Dear Frank, dear all,
Thank you for the proposals.
The two abstracts are both fine for me.
Regards,
Wataru
> 2018/03/14 16:50、Марина Чадеева <[log in to unmask]>のメール:
>
> Dear Frank, all,
>
> thank you very much for taking care of this.
> I have some minor comments:
>
> 1) suggestion: "system issues" ---> "assembling issues"
> "system issues" looks too common (severe)
>
> 2) "In this presentation, we present" ---> "We present"
>
> As for submission, I would be very grateful if Frank could submit the
> abstracts because I will be travelling in the upcoming days at the end of
> the week.
>
> Best regards,
> Marina
>
>
> В письме от Втр, 13 Мар 2018, 23:56 Frank Simon пишет:
>> Dear Jerry, all
>>
>> thank you very much for the fine-tuning of the abstracts! The new version
>> is given again below. Since the deadline is now imminent we should submit
>> the abstracts in the coming days, before the weekend.
>>
>> If there are any further comments / corrections please bring them up asap
>> (Imad: Of course the abstracts are meant to include SDHCAL developments,
>> for example under the keyword of large-area detector elements and
>> mechanics in the first one, and for the shower and performance studies for
>> different technologies mentioned in the second one, but of course
>> alternative, more explicit formulations can also be adopted if you have a
>> good suggestion.)
>>
>> We also have to decide who submits them: The default would be Marina, but
>> if you prefer that somebody else does it just let me know, then I will
>> submit the abstracts to avoid any problems in the transition phase in the
>> speakers bureau.
>>
>> Cheers,
>>
>> Frank
>>
>>
>> ===
>>
>>
>> Scalability of technologies for highly granular calorimeters
>>
>> After the successful demonstration of the performance of highly granular
>> electromagnetic and hadronic calorimeters by the CALICE collaboration,
>> emphasis has shifted to system issues and large scale production. These
>> are addressed by varied technological prototypes currently in production.
>> In this presentation, we present work on silicon, scintillator, and
>> gas-detector based imaging calorimeters for future electron-positron
>> colliders, pointing out the relevance also for LHC upgrades and other
>> applications. Emphasis will be placed on techniques developed for mass
>> production, such as automatic testing of active detector elements;
>> packaging, wrapping, and mounting of scintillators; and automatized
>> assembly chains as well as on solutions for large-size detector
>> components, precision mechanics and services. We also report results from
>> recent laboratory and beam tests of electromagnetic and hadronic
>> calorimeter prototypes using these production and testing techniques.
>>
>>
>> Reconstruction and study of hadronic showers with highly granular
>> calorimeters
>>
>> Prototype imaging electromagnetic and hadronic calorimeters developed and
>> operated by the CALICE collaboration provide an unprecedented wealth of
>> highly granular data of hadronic showers for a variety of active sensor
>> elements and different absorber materials. In this presentation, we
>> discuss the reconstruction and energy resolution of single hadrons in
>> individual detectors and combined electromagnetic and hadronic systems
>> using software compensation and semi-digital energy reconstruction. We
>> report on the performance of particle flow algorithms, both in terms of
>> improved energy resolution with software compensation techniques for
>> simulated particle jets and for the separation of nearby particles. A
>> prototype scintillator-based hadron calorimeter provides time information
>> at the few nanosecond level, extending previous studies of the time
>> structure of hadronic showers in steel and tungsten absorbers to larger
>> detector volumes. These measurements, together with studies of the spatial
>> structure of hadronic showers with different active elements, provide
>> four-dimensional information for hadronic showers which are confronted
>> with GEANT4 simulations using different hadronic physics models.
>>
>>
>>
>>> On 28. Feb 2018, at 17:27, Jerry Blazey <[log in to unmask]> wrote:
>>>
>>> Frank
>>>
>>> Thanks for taking a first pass at draft abstract. AS requested, I’ve
>>> attempted to “smooth and tune”, a tracked verison is attached.
>>>
>>> Jerry
>>>
>>>
>>> Gerald (Jerry) C. Blazey, Ph.D.
>>> Vice President for Research and Innovation Partnerships
>>> Professor of Physics
>>> Northern Illinois University
>>> +1(815)753-1883 / [log in to unmask]
>>>
>>>
>>> From: Distribution list for the Calice Speakers Bureau
>>> <[log in to unmask]> on behalf of Frank Simon
>>> <[log in to unmask]>
>>> Reply-To: Frank Simon <[log in to unmask]>
>>> Date: Monday, February 26, 2018 at 2:53 PM
>>> To: "[log in to unmask]"
>>> <[log in to unmask]>
>>> Subject: Re: Deadline of abstract submission to ICHEP 2018
>>>
>>>
>>> Scalability of technologies for highly granular calorimeters
>>>
>>> After the successful validation of the concept of highly granular
>>> electromagnetic and hadronic calorimeters by the CALICE collaboration,
>>> the emphasis of the development has now shifted to the development of
>>> solutions for system issues and large scale productions. These get
>>> addressed by different technological prototypes currently in production.
>>> In this presentation, we will present the technology R&D for silicon,
>>> scintillator and gas-detector based imaging calorimeters for future
>>> electron-positron colliders, pointing out the relevance also for LHC
>>> upgrades and other applications. Particular emphasis will be placed on
>>> techniques developed for mass production, such as automatic testing of
>>> active detector elements, packaging and mounting of scintillators,
>>> automatized assembly chains as well as on solutions for large-size
>>> detector components, precision mechanics and services. We will also
>>> report results from recent laboratory and beam tests of electromagnetic
>>> and hadronic calorimeter prototypes making use of these production and
>>> testing techniques.
>>>
>>>
>>> Reconstruction and study of hadronic showers with highly granular
>>> calorimeters
>>>
>>> The physics and technological prototypes of imaging electromagnetic and
>>> hadronic calorimeters developed and operated by the CALICE collaboration
>>> have provided an unprecedented wealth of highly granular data of
>>> hadronic showers for a variety of active sensor elements and different
>>> absorber materials. In this presentation, we will discuss the
>>> reconstruction and energy resolution of single hadrons in individual
>>> detectors and combined electromagnetic and hadronic systems using
>>> software compensation and semi-digital energy reconstruction. The
>>> performance observed in test beams is connected to particle flow
>>> algorithms, both in terms of improved energy resolution with software
>>> compensation techniques for simulated particle jets and for the
>>> separation of nearby particles. The data taken with the technological
>>> prototype of the scintillator-based hadron calorimeter provides time
>>> information on the few nanosecond level, allowing to extend previous
>>> studies of the time structure of hadronic showers in steel and tungsten
>>> absorbers to larger detector volumes. These measurements, together with
>>> studies of the spatial structure of hadronic showers with different
>>> active elements, provide four-dimensional studies of hadronic showers
>>> which are confronted with GEANT4 simulations using different hadronic
>>> physics models.
>>> <ICHEP 2018 Abstract Drafts.docx>
>>
>> <=========================================================>
>> Frank Simon
>>
>> Max-Planck-Institut fuer Physik
>>
>> Phone: +49-89-32354-535
>> Mobile: +49-160-90446142
>> <=========================================================>
>>
>
>
> *************************************************************
> Dr. Marina Chadeeva
> Laboratory of heavy quarks and leptons, bld. 3,
> P.N. Lebedev Physical Institute of the Russian Academy of Sciences
> 53 Leninskiy Prospekt,
> 119991, Moscow, Russia
> ***************************************************************
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