in North London.

The tournament was inaugurated decades ago by university groups in the UK who worked with Bubble Chambers, the main tool used in particle physics experimentation in the '60s and '70s, which provided the most stunning images of particle interactions.


The participants are, allegedly:

UCL x2
Bristol
Imperial
Manchester
Birmingham
Cambridge
Exiles?
Misfits?

You could say it is a bit like the Ivy League, except it is proper football and Bubble Chambers are a lot cooler than Ivy.

Neither of the two American universities that I have been associated with in the past, MIT and Stanford, are in the Ivy League, and definitely had a long history of working with Bubble Chambers.

I am sure that if they would like to send some teams over to the UK next year, they would be welcome to join the Bubble Chamber group of universities!

The Imperial team has been practising for the last few months, every week on Wednesdays. I can't say much more here, because our formation and free kick strategies are top secret, but I'll just say that with his dazzling white boots, smart kit, and incredible pace, you might have thought that Wayne Andrews was playing for us on the wing. Just don't tell the other teams that he (our winger, I mean) is a donkey!

---

The Imperial College High Energy Physics Football Team

Saturday was a great day out, with all the teams arriving more-or-less on time and the weather holding out till just before the final kick of the afternoon.

We started out losing 1-0 to Bristol in the first match of the group stage, but since this was the first time the Imperial team had actually played together ("practice sessions" notwithstanding), we weren't too disappointed. The Bristol players had clearly met the rest of their team before Saturday.

The highlight of the day was the Central London Derby, our second match, which ended

Imperial College London 6 - 0 UCL

Personally, I think it was my tight man-marking of their right winger (and goalie) "J.B." which ensured our clean sheet.

We then went on to beat Manchester 2 - 0, and at the end of group stage the table ended up like this:

                    Pts GD 
          Imperial   6  +7 
          Bristol    6  +2 
          Manchester 6  +1 
          UCL        0  -10

After this some more matches were played, Birmingham won, and Cambridge (not UCL) got the wooden spoon, known (for purely historical reasons as far as I could tell) The Troll.

Next year's tournament will be at Manchester, to which there are cheap direct flights from Boston....

SciBooNE or: How I learned to stop worrying and love the MRD

After many months of cajoling, I feel that I should write a blog entry on what I have been doing whilst living out here in the USA other than enjoying their fine beers, moderately sized meals and small economic vehicles.

I suppose I should first explain how I came to work on SciBooNE in the first place. In January 2006 I joined the T2K group my supervisor, Morgan Wascko, a new lecturer joining the group. As it turned out Morgan was also co-spokesperson on the SciBooNE experiment which at that stage was a proposed experiment to be built out at Fermilab to measure sub-GeV neutrino cross-sections of interest to T2K. After some discussion it was decided that this would be a good opportunity for me to get some hardware experience by going out to Fermilab and helping in the construction of one particular element of the detector, namely the Muon Range Detector (MRD).

The MRD is an iron-scintillator sandwich detector consisting of 13 alternating horizontal and vertical layers of counters separated by 5cm of iron. The total depth of iron in the detector is 60cm which corresponds to stopping a 900MeV muon. The purpose of the MRD is to measure the energies of muons produced in neutrino interactions, for example charged current quasi-elastic (CCQE), where a muon and a proton (muon neutrino) or neutron (muon anti-neutrino) are produced. By measuring the muon energy the neutrino energy can be reconstructed.

In May 2006 I visited Fermilab for 1 month to construct and test the prototype counter design for the MRD. By June the design had been approved and mass counter assembly could begin.
I returned to Fermilab in July this time to assist in the full counter assembly which got underway at the beginning of that month. With 362 counters to be made and 3 days needed for each counter to be produced this would be the largest single job for the MRD construction. The final counters were finished in December just in time to begin the detector assembly in January. At this stage it was decided that I should move to the States to help complete the detector construction and to see it through the beginnings of its data run.

The MRD is a unique detector in the fact that it is almost completely constructed from previously used materials. The scintillator panels (20cm x 155cm x 0.6cm) were taken from an earlier Fermilab experiment whilst 5 different photomultiplier tube (PMT) flavours are used to readout these counters. The iron having enjoyed a number of years outside in the elements had to be cleaned before it was ready to be used. Even some of the cables, both high voltage and signal, had been previously used. When it came to inspect these cables, in storage in a disused detector hall, they were found in a mess, you could say a ratsnest, not so much because the cables were tangled but rather a ratsnest! As 2 grad-students went about untangling the cables two 'rats' (though they could have been large mice) emerged from their makeshift home. Needless to say this added considerable time to the cable inpections as every inch had to be checked for damage and a number were rejected having been partially chewed!
The PMTs have a range of ages, from relatively new tubes used in the KTeV and NuTeV experiments, to RCA tubes that date to the early 70's and no doubt have been used in a number of different experiments over the years. As you can imagine this produces particular problems when it comes to understanding your detector efficiencies. It is a credit to all those involved in the construction that when the detector was switched on in May 2007 only 3 of the 362 channels were found to be dead, well below our expectations.

In January the detector construction got underway in Lab F on the Fermilab site. At this stage SciBooNE, a supposedly small experiment, was starting to sprawl. Office spaces could be found in Wilson Hall, the CDF trailer and the main CDF building. As for the detector construction, the CDF pit was devoted to SciBar and the EC whilst the MRD had spaces at Lab F and Lab 6 not to mention cable repairs taking place at the D0 hall and the civil construction of the SciBooNE hall in the Booster neutrino beamline. SciBooNE was maturing fast and with the aggressive schedule put forward the hope was to see a completed detector by early June in time to commission before the proposed shutdown in August.

The MRD construction proved to be a challenge. Initially the first few planes proved trivial to construct. However as more and more planes were added to the frame so the space between planes diminished. By the time the detector was completed the space between planes was 30cm (the depth of a fermilab standard issue hardhat!) Unfortunately by this stage the american portions had got the better of myself and Nakaji (nickname: 'The Blackhole') and so it was to the smallest of our collaborators, Kendall Mahn (5' 2") to complete the work. We looked on eating doughnuts (raspberry cream I believe).

The detector construction was completed in March and was partially cabled allowing us to test the DAQ system with one week of cosmic data. The move date was set for 23rd April, and so it was apt that "Once more into the breech" was mentioned more than once that day as a 360 ton crane lowered, i've been told i'm not allowed to say dropped, the MRD into place. SciBar and the EC were lowered 2 days later.

At this stage a number of tasks in the detector hall had to be undertaken and it was hoped that the MRD cabling would begin around the 25th May and be completed by early June. However with NuInt, a neutrino interactions conference, to be held at Fermilab from 30th May until 3rd June it was with a last gasp of energy that we pushed to complete the cabling early so as to show beam events at the conference. As you can see from Morgans post we succeeded in doing so but I think it is an astonishing feat that we completed the cabling of the detector on the 24th May, 1 day before we were meant to start!

I hope this has given you a little insight into SciBooNE and the MRD, I personally feel that it is astonishing that such detectors, both SciBar/EC and the MRD, can be constructed in such a short space of time. In a little more than a year a detector went from merely a blueprint with a counter design that had yet to be confirmed as suitable, to a detector taking data. SciBars timeline is equally incredible given that it was shipped in from Japan and had to be reconstructed with a new support frame and DAQ system. It has been a great experience to work in such a dynamic collaboration, I hope this continues. All SciBooNE collaborators must be congratulated for all their hard work.

P.S. I am in the process of making a website where I will be posting photos of the MRD construction among other things T2K/SciBooNE related. I will post a link in due course.

First Neutrinos in SciBooNE

I am the co-spokesperson of SciBooNE, Fermilab's newest neutrino experiment. We have a small detector with fine-grained tracking capability (for a neutrino experiment) placed 100m from the beam target of the Booster Neutrtino Beam, which is the same beam that sends neutrinos to MiniBooNE. We've just crossed the latest and most exciting of a series of significant milestones: recording our first neutrino events! Early last week, our Run Coordinator Masashi Yokoyama from Kyoto University, led the SciBooNE graduate students on an all-nighter so we could record a neutrino event or two in time for the NuInt07 conference at Fermilab. The results were fantastic, and one example is shown at right.

The picture is a top-view event display of our first neutrino interaction with energy deposited in all three detector subsystems. The green field at left represents the SciBar detector, which is made of plastic scintillators with wavelength shifting fibers read out by multi-anode PMTS. The traced square and rectangles in the middle represent the Electron Catcher (EC), which is a lead/scintillating fibre EM calorimeter. The beige strips with small green trim at right represent the Muon Range Detector, which is made of 5 cm iron planes interspersed with plastic scintillators paddles read out by 2-inch PMTs. Maybe Joe will write a blog entry to describe what the MRD does; he knows all about it since he built it! Anyway, the event appears to be a single mu+ track from a muon-antineutrino. In the display, the red dots in SciBar represent strips that registered PMT hits, and the size of the dot is proportional to the amount of charge recorded. The horizontal blue and red lines next to the EC show the amount of charge read out by the EC PMTs (the EC modules are read out on both sides) and are consistent with a MIP. The MRD squares represent scintillators that were hit; we can see that the muon penetrated at least 7 of the iron planes.

Although we have identical readout systems for the side view, we were not running those channels when this event was recorded because the cooling systems were not yet fully operational. They are operational now, and we should be ready for stable beam operations by early next week.

It's a very exciting time for SciBooNE!

R-ECFA Meeting 11-12th May

ECFA stands for European Committee for Future Accelerators. The committee visits institutes in its member countries to assess the current status of accelerator physics and make suggestions on how things can be improved. I was invited to give a talk at a recent Restricted-ECFA meeting that was held at Imperial. They wanted to get an idea about what PhDs in particle physics are really like, so gave a talk about what I had done during my PhD, why I did one in the first place and what my future plans are. It was a lot of fun to stand up and give a talk that was all based on opinion (so I couldn’t technically get anything wrong!). I told them that I thought the atmosphere at CERN was great and that everyone who works there is really enthusiastic. I also said I thought the funding for PhD students was set a quite a reasonable level, sorry to anyone who thinks I should have used the opportunity to campaign for more cash. I had a few complaints, mainly about PPARC admin department (all PhD students have a story or two to back this up) and GSEPS (transferable skills courses) which are generally a waste of time. In the main I think I am lucky to be working in such an interesting and diverse field, especially at such an important time, so that’s what I told them.

Many people gave talks concerning the state of physics in schools, funding for research and general overviews of experiments and institutes. The committee returned a very positive verdict about the status of physics in the UK and made some constructive suggestions. They commented on the small proportion of women in the field but accepted that redressing this balance is a complicated, long term process.

Rector supports blog

Last Friday Imperial's rector Sir Richard Sykes visited CERN - in particular the two experiments with IC involvement CMS and LHCb.

The visit was supervised by CERN's VIP service, a guarantee that nothing can go wrong: 9:00 pick up at the hotel, 9:25 arrive at LHCb, visit. 9:45 go to CMS, photographer is waiting... and so on until the signature of the guest book at 14:15 (involving another photographer). A quite impressive organization that has not much in common with the usual "private" visits of LHCb or CMS.

So early in the morning Jim and the rector met us (Tatsuya, our spokesman, Will and myself) at point 8 for a visit of the LHCb detector. Tatsuya showed every interesting detail and let us enter any usually forbidden door. A quite interesting tour, even for LHCb members!

Of course we had a long stop in front of RICH1 where I tried to explain how it works (remember Cherenkov radiation?) and why we need such a device and CMS don't. I also took the opportunity to ask him if I could make a picture for the blog. That's when he said it was a great idea. One needs to be modern...

After a brief visit of the LHC tunnel we left Tatsuya and Will and continued to point 5 for a CMS visit. Since I hadn't seen CMS for quite some time (especially not since there's something in the cavern) I joined the CMS tour - which was really impressive. Not only because of CMS, but mostly because Jim knows every detail of it and seems to remember an anecdote about every piece of equipment. He also seems to remember each price tag...

The morning was quite challenging - the rector - a biologist - had many interesting questions and seemed very interested about the goals of the research and the technical challenges. I am also not used to being followed by a professional photographer all the time!

We then went to CERN for a lunch with Lyn Evans - head of the LHC project - and Geoff (who would later show the CMS tracker). Of course I tried to get a few insider information about when the LHC will start, but the official statement remains: there will be an announcement by the end of the month. (But feel free to drop by my office I you want to hear some unofficial statements).

Must See TV Tonight

Apologies to our vast international readership who do not have the privilege of paying the BBC licence fee, but tonight there will be a programme on BBC2 at 9pm, called, ahem, Horizon: The Six-Billion Dollar Experiment.

Yes, it is about the LHC.

Since there is absolutely nothing else on the telly tonight, I am sure the whole nation will be captivated by this programme.

Among the questions to be answered tonight:

• Will the BBC get the physics right?
  
• Might the LHC create a black hole which will gobble up the planet (a question that I was asked at passport control last month!)
  
• Will anyone tell them that "the God Particle" is a really really useless name for the Higgs? (with all due respect)
  
• Will any of our colleagues at Imperial HEP appear?
  
• How will Peter Crouch do against John Terry and Michael Essien?